1 PHYSICAL QUANTITIES Physics: Study of matter in relation to energy. Physical Quantity: A property of matter than can be quantified with measurement and can also be expressed as a number. There are two types of physical quantities. These are 1. Basic Physical quantities 2. Derived Physical quantities Basic Physical Quantities. These are the fundamental physical quantities. Quantity Symbol SI Units Symbol of SI Units. Length Mass Time absolute temperature electric current luminar intensity molecular quantity s,l m t T I L n metre kilogram seconds Kelvin Amperes Candela mol n kg s K A Ca mol Derived Physical Quantities These are derived from one or more basic quantities. Quantity Symbol SI Units Symbol of SI Units. Area Volume Velocity Acceleration Pressure Energy Density Frequency Voltage Charge Force Resistance A V u,v a P E, U, Q, W metres squared Cubic metres metres per second metres per second squared Pascals Joules kilograms per cubic metre Hertz Volts Coulombs Newtons Ohms m2 m3 m/s or ms-1 m/s2 or ms21 Pa J 3 kg/m or kgm-3 Hz V C N f V Q F R PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 2 Multiples And Submultiples Of Si Units Power 10-18 10-15 10-12 10-9 10-6 10-3 10-2 10-1 101 102 103 106 109 1012 1015 1018 Prefix attofemtopiconanomicromillicentidecidekahectokiloMegaGigaTeraPetaExa- Abbreviation A F P N M C D Da H K M G T P E Unit Conversions Sometimes it may be necessary to convert from one unit to another unit for the same physical quantity. To convert from a base unit to a multiple/submultiple, divide by the power of ten for the prefix. E.g. Change 200 metres to millimetres. 200 = 200 x 103 millimetres. 3 10 To convert from a base unit to a multiple/submultiple, multiply by the power of ten for the prefix. E.g. Change 300 Megavolts to volts. 300 x 106 volts. Classwork Perform the following unit conversions 1 10 mm to m 2. 300 GHz to Hz 3. 0.01 A to A 4. 20 km to mm 5. 480 mJ to MJ 6. 1 mm2 to m2 7. 1 m3 to cm3. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 3 Measurement of Time Time: - Period between events - Duration of an event. Instruments used to measure time include watch/clock, pendulum, sundial, hourglass. Time measuring instruments depend on events which can repeat themselves regularly. Examples include -vibration of quartz crystals -appearance of the moon/stars/sun in the sky. -croacking of the cock. SI units of time are seconds (s). Other units include Minutes, Hours, Days, Week, Fortnight, Months, Years, Decades, Centuries & Millennium. Using a stopwatch to measure time. A stopwatch is used in labs to measure the duration of an event and in some cases the period between events. Start/stop button: Lap/reset button: Used to initiate and end the timing process Used to reset the watch and also to momentarily stop the watch to take a reading. What time is shown by the stopwatch above? Time shown =............................ Accuracy of the stopwatch Accuracy of any measuring instrument is the smallest measurement that can be made with the instrument, or the smallest division in the instrument. Thus the accuracy of the stopwatch is 0.01 seconds. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 4 Errors associated with the use of a stopwatch 1. 2. Human reaction time: People do not react in a similar manner in similar situations. i.e reaction times are not always the same. This can lead to errors of time measurement. These errors can be minimized by taking multiple readings and then calculating the average Zero Error: This is where the instrument does not commence readings at zero. It is more prevalent in analogue clocks. Period of a Simple Pendulum This consists of a mass attached to a string which is then allowed to swing freely. The time taken to make one complete swing is called the Period (T) of the pendulum. Experiment to find period of a pendulum. Apparatus: Pendulum bob + string Metre ruler Stopwatch Retort stand + clamp. Procedure: 1. Setup the apparatus as shown below. 2. Measure and record l, the length of the pendulum. 3. Using the stopwatch, measure and record the time taken to make 20 complete oscillations. A complete oscillation is movement from Q to R and back to Q. 4. Calculate the period, T. 5. 6. Repeat steps 2 and 4 for two more values of l. Record your results in the table below. Length (cm) Time for 20 oscillations (s) Period, T (s) Factors affecting the period of a pendulum. i) Length ii) Acceleration due to gravity PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 5 Measurement of Length Length is a measurement of how long something is. SI units are metres (m). Instruments used to measure length include; - ruler - measuring tape - clickwheel - vernier alipers - micrometer screwgauge Measurement of length using a ruler. When using a ruler, one must try to avoid parallax error and zero error. Measurement of length using a Vernier Calipers. A vernier callipers is used to measure internal and external diameters, thickness of metal sheets, small depths, etc. The vernier callipers has two scales; the main scale and the vernier scales. The vernier scale slides over the main scale. The final reading from the instrument is the sum of the Main Scale Reading and the Vernier Scale Reading. The main scale reading is the mark on the main scale which is to the left of the zero of the vernier scale. The vernier scale reading is any mark on the vernier scale which coincides with any other mark on the main scale. The smallest division on the vernier scale is 0.01 cm. Errors associated with the use of a vernier callipers include zero error and parallax error. Accuracy of the vernier callipers is 0.1 mm. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 6 Measurement of length using a Micrometer Screw gauge. A measuring cylinder is used to measure small lengths accurately. It is able to give more accurate readings of length up to 25 mm. The micrometer screw gauge has two scales; the main scale and the drum scales. The drum scale slides over the main scale. The final reading from the instrument is the sum of the Main Scale Reading and the Drum Scale Reading. The Main Scale Reading is the last mark on the main scale which is on the edge of the drum/thimble. The main scale is calibrated/graduated in millimetres. The Drum Scale Reading is any mark on the drum scale which coincides with the horizontal line passing through the main scale. The smallest division on the drum scale is 0.01 mm. Errors associated with the use of a micrometer screw gauge include parallax error and zero error. There are two types of zero errors associated with the screw gauge. This are negative zero error and positive error. Diagram (b) shows a positive zero error of 0.02 mm. Diagram (c) shows a negative zero error of -0.04. Accuracy of the micrometer screw gauge is 0.01 mm. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 7 MOTION Definition of Terms Distance (s) The length of the pathway followed by an object between two points. SI units are metres. Displacement (s) Distance in a specified direction. SI units are metres. Average Speed: The total distance travelled in a given period of time. Average speed = total distance travelled time taken Velocity (u-initial velocity and v-final velocity): Speed in a stated direction or the rate at which displacement changes with time. The SI units are metres per second Acceleration (a): The rate at which velocity changes with time. acceleration = change in velocity time taken v - u t If the acceleration is negative it is called deceleration or retardation. a Uniform and Non-Uniform Motion Uniform Velocity: This refers to constant or steady velocity. t (s) 0 1 2 3 4 v (m/s) 8 8 8 8 8 Non Uniform Velocity: This refers to velocity which is not constant t (s) 0 1 2 3 4 v (m/s) 3 4 5 8 10 Uniform Acceleration: This refers to constant or steady acceleration. It means that the increase or decrease in velocity is the same per unit time. t (s) 0 1 2 3 4 v (m/s) 0 4 8 12 16 a (m/s) 4 4 4 4 Non-Uniform Acceleration: This refers to acceleration which is not constant. t (s) 0 1 2 3 4 5 v (m/s) 0 2 6 7 16 19 a (m/s) 2 4 1 9 3 PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 8 Motion Graphs Distance-Time Graphs Slope or gradient of a distance-time graph gives velocity. t (s) 0 1 2 3 4 5 s (m) 0 2 4 6 8 10 m Y2 - Y1 8m - 2m 4s - 1s X 2 - X1 6m 3s = 2 m/s If the distance-time graph is a diagonal line then the velocity is constant. If the distance-time graph is a horizontal line then the object is at rest. Velocity-Time Graphs Velocity-time graph for uniform velocity is a horizontal line. t (s) 0 1 2 3 4 v (m/s) 8 8 8 8 8 PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 9 Velocity-time graph for uniform acceleration and uniform deceleration is a diagonal line Uniform Acceleration Uniform Deceleration t (s) 0 1 2 3 4 5 v (m/s) 0 4 8 12 16 20 a (m/s) 4 4 4 4 4 Slope/gradient of a velocity-time graph gives acceleration. m t (s) 0 1 2 3 4 5 v (m/s) 20 16 12 8 4 0 a (m/s) 4 4 4 4 4 Y2 - Y1 X 2 - X1 8 m/s - 2 m/s 4s - 1s 6 m/s 3s = 2 m/s2 Area under a velocity-time graph gives distance covered. Area = 1 /2 x b x h = PHYSICS NOTES: Physical Quantities & Measurement 1 /2 x 5s x 10m/s = 25 m/s PREPARED BY RAYMOND 2017© 10 Classwork 1. The diagram below shows the velocity-time graph for a motor vehicle (a) (i) (ii) Describe the motion of the vehicle between (i) PQ (ii) QR (iii) RS (b) Using the graph, calculate the acceleration of the vehicle during the first 2 seconds. the acceleration of the vehicle during the last 2 seconds. (c) 2. Calculate the total distance travelled Use the distance-time graph below to answer questions which follow (a) (b) Describe the motion between (i) 0A (ii) AB (ii) BC Calculate speed in the last 1 second PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 11 Equations of Motion v u at eqn 1 s 12 (u v)t eqn 2 s ut 12 at 2 eqn 3 v 2 u 2 2as eqn 4 It is important to note that Eqn 1 does not have s Eqn 2 does not have a Eqn 3 does not have v Eqn 4 does not have t All the equations have u. NB: This equations only apply to objects travelling with uniform motion. M, Classwork (On answering these questions assume that there is no air resistance) 3. A bus starts off from rest and reaches a velocity of 25 m/s in 10 seconds. Calculate (i) acceleration of the bus the distance travelled in the first 10 seconds. (ii) A car travelling with a constant speed of 20 m/s accelerates at 2 m/s2 for 5 seconds. Calculate (i) the velocity of the car after 5 seconds (ii) distance travelled in that time. 4. A train travelling at 36 m/s decelerates at 4 m/s2 for 9 seconds. Calculate 5. (i) (ii) 6 An aircraft accelerates at 0.8 m/s2. It’s take off speed is 48 m/s. (i) (ii) 7. the velocity of the car after 9 seconds distance travelled in that time. What length of runway does the aircraft need to take off. How long does it take to reach its take off speed? Usain Bolt, a Jamaican athlete, is the world record holder after completing the 100 metre race in 9.58 seconds recently. Calculate (i) His final velocity as he crossed the finish line (ii) His acceleration PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 12 Vertical Motion without Air Resistance (Acceleration due to gravity, g) Assuming that there is no air resistance, all bodies undergoing vertical motion accelerate uniformly at g or –g depending on whether they are ascending or descending. Descending objects u = 0 m/s a = g = 10 m/s2 Ascending objects v = 0 m/s a = -g = -10 m/s2. Classwork (On answering these questions assume that there is no air resistance) 8. (i) (ii) 9. A cannon ball is shot vertically upwards with an initial velocity of 40 m/s. Calculate the maximum height reached by the cannon ball the time taken to reach that height. A ball is dropped from cliff. If the ball reaches the ground after 4 seconds, calculate (i) the height of the cliff (ii) the velocity of the ball just before hitting the ground 10 (iii) 11. A ball is thrown upwards with a velocity of 8 m/s. Calculate (i) the maximum height reached by the ball (ii) the time taken to reach that height on falling back, the ball lands on the roof of a house 0.4 seconds after reaching the maximum height. A motor car travelling at a constant speed of 20 m/s drives over a cliff and hits the ground after 4 seconds. Calculate (i) (ii) The height of the cliff The distance from the foot of the cliff to the point where the car hits the ground (iii) The vertical velocity of the car as it hits the ground (vi) The horizontal velocity of the car as it hits the ground PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 13 Vertical Motion with Air Resistance (Terminal Velocity) When a body falls through a fluid, its acceleration is reduced as it encounters friction. The acceleration is reduced because the fluid friction increases. The diagram below shows the movement of a ball as it falls through air, from the moment it is released. Stage 1 Initially as the ball is dropped the only force acting on it is its weight. At this point the ball accelerates uniformly at g. Stage 2 The ball has started experiencing fluid friction but its weight is greater than the fluid friction. Thus the acceleration of the ball is reduced but it is still greater than zero. As such the velocity keeps on increasing which results in an increase in fluid friction and as such the resultant force decreases. Stage 3 The fluid friction increases until it becomes equal to the weight. At this point the resultant force is zero and the acceleration is also zero. Thus the velocity stops increasing and remains constant for the remainder of the flight of the ball. This constant velocity is called terminal velocity. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 14 The diagram below shows the velocity-time graph for an object falling through a fluid until it reaches terminal velocity. Classwork 11. The diagram below shows the forces acting on a raindrop which is falling to the ground. (i) A is the force that causes the raindrop to fall. What is the force called? (ii) B is the total force opposing the motion of the drop. State one possible cause of this force. (iii) What happens to the raindrop when force A = force B? PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 15 Mass, Inertia, Weight & Centre Of Gravity Mass: Amount or quantity of matter in an object. Mass is a constant for every object and never changes. Inertia: It is the tendency of an object to resist changes to its state of motion. Objects with large mass have large inertia and those with small mass have a small inertia. As such inertia can be seen as an indirect measurement of mass. Weight: This is the gravitational pull on an object. Weight of an object depends on the acceleration due to gravity and as such can change depending on the force of gravity. weight = mass x acceleration due to gravity. W = mg Example: The table below shows the value of the acceleration due to gravity in different places. Earth Moon Space g (N/Kg) 10 1.6 0 Calculate the weight of a 60 Kg austronaut in (i) earth (ii) moon (iii) space Centre of Gravity (Centre of Mass) This refers to a point within an object where its entire mass or weight seems to be concentrated such that if the object is supported at this point it should balance. Centre of Gravity of Regular Objects. The centre of gravity of irregular objects is found at their geometric centre. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 16 Centre of Gravity of Irregular Objects. Apparatus Irregular lamina Retort stand & clamp Plumb line Procedure 1 Make 3 holes on the edge of the lamina and label them A, B & C. 2 Suspend the lamina on the retort stand through hole A 3 4 7 Suspend the plumb line in front of the lamina Allow both the lamina and the plumb line to come to rest. 5 Trace the plumb line along the lamina 6 Repeat steps 2 to 5 for holes B and C. The centre of gravity of the lamina is at the intersection lines. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 17 Toppling The position of the centre of gravity within an object determines if it topples over easily. A body topples if the vertical line through its centre of gravity falls outside its base. In figure (a) the vertical line through the centre of gravity falls within its base and as such will not topple. In figure (b) the vertical line through the centre of gravity falls on the edge of the base and as such will balance on the edge. In figure (c) the vertical line through the centre of gravity falls outside the base and as such will topple, i.e. fall over. Stability A body that topples easily is not stable while one which does not topple easily isstable. Factors affecting stability Stability of any object depends on Wideness of the base. If the base is wide then the object becomes more stable while bases which are not wide make objects less stable. Position of the centre of gravity. If the centre of gravity is positioned at a high position then the object is less stable. If the position of the centre of gravity is low then the object becomes more stable. Three terms are used to describe stability of objects. These are (i) Stable Equilibrium A body is in stable equilibrium if it goes to its original position after being slightly displaced and released. The Bunsen burner below is in stable equilibrium PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 18 1. (ii) Unstable Equilibrium A body is in unstable equilibrium if it does not retain its original position after being slightly displaced and released. Its centre of gravity falls. The Bunsen burner below is in unstable equilibrium (iii) Neutral equilibrium A body is in neutral equilibrium if it retains its new position after being slightly displaced and released. The position of its centre of gravity remains the same. The Bunsen burner below is in neutral equilibrium. Classwork The table below gives a value for the acceleration due to gravity, g, on various planets. Use it to answer questions which follow. Planet g (m/s2) Pluto 0.5 Mars 4 Earth 10 Jupiter 26 A 30 ton Spacecraft leaves earth and visits all the planets listed above. Calculate the weight of the spacecraft in Pluto, Earth, Mars & Jupiter 2. A bus and a racing car are travelling at the same high speed in the same direction. They both approach a curve on the road at the same time. The bus overshoots the curve while the racing car negotiates the curve with ease. (i) State two attributes of the racing car which helped it to negotiate the curve. (ii) State a way in which road curves are constructed so as to minimise cases of vehicles overshooting it. 3. A truck and a small car are travelling along a straight road at the same speed. Both drivers see an obstacle on the road and apply the brakes at the same time. Which vehicle is likely to stop first? Give a reason for your answer. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 19 ENERGY, WORK & POWER ENERGY Energy is the ability or capacity to do work. The SI unit of energy is the Joule (J). Energy exists in various forms. These include (a) Kinetic energy (Ke) Energy found in moving objects (b) Heat Energy (He) Kinetic energy of particles in matter. (c) Potential energy The energy an object has because of the height it has been moved, its chemical composition or because of its shape/size. Forms of potential energy include (i) Gravitational Potential energy (GPe). The energy an object has because of the height it has been moved. (ii) Chemical Potential energy (CPe). The energy an object has because of its chemical composition. (iii) Mechanical Potential energy (MPe). The energy an object has because of its shape/size. (d) Light energy (Le) The energy given off by luminous and non luminous objects (e) Electrical energy (Ee) Energy transported by electric charges in conductors. (f) Sound energy (Se) Energy found in vibrating objects. Principle of Energy Conservation It states that energy can neither be created nor destroyed, but can only change from one form to another during an energy conversion. Efficiency The quality of a system to convert one form of energy to another without wastage. During energy conversions, some of the energy is lost (i.e it is not changed into a useful form), heat energy accounts for most of the energy lost. Therefore, energy conversions are never 100% efficient. efficiency energy output X 100% energy input Energy conversions A person speaking into a microphone. Sound energy → Electrical energy 1. 2. Listening to a loud speaker. Electrical energy → Sound energy. 3. Hydroelectric Power Station. Gravitational Potential Energy → Kinetic Energy → Electrical energy Sources Of Energy Sources of energy can be divided into two groups. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 20 Renewable Sources Of Energy are those sources which can be replaced once used and are generally non polluting. Non-Renewable Sources Of Energy are those sources that cannot be replaced once used and are generally polluting. Major sources of energy in Botswana Energy Source 1) Solar Energy (Renewable) 2) Coal (non renewable) Use Botswana enjoys a lot of sunshine throughout the year. Solar water heaters are used in some households. Photovoltaic power can be generated from solar panels fitted with solar cells Used for generating electricity as well as heating and cooking advantages Abundant Cheap Environmental friendly Abundant Cheap Biomass (Firewood, cow dung, charcoal,food) (Renewable) Wind (Renewable) widely used for cooking and heating. Abundant Cheap Due to the flat terrain, Cheap there is not much wind in Environmental friendly Botswana. Windmills are used to pump water out of boreholes Disadvantages Expensive equipment No sunshine during cloud cover. Air pollution Coal mining scars the landscape Releases CO2 which causes global warming collection of fire wood leads to deforestation Release carbon dioxide leading to global warming. No wind at times . Sources of energy in other countries Energy Source Nuclear power (non renewable) Use Used for generating electricity Advantages Little fuel is needed to produce a lot of electricity.(Only 7 kg of uranium fuel are needed to produce 60 000 W of electricity PHYSICS NOTES: Physical Quantities & Measurement Disadvantages High building costs Expensive equipment Expensive maintenance Puts living things at risk of radioactive PREPARED BY RAYMOND 2017© 21 Hydroelectric power (renewable) Water is collected/stored behind huge dams on high ground such as mountains. The water is released through sluices and its GPe is changed to Ke which to drive turbines for generating electricity. per month) Does not release toxic gases into the atmosphere. Does not cause much pollution Crude oil & natural gas (non renewable) Geothermal energy ( renewable) Bio fuels (renewable) Used for generating electricity, fuel for motor vehicles and industrial machines. Heat energy from radioactive reactions in the earth’s core escapes to the surface through vents on the crust in the form of steam. This energy can be tapped and used for generating electricity and heating homes. These are alcohol based fuels produced from biomass through fermentation, pyrolisis and anaerobic digestion. They are used for generating electricity and fuel for motor vehicles. Abundant Cheap Cheap Does not cause much pollution Does not require much structural development. Environmentally friendly as waste products can be used to energy. If fermentation and pyrolisis are used there is little or no CO2 released into atmosphere. abundant emissions due to the possibility of nuclear meltdown. Requires expert skills. Waste products pose storage problems and can be used to make atomic weapons. Limited number of suitable sites to build the dam. High building costs The reservoir floods huge valleys which drowns animal and kills plants thus impacting on biodiversity. Huge numbers of people have to be relocated in order to accommodate the reservoir. Water loses its quality due to hydroelectric processes. The weight of the water in the reservoir causes seismic activity. Requires expert skills Their combustion releases greenhouse gases into the atmosphere which leads to global warming. Causes water pollution Accidents during their mining and transportation causes’ water and air pollution. Not available in many locations. High cost of drilling deep into the earth. Requires expert skills. Farming large amounts of crops is expensive Converting the bio mass to bio fuels is expensive. Food plants are used to process biofuels and this could lead to food shortages and/or increase in food prices. Pyrolisis is requires huge amounts of heat. Direct combustion could lead to air pollution. Socio-Economic and Environmental Impacts of using energy sources As shown in the table above the use of most energies sources has several disadvantages. Before any energy source is used it is important to determine its socio-economic and environmental impacts. As such there is need for an Environmental Impact Assessment (EIA) study to be carried out before any energy source is utilized Conservation of energy Energy which takes a form which is not useful at a particular time is said to have been wasted or lost. Preventing this from happening is called energy conservation. This is achieved through diligent use of available energy sources. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 22 Mechanical Energies These are energies associated with the position and motion of an object. Mechanical energy of a system is the sum of the gravitational potential energy and the kinetic energy of the system. Kinetic Energy The kinetic energy of a body of mass m, travelling with a velocity v, is given by Ke 1 mv 2 2 Gravitational Potential Energy The gravitational potential energy of a body of mass m, which is moved through a height h, is given by GPe mgh GPe – Ke Transformations Gain in GPe = Loss in Ke Loss in GPe = Gain in Ke ∆ GPe = ∆ Ke Classwork 1. A 5 kg rocket has 500J of kinetic energy. Find the velocity of the rocket. 2. A 100g steel ball is 1.8m above the floor. What is the amount of gravitational potential energy possessed by the ball? 3. A 200 g ball is shot vertically upwards to a height of 80 metres. Calculate (i) Kinetic energy of the ball as it left the ground. (ii) The velocity with which it leaves the ground (iii) Time taken to reach the height 4. A 2 kg stone is dropped from a tower and reaches the ground after 2 seconds. Calcultate the GPe of the stone before it is dropped. 5. A lamp is 60% efficient, if the lamp gives out 400J of light energy. (i) How much electrical energy was it supplied with? (ii) How much energy was wasted as heat. WORK Work is the transfer of energy. It is measured as a product of the force applied and the distance moved. Work done = applied force x distance moved W = Fs POWER PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 23 This is the rate at which work is done or the rate at which energy is transferred. Power Work done/Energy transfer time P W/E t Classwork 6. 7. A boy whose weight is 600 N runs up a flight of stairs 10m high in 12 seconds. Calculate the power he develops in climbing the stairs. A donkey pulls a cart with a force of 400N and takes 10 seconds to cover a distance of 100m. What is the power developed by the donkey in pulling the cart? 8. How long does it take an electric motor rated 800 W to complete 4kJ of work in lifting a load. 9. A machine changes 5 kJ of electrical energy into kinetic energy in half a minute. What is the power rating of the machine? 10. A hydroelectric dam generates 10 000 W of electricity every 2 minutes. To achieve this 3 000 kg of water falls down the dam to the turbines every 2 minutes. If the height of the dam is 60 m, calculate (i) amount of energy in the water as it reaches the turbines. (ii) amount of electrical energy generated by the dam. (iii) efficiency of the power station. (iv) the fate of the ‘lost’ energy. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 24 PRESSURE Pressure is the force applied per unit area. pressure force area P F A The SI units of pressure are Pascals [Pa]. One Pascal is equal to one Newton per square meter (1 Pa = 1N/m2). Examples of the effects of pressure are: Stiletto-heeled shoes are likely to mark floors, A knife is often sharpened before use, A car with tyres that have a small surface area easily sinks in sand or mud. Astronauts wear space suits when on mission. These provide pressure to balance body pressure. Pressure in Fluids The pressure in a fluid depends on depth of the liquid density of the liquid acceleration due to gravity P= ρgh Where ρ =density of fluid g = acceleration due to gravity h = depth of the fluid. Classwork 1. 2. 3. 4. 5. 6 Calculate the pressure if a 150N force is exerted on a surface area of 0.5m2. A concrete block of mass 90 kg and a square base of side 2 m is resting on the ground. What is the pressure it exerts on the ground? A pressure of 10 Pa acts on an area of 3.0m2. What is the force acting on the area? Which of the following will damage a wood-block floor that can withstand a pressure of 2000 kPa ? A A block weighing 2000kN standing on area of 2 m2. B An elephant weighing 200kN standing on an area of 0.2 m2. C A girl of weight 0.5 kN wearing stiletto-heeled shoes standing on an area of 0.0002m2. What is the pressure 100 m below the surface of sea water of density 1150 kg/m3? At a weather station the pressure is found to be 100 000 Pa while the average density of air is found to be 1.25 kg/m3. Calculate the average depth of the air above the weather station. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 25 Atmospheric Pressure This is the pressure due to the weight of the atmosphere on earth. The atmospheric pressure at sea level is about 1.0 x 105 Pa (100 000 Nm-2). We do not feel this pressure because it is balanced by our blood pressure. Effects Of Atmospheric Pressure Bleeding: If the atmospheric pressure is smaller than the blood pressure nose bleeding may occur. This is common during very hot days as well as at a high altitude. Collapsing Can: If air is removed from a can using a vacuum pump, the wall of the can collapses as air inside the can is gradually removed. The same effect can be seen when using a drinking straw on mini-juice packaged drink. Magdeburg Hemispheres: If two hemispheres are fitted together and air removed, it becomes very difficult to separate the hemispheres. Drinking Straw: Atmospheric pressure helps you to push the drink up as you suck using a straw. Rubber Sucker: When a rubber sucker is pressed against a smooth surface, air is removed. The atmospheric pressure pushes and holds the cup against the surface. Suction cups are used to lift metal sheets, glass panes or holders for towels and coats. Siphoning water: when siphoning water from a large tank to a smaller one, atmospheric pressure helps you by pushing the water up the pipe. Measuring Atmospheric Pressure Atmospheric pressure can be measured using a barometer. Types of barometers include Simple Mercury Barometer Aneroid Barometer Fortin’s Barometer Simple Mercury Barometer This instrument is used to measure atmospheric pressure. It consists of a cylindrical tube filled with mercury which is then inverted into a mercury bath. A small amount of the mercury flows into the bath but most remains in the tube. Atmospheric pressure acting on the surface of the mercury in the mercury bath supports the mercury column in the tube. The pressure at Y due to mercury column XY is equal to the atmospheric pressure. The height h is directly proportional to the atmospheric pressure and as such is used as a unit of measuring pressure. The height h is about 760 mm (0.76 m) mm at sea level. Thus 760 mm of mercury is equal to 1 atmosphere (1 atm). PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 26 U tube manometer A u-tube manometer is used to measure gas pressure. It consists of a u-tube filled with mercury. In figure (a), the level of the liquid in both arms of the u-tube is the same since only atmospheric pressure is acting on the liquid in the u-tube. (the gas has not been connected yet.) The pressures at A and at B are the same and are equal to atmospheric pressure. In figure (b), a gas supply is connected to the manometer. If the gas pressure is greater than atmospheric pressure it increases the pressure at A which causes level A to go down while level B rises. At equilibrium the pressure at A must equal to the pressure at C since they are both at the same level. Thus the gas pressure at A, PA is equal to the pressure at C, PC. (PA = PC.) But PC is equal to the pressure at B, PB (atmospheric pressure) + the pressure due to mercury column BC (gh). Therefore the gas pressure PA is given by, PA = PB + gh Where h = barometric height-height of the column BC = density of liquid in u-tube g = acceleration due gravity PB = atmospheric pressure Classwork 7. In a simple mercury barometer, the tube supports 73cm of mercury. What is the atmospheric pressure in Pascal’s? Density of mercury is 13 600 kg/m3 8. What would be the height of a water barometer if atmospheric pressure is 1 x 10 5pa and the density of water is 1.0 x 103 kg/m3 9. In a manometer used to measure gas pressure, the gas supports a 100 mm of mercury column, calculate the gas pressure. Atmospheric pressure is 760mm Hg. 10. The pressure at the base of a mountain is 105 000 Pa while the pressure at the mountain top is 15 000 Pa. If the average density of air is 1.25 kg/m3, calculate the height of the mountain. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 27 Weather Maps Atmospheric pressure and other atmospheric conditions such as temperature, humidity and cloud pattern can be used to predict weather. Such conditions can be plotted on a map to form a weather map. An isobar is a line on a weather map that joins places with the same atmospheric pressure. Pressure on a weather map is quoted in pressure units called millibars. 1 Bar = 100 000 Pa 1 atm (1 Bar = 1000 Millibars) Cyclone A cyclone is a region where the atmospheric pressure decreases as you approach the centre of the region. i.e it has low pressure at the centre . Wind blows spirally from a high to a low pressure region. Cyclones are characterised by wet, windy weather. The closer the isobars the stronger the wind and chances of rain. Examples of cyclones include whirlwinds, typhoons, hurricanes, tornadoes, willi-willies etc. Anticyclone An anticyclone is a region with high pressure at the centre. It is characterised by dry dense air. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 28 KINETIC THEORY OF MATTER Matter is made up of small particles called atoms or a group of atoms called molecules. The size of each particle is different for different materials. The distance between molecules can change depending on the Internal Energy (kinetic + potential) of the molecule or atom. Particles are always in motion (moving). The higher the temperature the faster the molecules move/vibrates. At the same temperature, all molecules have the same energy. Small particles move faster while heavy particles moves slowly. States Of Matter States of matter Properties Distance between molecules SOLID LIQUID GAS Have a definite volume and definite shape. Not compressible Have a definite volume but no definite shape (takes the shape of the container). Slightly compressible Have no definite shape and volume. (wholly fills up the container and takes the shape of the container). Highly compressible Molecules are very close to each other Molecules slightly further apart than in solids but still close together to have a definite volume Particle held by less strong forces. Molecules are much further apart. So gases can be compressed or squeezed in smaller space. Forces between molecules Held by strong forces of attraction called bonds. Motion Molecules vibrate to and fro at a fixed position. Free to move No or less forces of attraction. Molecules are free to move in any direction. Moves freely at high speed colliding with each other and the walls of the container. Motion of Gas Molecules and its Temperature and Pressure. If a gas is heated in a closed container, its molecules gain kinetic energy and begin to hit the walls of the container more frequently than before. This causes an increase in pressure on the walls of the container. The faster the gas molecules move, the higher the temperature they attain. The gas container can explode if it can’t withstand the pressure build up. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 29 Brownian Motion Brownian motion gives us the evidence that molecules in suspension (gases) are constantly moving. When smoke is trapped in a glass box (smoke cell) and is observed with a microscope, the smoke particle can be seen as bright specks moving around in a random and haphazard manner. This is because they collide with gas molecules that move at high velocities at random paths. Smoke particles are bigger compared to air particles. The specks of light seen is where collision between smoke particles and air particles occur. This phenomena is known as Brownian motion.. Evaporation Evaporation is the escape of high energy molecules from the surface of a liquid. Evaporation results in a drop in the temperature of the liquid from which the molecules escaped. This is because the molecules that escape acquire energy to do so from those which remain in the liquid.Evaporation only takes place at the surface of the liquid and occurs at any temperature. Factors That Affect Evaporation A number of factors affect the rate of evaporation. These are; Wind speed (drought).An increase in wind speed causes an increase in rate of evaporation Surface area. The larger the surface area the higher the rate of evaporation. Temperature. The higher the temperature the higher the rate of evaporation Humidity. The higher the humidity the lower the rate of evaporation. Applications of evaporation Ether is used in fridges to cool their interiors PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 30 Water sacks are put under the shade and moistened with water so that the water inside cools as the molecules outside evaporate. Organisms cool themselves by evaporation using different ways, . Dogs = Panting Elephants= Flap their ears Humans= Perspiration Plants=Evaporation from leaves THERMAL EXPANSION OF MATTER Matter expands when heated. This happens because particles gain kinetic energy and begin to move away from each other resulting in an increase in the space between them. When matter is cooled it contracts. Gases expand the most and solids expand the least(Gases contract the most and solids contract the least. Experiment to Demonstrate Expansion in Solids There are various experiments to show expansion in solids. These include Ball and ring apparatus, bimetallic strip etc. Ball and ring apparatus. Before the ball is heated, it easily passes through the ring. But if the ball is heated it does not pass through the ring. This is because the ball has expanded. If the ball is allowed to cool then it will contract. This will allow it to pass through the ring again. Bimetallic strips A bimetallic strip is made of two different metals which are riveted together. The two metals expand at different rates and as such when the strip is heated, it bends with the PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 31 most expansive metal on the outside. Study the diagrams (a) and (b) which show the bimetallic strip after cooling and heating respectively. Which of the two metals expand the most? Experiment to Demonstrate Expansion in liquids A coloured liquid is poured into a test tube which is fitted with a glass tube as shown below. Before heating, the level of the liquid is at level A. After heating the liquid level goes up to level B. This indicates that the liquid has expanded and increased in size. Experiment to Demonstrate Expansion in Gases PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 32 When the flask is heated bubbles are observed in the water as shown above. This indicates that the air inside has expanded and some of it is escaping through the glass tube to the outside. As the air passes through the water it causes the observed bubbles. Applications of Expansion 1. Thermostat These are devices that maintain a steady (constant) temperature in an appliance. The bimetallic strip in the thermostat bends to switch off the circuit if the temperature rises above the set temperature and straightens to switch on the circuit if the temperature falls below the set temperature. The diagram above shows the thermostat as used in an electric iron. Other appliances that use a thermostat include air conditioners, electric oven, electric kettle, e.t.c. 2. Fire alarm It uses bimetallic strip as a switch. When there is a fire in the house, the bimetallic strip bends to close the contacts thereby switching on the circuit. This causes the bell to ring. 3. Shrink fitting: The axle is cooled with liquid nitrogen (-198°c) so that it fits into the gap after contracting. It makes a tight fit after returning to normal temperature. 4. Hot riveting: A rivet is hammered in while hot and it makes a tight fit on contracting 5. Measurement of Temperature. Materials whose expansion is directly proportional to change in temperature can be used in thermometers for temperature measurement. E.g. mercury and alcohol are used in a liquid in glass thermometers. 6. Hot air balloons PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 33 Air inside expands as it is heated. This causes a reduction in density of the air inside. Since the density of air outside the balloon is higher the balloon rising due to convection. Consequences of Expansion 1. Railway line The ends of the rails are tapered and made to overlap to avoid bulging during a hot day. 2. Electric cables They are allowed to sag a bit so that in winter they do not become tight after contracting. 3. Bridges One end is fixed and the other end rests on rollers. An expansion gap is created to give room for expansion. The Unusual Expansion of Water When water is cooled, it contracts as expected until a temperature of 4oC is reached. Between temperatures of 4oC and 0oC, the water expands while it is being cooled from 4oC to 0oC. When the temperature of the water reaches 0oC, it expands even more as it freezes. See graph above. This is the reason why water bottles burst as the water freezes. As a consequence of its unusual expansion at 4oC, water has a maximum density at that temperature. This is why marine life can survive in a frozen pond( only the water at the top freezes while the water at the bottom remains a liquid). Ice cubes float in water for the same reason. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 34 IDEAL GAS LAWS Boyle’s Law The volume of a fixed mass of gas is inversely proportional to the pressure if the temperature is kept constant. P α 1/v P1 V1 = P2V2 Pressure law The pressure of a fixed mass of gas is directly proportional to its absolute temperature if the volume is constant P α T P1 P2 T1 T2 Charles Law The volume of a fixed mass of gas is directly proportional to the absolute temperature if the pressure is constant. V α T V1 V2 T1 T2 Classwork (when solving problems relating to gas laws all temperatures should be expressed in the absolute temperature scale) 1. If a certain quantity of gas has a volume of 30cm3 at a pressure of 1 x 105 Pa, what is its volume when the pressure is 5 x 105 Pa? 2. An enclosed mass of air occupies 4.0 x 103 m3at a pressure of 100 kPa, when the pressure is changed to 80 kPa, what will be the volume in m3 ? 3. A gas at a temperature of 5°c and pressure of 1.0 x 105 pa is heated until it reaches a temperature of 15°c, calculate the pressure of the gas. 4. A syringe has a gas at a pressure of 500 Pa. The temperature of the gas is 40°c. What will be the pressure of the gas if the temperature is reduced by half? 5. A container holds a gas at 0°c and pressure 0.5 x 105 Pa. To what temperature must it be heated for the pressure to double? 6. A quantity of helium gas occupies a volume of 60 cm3 at 25°c. The gas is then cooled until it occupies a volume of 15cm3, calculate the temperature of the gas. Absolute Temperature Scale (Kelvin Scale) PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 35 If the volume-temperature or pressure-temperature graphs for an ideal gas are plotted and then extrapolated or produced backwards, they are found to cut the temperature axis at -273 oC. This suggests that -273 oC is the lowest possible temperature. As a consequence this temperature is called absolute zero and is the zero of the absolute temperature scale (Kelvin scale). At this temperature molecular motion ceases the total internal energy is zero. This is only true for ideal gases. Practically this is impossible because gases generally liquefy before reaching -273 oC. it implies that that matter ceases to exist -273 oC( since the volume is 0 and the pressure is also 0 at this temperature). Relationship between the Kelvin and Celsius temperature scales TK= TC + 273 or TC= TK – 273 Where TK= temperature in Kelvin TC= temperature in °Celsius NB: The size of 1 Kelvin is the same as the size of 1oCelsius. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 36 MEASUREMENT OF TEMPERATURE Temperature is an indirect measurement of the average kinetic energy of particles in matter or the degree of coldness or hotness of matter. Thermometers are used to measure temperature. Measurement of temperature depends on physical properties of matter which change with a change in temperature. This include Thermal expansion Voltage Electrical resistance Colour Liquid in Glass thermometer A liquid-in-glass thermometer makes use of the thermal expansion of liquids to measure temperature. It is made of a capillary tube which is sealed at one end and has a liquid filled bulb at the other end. When the bulb is placed at a higher temperature, the liquid expands along the bore. If the bulb is placed at a lower temperature the liquid contracts back into the bulb. The liquid used in the thermometer should have a low melting point and a high boiling point. The liquid should also be clearly visible and should not stick to the sides of the bore. Commonly used liquids include mercury and alcohol. Mercury has a melting point of -39 oC and a boiling point of 357 oC. Alcohol has a melting point of -115 oC and a boiling point of 78 oC. Mercury is the least used because it is very toxic. A dye is added to alcohol to make it visible. Examples of liquid-in-glass thermometers include the laboratory thermometer as well as the clinical thermometer. Their design features are described below. Laboratory Thermometer PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 37 Design feature Purpose or working principle The liquid is contained in a thin The thin wall allows quick conduction of heat walled glass bulb. through the glass (a poor conductor of heat) to the liquid Small bulb Small bulb contains a small amount of liquid which will be more responsive to heat. Narrow uniform bore The narrow tube allows a noticeable movement of the liquid column for a small change in temperature(i.e good sensitivity). Thick capillary tube walls The uniform bore ensures even expansion of the liquid. Acts as a magnifying glass for easy reading of the liquid thread in the stem Clinical Thermometer Design feature Purpose or working principle The liquid is contained in a thin The thin wall allows quick conduction of heat walled glass bulb. quickly through the glass (a poor conductor of heat) to the liquid Small bulb Small bulb contains a small amount of liquid which will be more responsive to heat. Narrow and uniform bore The narrow bore allows a large change in length for the mercury thread for a small change in temperature (i.e good sensitivity). Oval shaped capillary tube walls Small range (35 oC to 42 oC) Constriction just above the bulb. PHYSICS NOTES: Physical Quantities & Measurement The uniform bore ensures even expansion of the liquid. Acts as a magnifying glass for easy reading of the mercury thread in the stem Normal human body temperature is around 36.9 oC, so the small range allows for greater accuracy and the stem can be made reasonably shorter. Prevents the backflow of mercury into the bulb before a reading is taken. PREPARED BY RAYMOND 2017© 38 Calibrating a liquid-in-glass thermometer Two points are marked first. These are the upper fixed point and the lower fixed point. Lower Fixed Point (0oC) The lower fixed point is the 0oC mark on a thermometer. The thermometer is placed in pure melting ice. Explain why the ice has to be pure. When all the liquid has stopped contracting, a mark is placed on the thermometer to indicate the lower fixed point. Upper Fixed Point (100oC) The upper fixed point is the 100oC mark on a thermometer. The thermometer is placed in the steam above pure boiling water. Explain why the water has to be pure. When all the liquid in the thermometer has stopped expanding, a mark is placed on the thermometer to indicate the upper fixed point. Calibrating the rest of the scale The rest of the scale is calibrated by measuring the length between the lower fixed point and the upper fixed point. This length is then divided by 100oC. Sensitivity of a thermometer A thermometer is said to be sensitive if it gives a large response to a small temperature change. A sensitive thermometer is able to detect small temperature changes. A thermometer can be made more sensitive by Using a large bulb. Decreasing the diameter of the bore. Range of a thermometer This refers to the temperatures that a thermometer can measure. Thermocouple PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 39 A thermocouple thermometer consists of two wires of different materials joined together at two junctions. When the two junctions are at different temperatures an electromotive force (emf) is induced. This emf is directly proportional to the difference in temperature between the two junctions and it causes current to flow through the wires. This current can be measured with a galvanometer. The two junctions are called reference and test junctions respectively. The reference junction is always placed at a constant temperature and the test junction is the one used for measuring the temperature. Advantages of the thermocouple thermometer. Used to measure rapidly changing temperatures Used to measure very high temperatures which makes them suitable for use in industries. HEAT CAPACITY When the temperature of a substance increases, the average kinetic energy of the particles in the substance is increased. This leads to an increase in the total kinetic energy of the particles in the substance. Thus an increase in the temperature of a substance leads to an increase in the heat energy of the substance. Heat Capacity The heat capacity of a substance is the amount of heat energy needed to raise the temperature of the substance by 1oC or 1K.. heat capacity PHYSICS NOTES: Physical Quantities & Measurement heat energy change in temperature PREPARED BY RAYMOND 2017© 40 Specific Heat Capacity, (c) The specific heat capacity of a substance is the amount of heat energy required to raise the temperature of 1kg of the substance by 1°C or 1K. specific heat capacity c Q m x heat energy mass x change in temperature or Q = m c ∆ The SI units are J kg-1K-1 (J/kg K ) or J kg-1 oC-1 (J/kg oC). Every material has its own specific heat capacity. Examples are given below. Specific heat capacity (J kg -1K -1) 4200 2100 400 460 130 Material Water Ice Copper Iron Lead Classwork 1. Calculate the amount of heat energy gained when the temperature of 5 kg of copper rises from 15 °C to 25 °C. 2. How much heat energy is lost when the temperature of 100g of water drops from 30 °C to 10 °C ? 3. A piece of aluminium mass 0,5 kg is heated to 100 °C and then placed in 0.4 kg of water at 10°C. If the resulting temperature of the mixture is 30°C, what is the specific heat capacity of aluminium? 4. A tank holding 50kg of water is heated by a 2.5 kW immersion heater. Estimate the time it takes for the temperature to rise from 150 C to 60oC. 5. A 1 kg lead ball is dropped from a 65 m tower. Calculate the change in its temperature on hitting the ground PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 41 Experiment to find the specific heat capacity of aluminium Apparatus Aluminum cylinder with two holes drilled in it. Immersion heater with power rating Triple beam balance or any other suitable scale. Thermometer Power supply Stop watch Procedure 1. Place the immersion heater in the central hole and the thermometer in the other as shown below. 2. 3. 4. Record the initial temperature of the block Connect the heater to a power supply and switch it on for 5 minutes. Wait until the temperature stops rising. Record the temperature and the time taken to reach this temperature. 5. Calculate the amount of heat supplied by the heater using the expression, Energy = power x time. 6. Assuming no heat loss, calculate the specific heat capacity of aluminium using the expression Q = mc∆. Changes of state Melting: A change of state from solid to liquid at a specific temperature called melting point. Freezing or Solidification: A change of state from liquid to solid without a change in temperature. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 42 Boiling; A change of state from liquid to gas at a specific temperature called boiling point. Condensation; A change of state from gas to liquid. Difference between boiling and evaporation EVAPORATION BOILING -Takes place at any temperature -takes place at definite temperature -Takes place at the surface of a liquid -Takes place within liquid Cooling curve A ……………………………………………………………………….…. B ………………………………………………………………………...... C ………………………………………………………………………...... D ………………………………………………………………………...... E ………………………………………………………………………...... Heating curve PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 43 A B C D E ……………………………………………………………………….…. ………………………………………………………………………...... ………………………………………………………………………...... ………………………………………………………………………...... ………………………………………………………………………...... LATENT HEAT Latent heat This is the hidden heat energy that is absorbed or released during a change of state Specific Latent heat of fusion,(lf) The specific latent heat of fusion is amount of heat energy required to change 1 kg of a body from solid to liquid (or liquid to solid) at constant temperature. Heat energy = mass x specific latent heat of fusion Q = m lf Specific Latent heat of vaporization,(lv) The specific latent heat of vaporization is amount of heat energy required to change 1 kg of a body of mass from solid to liquid. Heat energy = mass x specific latent heat of vaporisation Q = m lv Classwork 6. 7. How much energy is required to change 2 kg of ice in to water at 0 oC. Calculate the energy released when 1 kg of steam changes to water. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 44 How much heat is needed to change 40 g of ice at 0oC to steam at 100 oC. 8. 9. 10. Calculate heat needed to change 2 kg of ice at 0oC to steam at 100oC. How much heat is lost when 50 g of water at 60oC is changed to ice at -5oC? PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 45 TRANSFER OF THERMAL ENERGY There are three methods of thermal transfer and these are 1. Conduction 2. Convection 3. Radiation Conduction This is the transfer of heat through matter from areas of high temperature to areas of low temperature without the movement of matter. Conduction occurs mainly in solids and it is faster in metals as they have free or ‘lone’ electrons that can carry heat energy around. Liquids and gases are poor conductors of heat. The particles in a solid vibrate about fixed positions. When one end of a solid is heated the particles at that end vibrate faster and pass on their vibrations to the neighbouring particles. This causes the heat to be conducted along from one end of the solid to the other. Investigating Conduction The diagram below shows three solid rods. Pins are attached at the end of each rod with wax. The rods are then heated at one end with the same heat source at the same time. State the order in which the pins will fall and explain why. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 46 Convection Convection is a method of heat transfer in fluids (liquids and gases). During convection, matter moves. It is the transfer of heat from a region of high temperature to a region of low temperature by movement of the fluid itself. When a fluid is heated the fluid nearest the heat source is heated first, expands and becomes less dense. This less dense fluid moves up and is replaced by the more dense fluid from above. The colder fluid is heated and the whole process is repeated until the whole fluid is at the same temperature. The cyclic movement of the fluid as it is heated is called convection currents. Demonstrating convection in fluids. A convection tube is filled with water. A small amount of potassium permanganate is then placed in the water as shown below. The convection tube is then heated at one corner. The arrows indicate inside the tube indicate the direction taken by the purple colour of (KMnO 4). PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 47 Demonstrating convection in gases. The air around the candle flame is heated and expands. It becomes less dense, rises and escapes through chimney B. Colder air enters the chamber through chimney A due to convection currents. The convection currents carry with them some of the smoke particles and as such smoke enters through chimney A and escapes through chimney B. The arrows on the diagram indicate the direction followed by the smoke from the cloth. Radiation Radiation is the transfer of heat through electromagnetic waves. Radiant heat is emitted and absorbed by any object that is above absolute zero(-273oC). can pass through a vacuum, i.e. matter is not necessary for the transfer of heat through radiation. Infra-red radiation Investigating Good & Bad absorbers of radiant heat. The diagram below shows two cardboards placed at an equal distance from a heater. One cardboard is painted white while the other one is painted black. Metals pins are pasted to each cardboard with wax. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 48 Which of the two pins falls first? Explain why. Investigating Good & Bad emitters of radiant heat. Two test tubes, one painted black and the other painted white are filled with boiling water as shown in the diagram below. The two test tubes are then allowed to cool while the temperature of the water is measure over a period of time. Which of the two thermometers will show a quick fall in temperature? Explain why. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 49 Applications Of Thermal Transfer Methods Thermos flask A thermos flask is used to maintain liquids at a constant temperature. To do this they prevent heat loss/gain through radiation, conduction and convection. A thermos flask has the following basic features. Double walls: Used to create a vacuum. Plastic/cork lid: It prevents heat gain/loss through convection and radiation. Vacuum; It prevents heat gain/loss through conduction and convection. Silvered Walls Prevents heat gain/loss through radiation. They reflect back the incoming or outgoing radiation. School Uniform A white shirt is usually recommended to be worn during summer to absorb less heat. Jerseys are usually dark coloured to help the students absorb more heat during winter or cold weather. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 50 Domestic water heating system Cold water goes into the boiler at the bottom. Hot water rises through convection to the top of the storage tank. Car cooling system The arrows on the diagram shows the flow of the water. -Petrol burns in the engine cylinders -Water surrounding the engine cylinders become hot and rises to the top from where it is pumped to the radiator.. -Hot water rises to the top of the radiator by convection. -Heat is passed from the water to the radiator by conduction. -Heat is passed to the air from the radiator by conduction, convection and radiation. -Cool water flows from the lower end of the radiator back into the engine. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 51 Colour of pots & kettles as well as colours of houses in particular climates Cooking pots and tea pots are usually shiny so that they won’t lose heat quickly. In cold countries the colour of houses, vehicles are usually dark to help them absorb more heat while in hot area countries they are usually light coloured to absorb less heat during the day. Consequences of heat transfer in nature Land and sea breeze This occur next to bodies of water, e.g. lakes, dams, the sea, ponds etc. At night the land emits more heat than the water and as such becomes colder. The air above the water rises and cool air blows in from the side of the land. This is called a land breeze Tropical Cyclones -Air over warm parts of the sea becomes warm. -The warm air rises carrying moisture high into the atmosphere. -The movement of the earth causes the airflow to spin -This huge spinning mass of moist air is called a tropical cyclone. -It causes wet cloudy weather with strong winds. -If the winds become very strong(120-350 km/h) the storm is called a hurricane or typhoon. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 52 Days & nights in deserts Sand is a good absorber and emitter of heat. It has a very low specific heat capacity. During the day it absorbs a lot of heat and as such days are hotter in the desert. At night the sand emits most of its heat and as such nights can be very cold in the desert. Desert Breezes -During the day the desert sand becomes hotter than areas covered by vegetation. The wind is from forest to desert -At night the desert sand loses heat faster and warmer air rises from the forest and a breeze develops from desert to forest. Greenhouse effect - Radiant heat from the sub is absorbed by the earth - The earth becomes warm and emits heat most of which escapes back into space. - CO2.SO2, CO and CH4 gases in the atmosphere prevent some of this heat from escaping and as such it is trapped in the atmosphere. - An increase in these gases in the atmosphere means more heat is trapped and the atmosphere becomes warmer. - This is known as the Greenhouse effect. - The Greenhouse Effect gives rise to Global warming which in turn leads to climate change which could lead to extinction of some animal & plant species, melting of polar ice caps which results in flooding of coastal areas, Increase in violent storms (especially tropical cyclones) due to the increased energy in the atmosphere. Desertification in some areas. RADIOACTIVITY Radioactivity is the spontaneous emission of ionizing radiation by unstable nuclei. Radioactive Materials This includes Uranium, Carbon 14, Plutonium, Cobalt 60, Radium, Radon, Krypton, Strontium etc. Compounds of radioactive elements are also radioactive since the nucleus is not changed during a chemical reaction. Thus all uranium salts are radioactive. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 53 Properties of Radioactive Emissions. During the process of radioactivity three emissions may be given out. These are the alpha particles (α), beta particles (β) and gamma rays (γ). Some of the nuclei emit the three emissions while others two or only one. Emmision Gamma Nature Speed Charge Ionizing Power Penetration Power Deflection in electric field Deflection in magnetic field. Electromagnetic wave c 0 Weak High. Can only be stopped by thick concrete or at least 6cm of lead. No deflection Beta No deflection Alpha High speed electron 0.9c -1 Moderate Moderate Can be stopped by aluminium foil. Can travel 50cm to 100cm in air. Deflected towards positive plate Deflected according to Fleming’s left hand rule High speed helium nucleus 0.1c +2 high Weak Can be stopped by a piece of paper. Can only travel 10 cm in air. Deflected towards negative plate Deflected according to Fleming’s left hand rule Detection Of Radioactive Emissions. Ionising radiation can be detected with a; cloud chamber -photographic film, -a Geiger-Muler tube Background Radiation This refers to the ever present ionizing radiation that organism are exposed to, including from natural and artificial sources. Natural background radiation comes from radioactive nuclei in rocks, water, air, vegetation, food, etc. Artificial background radiation comes from radioactive nuclei used in hospitals, nuclear power stations, nuclear weapons testing sites, nuclear power accidents, etc. Dangers of exposure to radioactive emissions. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 54 1. 2. 3. 4. 5. 6. 7. 8. It may cause mutations. (leading to birth defects). It may lead to cancer. It can lead to sterility It can cause cataracts, loss of hair, sickness, or death. Ionizing effects kill living tissue. Exposure to gamma rays can cause severe radiation burns. Greatest hazard with beta sources is when ingested (via food or water) or inhaled. Alpha particles are a danger only if taken into the body but are more dangerous than beta particles. Safety precautions when using radioactive materials. 1. Sources should be placed in containers made from thick lead. 2. Radioactive labs should be constructed from thick concrete and have windows made from lead. 3. Working area along with its air content should be monitored. e.g with a Geiger counter. 4. Protective clothing should be worn. 5. Washing facilities should be readily available. 6. Time spent with source should be limited 7. Remote handling techniques should be used. 8. Work should be carried out behind shielding or at a distance from the radiation source. 9. Film badges should be worn to detect radiation levels. Uses of radioactive materials 1. 2. 3. 4. 5. 6. 7. 8. Detection of leaks in pipes Thickness gauges, eg production of papers/metal sheets. Gamma rays are used to sterilize food and medical equipment. Chemotherapy and Radiotherapy Pacemaker batteries Tracers in plants to study the pathway of minerals in water. Production of electricity Radio carbon dating. Radioactive waste disposal Radioactive waste should be sealed in lead containers and buried deep underground in concrete bunkers. The Nucleus. The nucleus of an atom (also called a nuclide) consists of particles called nucleons. This refers to protons and neutrons. The notation below is used to denote a nuclide. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 55 Z A X Where X = nuclide name Z = mass number or nucleon number A = proton number. Isotopes This refers to nuclides with the same A but different Z or any of two or more forms of an element where the atoms have same proton number but different electron number. Examples of isotopes include Carbon 12 and Carbon 14. Nuclear Reactions Nuclear reactions take place in the nucleus and are responsible for radioactive decay or radioactivity which emits radioactive emissions. Alpha decay During alpha decay a nuclide releases a helium nucleus, since it loses two protons and two neutrons. Thus Z decreases by 4 while A decreases by 2. Z A X → + Z -4 A 2 Y Beta decay During beta decay a neutron splits into a proton and an electron. The proton remains in the nucleus while the electron is ejected from the nucleus at very high speed. Thus Z remains the same while A increases by 1. Z A X → 1 + Z A 1 Y Gamma decay Alpha and beta decay results in the formation of a new energized nucleus. This energy is released as a burst of gamma rays when the nucleons reconstitute in the nucleus. Thus gamma decay does not result in the formation of a new nucleus. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 56 Nuclear Energy Nuclear energy is the use of exothermic nuclear processes to generate useful heat and electricity. This includes nuclear fission and nuclear fusion. Nuclear energy is calculated with the equation E mc 2 Nuclear Fission During radioactive decay is energy is released, most of it in the form of gamma rays but some is released in the form of neutrons. If one of these neutrons hits a large energized nucleus, the nucleus may split into two equal parts (sometimes three) releasing energy and more neutrons. This is called nuclear fission. Example Uranium 235 is bombarded with a neutron. 235 92 U n 1 137 0 54 Xe 96 38 Sr n n n 1 1 1 0 0 0 The newly formed nuclei are called fission fragments or daughter nuclei, while the one hit by the neutron is called the parent nuclei. The newly released neutrons are called fission neutrons and can go on and hit other nuclei. This would result in a chain reaction which takes place very fast and may cause an explosion if not controlled. Boron rods are used to absorb some of the neutrons so that the rate of reaction is slowed down. The diagram below illustrates a chain reaction. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 57 The energy released during chain reactions is harnessed in a nuclear reactor, and can be used to produce electricity in a nuclear power station or to power submarines( and other military ships). Nuclear Fusion Two or more nuclei are joined together to form a larger nucleus. 2 1 H H He n 3 4 1 2 2 0 For this process to start, very high temperatures are required. Nucleus fission starts the process. The sun provides it’s energy by nuclear fission. Advantages of nuclear energy Little fuel is needed to produce a lot of electricity.(Only 7 kg of uranium fuel are needed to produce 60 000 W of electricity per month) Does not release toxic gases into the atmosphere (no greenhouse gases released, therefore does not cause global warming.) It does not produce smoke particles to pollute the atmosphere. It is reliable. It does not depend on the weather. Disadvantages of nuclear energy. Uranium mining exposes people to radio-active dust and radon gas Fuel processing is strenuous and expensive Nuclear power is not renewable. Supply of high quality uranium, one of the raw material, will last only for a few decades. A large amount of nuclear waste is also created and disposal of this waste is a major problem because The waste is radioactive and remains active for long periods of time. It creates heat pollution which is harmful to the environment. Nuclear waste can also be used to make nuclear weapons. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 58 Starting a nuclear plant requires huge capital investment and advanced technology. There are number of restrictions on the export or import of nuclear technology, fuels etc. Proliferation of nuclear technology increases the risk of nuclear war too. HALF LIFE OF RADIOACTIVE ELEMENTS The half life of a radioactive element is the time it takes for half of the radioactive atoms in a sample to decay. Examples Uranium 238 4.5 x 106 years Uranium 235 700 x 106 years Uranium 232 69 years Plutonium 238 88 years Plutonium 239 24 110 years Carbon 14 5730 years Carbon 15 3 seconds Cobalt 60 5 years Cobat 57 271 days Radium 1600 years Iodine 8 days No of half lives elapsed Fraction remaining 0 1 1 1 2 1 3 1 4 1 5 1 n 1 n /2 /2 /4 /8 /16 /32 where n= number of half lives. Classwork 1. How long will it take 2g of Radium sample to decay to 0.5g. Find the number of years that it would take Carbon 14 to decay to 1/8 of it’s original 2. sample. 3. If 300 atoms of radiation iodine remain after 40 days of decay, find the original number of the atoms given that iodine has a half life of 8 days. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 59 4. A sample of thoron gas undergoes radioactive decay. If the original mass was 64g, what was the radioactive mass left after 208 seconds? (half life of gas is 52 seconds) DECAY CURVE A decay curve is an exponential graph displaying the decrease of radioactivity with time. It could be a plot of no of atoms or mass or activity vs time Activity or count rate – the average number of decays per second. SI units- Bequered (Bq). MAGNETISM Properties of Magnets; 1. All magnets have two poles. These are the north pole ( N pole) and the south pole ( S pole).These two poles can NOT exist independently. 2. All magnets obey the Law Of Magnetic Poles which states that “Like poles repel and unlike poles attract”. 3. All magnets attract magnetic materials. These include iron, cobalt, nickel and alloys like alcomax, alnico and steel. 4. A freely suspended magnet always comes to rest with its north pole pointing towards the earth’s north pole and its south pole pointing towards the south pole. Magnetic And Non-Magnetic Materials PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 60 Magnetic materials are those which can be attracted by magnets while non-magnetic materials can not. Magnetic materials are used to make magnets because they can acquire magnetism. They can be divided into two groups. These are Hard Magnetic materials and Soft Magnetic materials. Hard magnetic materials are difficult to magnetise and demagnetize. They are used to make permanent magnets. Examples include steel, alcomax alnico etc. Soft magnetic materials are easy to magnetise and demagnetize. They are used to make temporary magnets. Examples include iron, cobalt and nickel. Induced magnetism When a piece of an iron bar is brought very close to some iron filings, there is no attraction between them. However if a magnet is brought close to the iron bar it is seen to immediately attract the iron filings. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 61 The iron bar behaves like a magnet if and only if it is still attached to a permanent magnet. When the magnet is removed the iron fillings quickly drop away. This is because iron is a soft magnetic material. If a steel bar is used the iron filings will stay attached to the steel bar for a little longer after removing the permanent magnet. Magnetisation There are two methods of magnetisation. These are Stroking and use of Electricity. Stroking method The steel rod is stroked from end to end about 30-20 times in the same direction by the same pole of the magnet. The pole induced at the end of the rod where stroking begins is the same pole as the stroking pole. In the diagram above end B will become the South pole. If the rod was stroked with the PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 62 north pole then end B will become the North pole. The poles can also be identified using the law of magnetic poles. Electricity method A steel rod is placed inside a solenoid (a cylindrical coil wound with 500 or more turns of insulated wire) which is connected to a direct current(dc) supply. The switch is then closed for a few seconds. The rod will be found to be magnetized. The polarity of the magnet is given by the right hand grip rule [if the fingers grip the solenoid in the direction of the current, the thumb points to the North Pole]. In the diagram above P is the _______________ pole while Q is the ______________ pole Demagnetisation Electrical Method The magnet is placed inside a solenoid which is connected to an alternating current supply. While the current is on, the magnet is slowly removed from the solenoid to some 2-3 metres away from solenoid. Other Methods Magnets can also be demagnetized by heating and hammering as well as poor storage. Magnetic Saturation All magnetic materials are assumed to be made up of tiny magnets called magnetic domains. When the domains are haphazardly aligned then the material does not exhibit the properties of a magnet. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 63 If some of the the domains are aligned in the same direction, then the magnetic material starts acting like a magnet. If all domains are aligned in the same direction then Magnetic Saturation has been acquired as shown below. Magnetic saturation is the point beyond which the strength of the magnet can NOT be increased. Magnetic Fields A magnetic field is the region within which a magnet exerts its magnetic force. Magnetic field lines Magnetic filed lines or lines of force are used to illustrate the magnetic field around a magnet. They begin at the N-pole and end at the S-pole They do not cross They are concentrated at the poles. Field around a single magnet PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 64 Field between unlike poles Field between similar poles X refers to a point where the net field is zero. This point is called the neutral point. The magnetic field around a magnet can be detected using using a plotting campus as well as iron filings. Using a plotting campus Lay a bar of magnet on a sheet of paper. Place a plotting compass at a point near one of the poles of the magnet. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 65 Mark the position pointed by the arrow of the ploting compass. Move the compass so that the beginning of the arrow is exactly over the position you marked. Mark the new position pointed by the compass arrow. Continue the process until the south pole of the magnet is reached .Join the dots to give one line of force and show the direction of the field or force by putting arrows on it. Iron filling method A plain paper is placed above a magnet and iron fillings are sprinkled on top of the paper. The iron fillings should form a pattern of the field lines of force. Electromagnets An electromagnet is a temporary magnet and its magnetism can be switched on and off. It consists of an insulated wire wound around a soft magnetic material. This is then connected to a direct current supply. The strength of the electromagnet can be increased by either increasing the current in the coil increasing the number of turns in the coil bringing the poles closer to each other. Electromagnets are used for; Lifting scrap metal Tape recording Relay /reed switch Electric bell PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 66 Magnetic shielding /screening When a short iron bar is placed in a magnet field, the field appears to be drawn towards the bar and concentrated through it. The magnetic field passes through the bar but around it since iron is a soft magnetic material. If an iron ring is placed in a magnetic field, the field does not pass inside the ring, Thus iron rings/boxes iron boxes can be used to protect equipment that can be affected by magnetic fields. This is known as magnetic shielding/screening. ELECTROSTATICS [Static Electricity]. Static electricity refers to charge that is not moving i.e. stationary charge. An insulator can be charged electrically by rubbing it while a conductor cannot. Types Of Charge There are two types of charge. These are Positive [+] and Negative [-]. The SI unit of charge is the Coulomb (C) Negative charge is acquired if excess electrons are gained and positive charge is gained if electrons are lost. NB: Positive charge arises as a result of a deficiency of electrons. All charges obey The Law Of Electric Charges which states that “like charges repel and unlike charges attract” Electric charges can exist independent of each other. Electrostatic Charging Methods of electrostatic charging include (i) (ii) Charging through contact Charging through induction Charging Through Contact When a polythene rod is rubbed with a cloth it becomes negatively charged. Electrons flow from the piece of cloth into the polythene rod. As a result the cloth attains a positive charge. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 67 On the other hand an acetate rod becomes positively charged when rubbed with a piece of cloth. Electrons flow out of the acetate rod into the cloth which then becomes negatively charged. The rods and cloths described above became charge through contact. Charging through induction Charging through induction can be achieved in two ways- by earthing as well as through separation of charges. Charging through separation of charge. This can be illustrated by placing two metal spheres A and B next to each other so that they are in contact. A charged strip is then brought close to the metal spheres, but not touching them. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 68 This causes a separation of charges in the two spheres. All negative charges are attracted from sphere A to B. On being separated, the two spheres are found to be ; A- Positively charged B- Negatively charged Charging through earthing A charged strip is brought close to a neutrally charged metal sphere. See (a) below. This causes a separation of charge within the sphere itself. See (b) below. Earthing the sphere causes the negative charge to be repelled by the strip to the ground. See (c) above. This leaves the sphere with a net positive charge. See (d )above. Detecting Charge Charge can be detected through the use of a Gold Leaf Electroscope. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 69 When a charged object is brought close to the metal cap, the gold leaf deflects upwards. This happens because both the stem and the leaf have the same charge and as such repel each other. To find out the nature of the charge on the object; the electroscope has to be charged first.i.e only a charged electroscope can be used to detect the type of charge in an object. Discharging Discharging refers to the loss of excess charge. It takes place through contact or ionization. Dangers of ionization are minimized by earthing. Lightning Conductor As clouds move overhead they gain a negative charge. When excess charge has been accumulated in the cloud it is discharged to the ground through ionization. This is called lightning. Lightning is dangerous and it’s effects can be minimized through the use of a Lightning Conductor. A lightning conductor discharges a cloud before it discharges on its own. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 70 The lightning conductor should be made from a good conductor of electricity and it should be taller than the structure it is protecting. When clouds move through the sky they acquire a negative charge. As they pass above the lightning conductor they induce a positive charge in the spikes at the tip of the lightning conductor. Since charge accumulates at sharp points, the positive charge at the tip of the spikes is large enough to ionize the air molecules around them by attracting electrons from them. These electrons are repelled down the lightning conductor to the ground.. The resulting positive ions are attracted by the negatively charged cloud. Thus an electric wind of positively charged particles moves from the spikes to the cloud where they neutralize its negative charged. Electric Fields PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 71 The electric field is a region in which a charged particle exerts its electric force. Electric fields are illustrated with the help of electric field lines which begin at the positive charge and end at the negative charge. Field around single charges. positive charge negative charge Field between simmilar charges. Field between 2 unlike charges. Field between 2 positively charged plates. ELECTRICITY Electric Current, I Current is the rate of flow of electric charge. Conventional current flows from positive to negative but the flow of electric charges is from negative to positive. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 72 current I charge time where Q t I = current Q = charge t = time The SI units of current are Amperes(A) or Coulomb per second (C/s). Current is measured with an ammeter. The circuit symbol for an ammeter is ammeter is always connected in series with other circuit components. . An Potential Difference (pd) or Voltage,V This refers to the electrical energy needed to drive a charge between two points in a circuit. voltage electricalenergy charge V E Q Where V = voltage E = electrical energy Q = charge The SI units of voltage are Volts(V) or Joules per Coulomb (J/C). NB: One volt is the energy needed to drive a coulomb of charge around a circuit. Voltage is measured with a voltmeter. The circuit symbol for voltmeter is voltmeter is always connected in parallel with other circuit components. . A Electromotive force(emf) This is the electrical energy required to drive a charge round a circuit by a power supply. A voltmeter is connected across the power supply in order to measure the emf. Resistance, R PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 73 Resistance is the opposition to flow of current. SI units of resistance are Ohms (Ω). An ohmmeter can be used to measure resistance. Resistivity The resistance of a conductor is indirectly proportional to the cross sectional area(A) of the conductor . R α directly proportional to the length (l) of the conductor. R l 1 A Combining the two R α l A R ρ l A Where R = Resistanceof the conductor l = length of the conductor = resistivity of the conductor A = cross-sectional area of the conductor. Resistivity of any material is constant. For example the resistivity of copper is 1.8 x 10-8 m and nichrome (an alloy) has a resistivity of 110 x 10-8 m. Ohm’s Law The current (I) through a conductor is directly proportional to the voltage (V) across the conductor, provided temperature and other conditions remain constant. V = IR Where V = voltage I = current R = resistance. V/I Characteristic Graphs PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 74 Ohmic Conductor Filament bulb Thermistor Electrical Energy I Q t Q = It ……………………………..(i) V E …………………………..(ii) Q Using eqn (i) in eqn (ii) V E It Rearranging the eqn E IVt Where E = electrical energy I = electrical current V = voltage t = time Electrical Power, P Power Energy time but PHYSICS NOTES: Physical Quantities & Measurement Energy IVt P IVt t PREPARED BY RAYMOND 2017© 75 P IV Where P = electrical power I = electrical current V = voltage Series Circuits In a series circuit there is only one pathway for current. Current in Series circuits The current is the same at all points in a series circuit A1 = A2 = A3 and therefore I1 = I2 = I3 Voltage in a Series Circuit. In a series circuit there is a potential drop across the circuit components. Thus the sum of the voltages across the circuit components should give the emf. VT = V1 + V2 + … Resistance in a series circuit. The total resistance, RT for resistors R1, R2, R3,etc which are in series is given by RT = R1 + R2 + R3 + … PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 76 Parallel Circuits This is a circuit in which there is more than one pathway for current. Current in parallel circuits Current divides among the several pathways in a parallel circuit. AT = A1 + A2 IT = I1 + I2 + … Voltage in parallel circuits The voltages across parallel circuit components are equal. VT = V1 = V2 Resistance in parallel circuits The total resistance, RT for resistors R1, R2, R3, etc which are parallel is given by 1 1 1 1 ... RT R1 R2 R3 PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 77 PRACTICAL ELECTRIC CIRCUITRY USES OF ELECTRICITY Electricity is used in Lighting Machines Security Communication Heating COST OF ELECTRICITY Cost of electricity = cost per unit X no of units No of units = time in hours X power in kilowatts. [ 1 unit is equal to 1 kilowatt-hour.(kWh)] Example. If BPC sells electricity at P0.55 per unit, calculate the cost of using two 100 W bulbs for ten hours. No of units Cost = 2 x 100W x 10 hrs = 2 x 0.1 kW x 10 hrs = 2 kWh = 20 kWh x P0.55 = P1.10 DANGERS OF ELECTRICITY (a) (b) (c) (d) Damaged Insulation An electric shock can occur if a current flows from the electric circuit through a person’s body to the Earth. This can happen when someone touches the exposed part of the wire carrying current (live wire). Overheating Of Cables When current increases through a conductor, the amount of heat energy lost due to the resistance of the wire increases. This can lead to explosion, fire or the cables overheating. Damp Conditions Water can conduct electricity. When the body is wet, the resistance of the body decreases hence more current can flow through the body. One can get a shock if s/he operates an appliance with wet hands since water can conduct electricity. Overloading A Socket When a socket is overloaded with many appliances, the current from the mains increases which will lead to increased heat produced by cables. This can cause the insulating material to melt or cause an explosion or fire. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 78 SAFE USE OF ELECTRICITY Fuses This is a safety device made from tin coated-copper wire. It has a low melting point such that it melts and breaks the circuit when current through it exceeds a certain value called the fuse rating. This could be due to short circuits or overheating of cables. A fuse ensures that the current carrying capacity of the wire is not exceeded. To calculate the fuse rating one has to know the power rating of the device. For example, a 3kW 240V electric fire needs a current of about Therefore a 13A fuse is recommended. Fuses and switches are always connected to the live wire so as to isolate the appliance from the current source when the appliance is not in use or in case of a short circuit. Earthing Appliances that are made of metal on the outer case must be earthed as a safety precaution. This connects the body of the appliance to the ground. When the device is faulty or the ‘live’ wire breaks and touches the metal case, the earth wire will channel the charge to the ground to prevent any electric shocks. Double Insulation Appliances that are made from non-metal outer case are usually double-insulated using a tough, stiff non-conducting material. This prevents electric current to flow to the user in case there is a fault. Devices that are double insulated carry the sign below. 3 Pin Mains Plug Earth wire (green or/and yellow). This is connected to the earth pin. Live wire (brown). This is connected to the live pin. It carries live current to the circuit. Neutral wire (blue). This is connected to the neutral pin. It is earthed at the power station. RING MAIN CIRCUIT PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 79 ELECTROMAGNETIC EFFECTS ELECTROMAGNETIC INDUCTION A change in the magnetic field around a conductor induces an emf in the conductor. The magnetic field around a conductor can change in several ways including moving the conductor into and out of a magnetic field or moving a permanent magnet around a conductor. In the diagram below a conductor is being moved in a magnetic field. An emf will only be induced in the conductor if it cuts the magnetic field, i.e. if the conductor is moving perpendicular to the field as shown by the arrows in the diagram above. No emf will be induced if the wire moves parallel to the magnetic field or if the conductor is not moving (stationary). The direction of induced current is found by using Fleming’s right hand rule. The thumb represents the motion of wire, the first finger represents the direction of the magnetic field and second finger represents the direction of the induced current. NB. All three fingers should be perpendicular to each other. In the diagram above when the conductor is moved upwards the current flows from ___ to ___ and when it is moved downwards the current flows from ___ to ___. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 80 If the conductor is coiled, then the direction of the induced emf is given by Lenz’s law which states that the direction of induced current is such that it opposes the change causing it. In the diagram above the north pole of the magnet is being moved away from end Q of the solenoid. According to Lenz’s law this will induce a south pole on end Q of the solenoid. The outward motion of the magnet will then be opposed since unlike poles attract. The direction of current in the coil can then be determined using the Right Hand Grip Rule. The current moves from ___ to ___. In the diagram above the north pole of the magnet is being moved into end Q of the solenoid. According to Lenz’s law this will induce a north pole on end Q of the solenoid. The inward motion of the magnet will then be opposed since like poles repel. The direction of current in the coil can then be determined using the Right Hand Grip Rule. The current moves from ___ to ___. Factors that affect the size of the induced current are, 1. Speed of movement of the wire. 2. Strength of the magnet. 3. Number of times the conductor has been wound. Simple Alternating Current Generator PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 81 A simple a.c. generator comprises a rectangular coil, slip rings, carbon brushes and a permanent magnet. When the coil is rotated within the magnetic field, an emf is induced as the coil cuts the magnetic field lines. Thus maximum emf is induced when the coil is parallel to the field and zero emf is induced when the coil is perpendicular to the magnetic field. The induced current reverses direction after every half cycle to create an alternating current. The output voltage is illustrated below Transformers A transformer is used to step down or step up voltage. It operates on the principle of mutual induction which states that a change in the magnetic field of a coil induces an emf in a neighbouring coil. The emf is induced because the magnetic fields cut the conductor in the secondary coil. The induced emf is enhanced by putting the coils on a soft iron core so as to increase magnetic field. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 82 The diagram below shows two coils A and B which are placed next to each other. Coil A is connected to a d.c. power supply while Coil B is connected to a centre zero galvanometer. When switch S is closed the pointer deflects in one direction and goes back to rest position. When the switch is opened the pointer is deflected in the opposite direction and goes back to rest position. When the switch is left closed or opened there is no deflection of the pointer. Coil A is the primary coil and Coil B is the secondary coil. The voltage in the primary coil is the primary voltage (Vp) and the voltage in the secondary coil is called the secondary voltage (Vs). Step-down Transformer (Vp > Vs) A step down transformer has more turns in the primary coil than in the secondary coil. (N p > Ns). Step-up Transformer (Vs > Vp) A step up transformer has more turns in the secondary coil than in the primary coil. (Np < Ns). Transformer equation The voltages in the secondary and primary coils of a transformer are related through the expression secondary voltage primary voltage secondary turns primary turns Vp Vs Ns Np Energy loss in a transformer According to the principle of energy conservation the energy input into a transformer should be equal to the energy output from the transformer. Thus the power in the primary coil should be equal to the power in the secondary coil, i.e. IpVp = IsVs PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 83 However transformers are not 100 % efficient, that is the some of the input energy is not converted to useful energy but is lost due to several factors including; i ii iii resistance of the windings. Resistance of a conductor increases with its length and due to the length of the conductor in the coil some energy is lost as heat. eddy currents. This are currents which are induced in the soft iron core of the transformer itself and they cause energy loss due to heat. The soft iron core in transformers is laminated to try and reduce eddy currents. leakage of field lines. Not all the field lines from the primary coil cuts the secondary coil, and as such cause energy loss from the transformer. Transmission of electrical power Power stations generate electricity at more than 10 000V. This is then stepped up to more than 200 000V before it can be transmitted over long distances. When it gets to a town or village, the voltage is stepped down to a suitable voltage at a substation. This is done to reduce the amount of energy lost due to the length of the transmission lines. Magnetic Effects of Current Magnetic Field around a Current Carrying Conductor A current carrying conductor has a magnetic field around it. The direction of the field can be shown with the help of the Right Hand Grip rule [Thumb points in direction of current while the fingers indicate the direction of the field around the conductor]. The strength of the field can be increased by coiling the conductor. A coiled conductor is called a solenoid. The strength of the magnetic field around a solenoid can be increased by 1. Increasing the number of turns 2. increasing the current 3. inserting a soft magnetic material into the coil to form an electromagnet. Magnetic field around single current carrying conductors. Magnetic field around parallel conductors carrying current in same direction PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 84 Conductors carrying current in opposite directions attract each other. The region labelled X represents the neutral point. At this point the net field is ZERO because the two magnetic fields cancel each other out. Magnetic field around parallel conductors carrying current opposite directions Parallel conductors carrying current in opposite directions repel each other. This is because the field between the two conductors add up. The Motor Effect Current carrying conductor in a magnetic field. A current carrying conductor experiences a force in a magnetic field. The direction of the force can be determined with the help of Fleming’s left hand rule; First finger – direction of field Second finger – direction of current Thumb – direction of the motion. In the diagram below the conductor will move as indicated. The fields above the conductor add up while the fields beneath the conductor cancel each other out. Consequently there is a resultant motion of the conductor towards the side where the field is weaker. In the diagram below the conductor will move as indicated. The fields above the conductor cancel out each other up while the fields beneath the conductor add up. Consequently there is a resultant motion of the conductor towards the side where the field is weaker. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 85 Reversing the field or the current also causes the direction of motion to change. Simple DC Motor A simple DC motor consists of a rectangular coil abcd as shown above. The coil is mounted on an axle between the poles of a magnet. When current passes through the coil it experiences a turning effect about the axle. The direction of rotation can be determined using Fleming’s Left Hand rule. The turning effect of the coil can be increased by 1. increasing the number of turns in the coil 2. increasing the current 3. Inserting a soft magnetic material in the coil. In the diagram above the split-ring commutator ensures that the side of the coil that is next to the North Pole is always in contact with the positive brush, while the side of the coil next to the South Pole is always connected to the negative brush. This ensures that rotation is always in the same direction. Practical electric motors are used to provide kinetic energy for different purposes including domestic and industrial. Such motors are different from the simple dc motors in that the magnetic field in which the coil spins is provided by an electromagnets instead of a permanent magnet. Several coils are used in one motor The coils have multiple turns They use alternating current. Moving Coil Loudspeakers. It consists of coil which is attached to a paper cone. The coil is inserted in a pot magnet. Varying currents from an amplifier pass through the coil, which causes a force to act on the coil. The direction of this force can be determined using Fleming’s Left Hand Rule. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 86 Since the current to the speaker is alternating the coil experiences a to and fro movement within the pot. This causes the vibrations in the paper cone thus producing sound. Microphones A microphone works like a loudspeaker in reverse. Thus it operates like a simple ac generator. The paper cone picks up sound waves from the air which cause the paper cone to vibrate and as such causes the coil to move in and out of the pot magnet. This results in a small alternating current to be induced in the coil. THERMIONIC EMISSION Cathode Rays When certain metal filaments are heated, electrons on their surface may gain enough thermal energy to escape. This release of high speed electrons from the surface of a hot filament is known as thermionic emission. Beams of electrons released during thermionic emission are called cathode rays. Properties of cathode rays They have a negative charge They travel at very high speeds They are deflected towards the positive plate in an electric field. They are deflected according to Fleming’s left hand rule in a magnetic field.(flow of convetional current is opposite to direction of cathode rays) PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 87 Cathode Ray Oscilloscope Basic structure The cathode ray oscilloscope consists of three parts. These are the electron gun, the deflection system and the screen. The electron gun consists of the anode and the cathode. The deflection system consists of the X-plates and the Y-plates. Part Electron gun Heater/fillament Cathode PHYSICS NOTES: Physical Quantities & Measurement Function Heats the cathode. Emits electrons when hot PREPARED BY RAYMOND 2017© 88 Anode Deflection system Y-plates X-plates Fluorescent screen Accelerates and focuses electron beam Deflects beam of electrons vertically Deflects beam of electrons horizontally Displays the pattern of movement of the beam. Function The cathode ray oscilloscope can be used among other things to measure potential difference. measure short time periods. display waveforms of alternating potential difference. Input voltage is applied across the Y plates. INTRODUCTORY ELECTRONICS Circuit Components Colour coded resistors Resistors are used in electrical circuits to control the amount of current flowing through the circuit. First Band – 1st digit of the resistance Second band – 2nd digit of the resistance PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 89 Third band – no of zeros. Fourth band – tolerance. Diode A diode is a circuit component which allows current to pass in one direction only. Circuit symbol PROPERTIES OF WAVES Definition Of Terms Wave A wave is a disturbance in a medium which carries energy. Wave front It can be the position of the crests of a wave shown by straight lines. A wave front is always perpendicular to the direction of the wave. Think of a wave front as the crest of a transverse wave or the compression of a longitudinal wave. Fig 1.10 Wave fronts When a stone is dropped in a pond, at the point where the stone hits the water surface, circular ripples are formed which expand outwards. These are water waves travelling in a circular wave front. If you’ve watch an object floating on the water after it has being disturbed, you will notice that the object moves up and down in its original position. . Displacement-Displacement Graph This graph can be used to show wavelength and amplitude. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 90 Fig. 3.10. A dispacement-displacement graph Wavelength (λ)It is the distance between two (2) similar but successive points on a wave. It is denoted by the Greek letter lambda (λ) and it is measured in metres (m From Fig. 3.10, A and C are similar and successive, therefore the distance between A and C can be the wavelength of the wave or the distance between B and D. Amplitude: It is the maximum displacement of a vibrating particle from the undisturbed or rest position. From Fig. 3.10. a, is the amplitude of the wave. Displacement-Time Graph This graph can be used to show period and amplitude. Fig. 3.20. A dispacement-time graph. Period (T): The time taken make a complete wave is called the PERIOD (T).From Fig. 3.20 P and R are similar and as such PR is gives us the period of the wave. The same applies to QS. Other Terms. Frequency (f) It is the number of complete waves made in a given period of time. Also frequency can be the number of waves passing a point in a given period of time. It is measured in HERTZ (Hz). Frequency = number of waves/vib rations/oscillations total time taken Frequency is the inverse of period such that PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 91 T= 1 f and f = 1 T Wave Speed ( ): It is the displacement of a wave per unit time. It is measured in metres per second (m/s). The Wave Equation The relationship between the speed, wavelength and the frequency of a wave is given by the equation Wave speed = wavelength x frequency =λf Types of Waves Transverse Waves These are the waves produced when particle displacement is perpendicular to the direction of the wave. Fig. 2.1 shows the particle displacement in relation to the wave motion. Fig. 2.10. Particle displacement in a transverse wave. They are characterized by crests and troughs. Examples include: Water waves, EM waves and secondary seismic waves. Longitudinal waves These are the waves produced when particle displacement is parallel to the direction of the wave. Fig. 2.21 shows the particle displacement as a longitudinal wave passes through matter. Fig. 2.21. Particle displacement in a longitudinal wave. They are characterized by compressions and rarefactions as shown below PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 92 Examples include: Sound waves, shock waves from explosions and primary seismic waves. Classwork 1. The waves below are traveling across water. 2. Calculate i. Wavelength of the waves. ii. Period of the waves iii. Frequency of the waves. iv. Wave speed The lines in the diagram below are crests of straight water waves i ii. What is the wavelength of the wave? If wave A occupied 5 seconds ago the position now occupied by wave F, what is 3. the frequency of the wave? iii. What is the speed of the wave? A set of waves has a period of 10 seconds. If their speed is 2 m/s calculate their wavelength. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 93 Reflection, Refraction and Diffraction of Waves Waves can undergo reflection (bounce back), refraction (bend) and diffraction (spreading out). Water waves traveling from deeper water to shallow water will undergo a change in speed and the wavelength while the frequency remains the same. The speed and the wavelength decreases. This is due to refraction. Reflection of waves Refraction of waves Water waves traveling over a straight wave front spread out when they pass through an opening. Water waves passing over a narrow opening behaves as if they are produced by a point source (that is they become circular). This phenomenon is called DIFFRACTION. Diffraction of waves PHYSICS NOTES: Physical Quantities & Measurement Diffraction of sea waves as they pass into a harbour. PREPARED BY RAYMOND 2017© 94 Classwork 4. In the diagram below light waves are incident on an air-glass boundary. Some are reflected and some are refracted in the glass. (i) (ii) Which of the following is not the same for the incident and refracted waves? frequency, wavelength, direction, speed, brightness Complete the diagram above to illustrare the refracted and reflected waves. Electromagnetic Waves These are waves which make up the electromagnetic spectrum. The waves in the spectrum are continuous. Components Of The Electromagnetic Spectrum The electromagnetic spectrum has seven components PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 95 Fig. 1.0 The electromagnetic spectrum The components of the spectrum arranged in order of increasing wavelength are 1. 2. 3. 4. 5. 6. 7. Gamma rays X-rays Ultra-violet Light Infra-red Microwaves Radio waves Properties of Electromagnetic Waves They carry energy from one place to another and can be absorbed by matter to cause heating and other effects. Waves with shorter wavelength have high frequency and carry the greatest energy. They are transverse in nature They can travel in a vacuum. They travel at a speed of 3.0 x 108 m/s in vacuum. This is usually called the speed of light although it is the speed of all EM waves. The waves are a combination of travelling electric and magnetic fields which are perpendicular to one another. They obey the wave equation [v = λf] such that C = λf where C is the speed of EM waves and is a constant (3.0 x 108 m/s). They are transverse in nature They can be reflected, refracted and diffracted. Sources, Methods of detection and Uses of EM waves. wave Gamma Rays Sources Emitted by radioactive materials. Cosmic rays Nuclear reactions PHYSICS NOTES: Physical Quantities & Measurement Detection Photographic film Geiger Muller tube. Uses Radiotherapy to treat cancer. Chemotherapy to treat cancer Sterilizing food and medical eq Checking for flaws in metal cas Gamma photography As a tracer in plants to stu minerals. In metal factories to control metal bars. PREPARED BY RAYMOND 2017© 96 X-Rays X-ray tubes Cosmic rays Photographic film Geiger Muller tube. UltraViolet (UV) Photographic film Fluorescent materials (they glow when exposed to UV radiation). Cosmic rays, UV lamps Mercury Lamps Electric arc used in welding X-ray photography Radiography Radiotherapy to kill cancer tiss Used in security check poin mines. Detection of cracks in metal we Astronomy Diffraction to find crystal struc Visible Light Luminous and non-luminous objects. Eye Photographic film Light Dependant Resistor Chloroplasts Solar cells InfraRed (IR) All matter especially hot objects. Photographic film Thermometer with blackened bulb. Thermistor Skin Microwaves Microwaves ovens Microwave transmitters Cosmic rays PHYSICS NOTES: Physical Quantities & Measurement Photographic film Microwave receivers Used to check for counterfeit m Used to detect forged art. Used to get a sun –tan. Fluorescent dyes are added detergents. When exposed to the sun or disco lights our teet brightly. Leads to production of vitami by the skin in small quantities. Used to sterilize food Automatic counting in industry Astronomy Used in optical instruments. In photography. Sight Photosynthesis Spectral analysis Information transmission To make LASERS Astronomy Used in IR heaters/cookers/gril Infrared photography. In remote control units for T systems, Air-Cons, Burglar alarms use sensors radiation emitted by an intrude used in motion sensors to autom security lamps. IR imagers are used to locate p at night or in thick smoke o rubble. Drying paint on new cars. Astronomy Mobile telephone communicati Digital Television broadcasts RADAR to locate position of s as well as determine the speed Cooking with microwave oven Killing insects in granaries. Microwave photography Astronomy PREPARED BY RAYMOND 2017© 97 Radio waves Cosmic rays Radio transmitters Radio receivers Radio and TV broadcasts Astronomy Two way radio communication Side Effects of Electromagnetic Waves Gamma Rays Can cause gene mutation Can cause cancer and leukemia Can cause cataracts Can cause sterility Can cause severe radiation burns Can cause miscarriage or damage to the foetus X-Rays Can cause cancer Can cause miscarriage or damage to the foetus Can cause radiation burns Can cause sterility Ultra-Violet Radiation Can cause skin cancer Can kill retinal cells resulting in blindness. Visible light Over exposure can cause fatigue of the cilliary muscles. Infra-Red Radiation Can burn the skin or matter Can cause sunburn. Microwaves Have a heating effect which can cause burns. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 98 SOUND WAVES Sound waves are produced by vibrating sources. They are longitudinal waves in nature and as such need a medium in order to be transmitted from one place to another. Bell-jar experiment The bell-jar experiment can be used to show if this is possible. An electric bell is suspended with rubber bands inside a bell jar. The rubber bands reduce sound transmission by the wires so that sound is only transmitted through the glass. When the circuit is complete the bell rings. A vacuum pump is then used to remove the air from the bell jar. The sound heard decreases as the air is pumped from the bell-jar even though the hammer is still seen striking the gong. Eventually no sound is heard even though the hammer is still striking the gong. This happens when all the air has been removed from the bell jar which shows that sound needs a medium for its propagation. Relative order of the speed of sound in gases, liquids and solids. Sound travels fastest in solids, followed by liquids then gases. This is because the particles of matter are far apart in gases but closely packed in solids. Material Iron steel Water PHYSICS NOTES: Physical Quantities & Measurement Speed (m/s) 5000 4500 1500 PREPARED BY RAYMOND 2017© 99 Air(mixture of gases) Hydrogen Carbon dioxide 330 1350 280 Reflection of Sound Reflected sound is called an echo. Multiple reflection of sound may produce an effect called reverberation. It occurs when too many echoes mix up to produce a dull unclear sound. Diffraction of Sound Waves You can hear around corners even if you cant see the speaker. This is because the waves can bend (diffract) around corners. Audible Frequency Audible frequency refers to the range of frequencies which can be heard by an organism. Each animal species has its own audible frequency. Examples are shown below. Animal Human Beings Dogs Bats Dolphins Elephants Audible Frequency 20 Hz – 20 kHz 20 kHz – 100 kHz 20 Hz – 200 kHz 20 Hz – 200 KHz 5 Hz – 100 kHz Ultrasonic Sound (Ultrasound or sonar) This refers to sound which has a frequency which is above the audible frequency for a particular organism.For human beings any sound above 20 kHz is ultrasound. This means that we can not hear sound which is above 20 kHz even though it can be heard by other animals or detected electronically. Ultrasound waves can be concentrated to form a narrow beam which has many uses. They can be used 1. To study the development of a foetus inside its mother or determining the sex of an unborn baby without operation. 2. To clean jewellery and equipment. The equipment/jewellery is placed in a bath of a 3. special liquid. The ultrasound will shake the dirt off the equipment/jewellery. This is the technique that is used to clean clothes. By dentist to clean tartar coating from your teeth, helping you prevent gum disease. 4. By ships to measure the depth of the sea using expression PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 100 s 2d . t Where s = speed of sound waves d = depth of ocean t = time taken by wave to travel distance 2d. 2d = distance travelled by wave In order to measure the sea depth, ultra sound beams are sent from the ship to the sea bottom or floor. The time taken for the wave to move from the ship to the sea bottom and back to the ship is then measured. This time is then used along with the speed of sound in water to calculate the sea depth. Example: The ultra sound wave above took 4 seconds to travel to sea floor and back to ship. If the speed of sound in sea water is 1500 m/s calculate depth, d. 2d Solution: s t st d 2 1500 x 4 d 2 d = 3000 metres. This method is known as echo sounding and can also be used to calculate the distance between large buildings/structures. 5. Used for navigation by submarines to locate other submarines. 6. To locate shoal of fish as shown below in the diagram. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 101 Noise Pollution Unpleasant sounds are called noise. An area that has a high degree of noise is said to be polluted by noise. These situations can be in a densely populated town or part of the town, airports, studios, road traffic etc. Noise can damage ears, cause tiredness and make someone lose concentration. There are ways in which unwanted noise can be reduced. By building quieter engines or building airports far away from the residential area. In cars exhaust systems can be fitted with silencers. At home sound absorbing materials such as curtains, carpets, windows can be used. The further the noise is, the weaker it is. People who are exposed to high level of noise can wear ear protectors. Classwork 1. A man standing between two hills claps his hand. He receives the first echo after 2.25s. The speed of sound in air is 330 m/s. (a) find the distance between the man and the nearer hill. (b) Calculate the time taken by the second echo to reach the man if the distance between the man and the further hill is 512 m. 2. A man fires a gun and hears the echo from a cliff after 4 seconds. How far away is the cliff? (Speed of sound = 340 m/s) A sonar pulse sent out by a boat arrives back after 3 seconds. If the speed of sound in water 1500 m/s, how deep is the water? 3 Characteristics of Sound The notes from a musical instrument can vary in three ways: PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 102 Pitch Loudness Quality Frequency and Pitch Pitch of a sound note depends on its frequency. The higher the frequency, the higher the pitch and the lower the frequency, the lower the pitch. A high-pitched note has a high frequency but a short wavelength. Loudness and Amplitude Loudness of a sound depends on the amplitude of the wave. The larger the amplitude the louder the sound note. Quality of a sound note. The same note on different instrument sounds different even if the frequency is the same. We say they differ in quality (Timbre). This difference is brought by the fact that no instrument other than a tuning fork or a signal generator can produce a note of one frequency (a pure note). Notes of the same frequency (pitch) but different quality. Acoustics When a band is playing in a hall, the sound the audience hears depends partly on how the hall itself affects the sound waves. That is the acoustics of the hall. A large empty hall, with hard walls, floors, and ceiling usually sounds ‘echoey’. Sound waves are reflected from the surfaces and mixes with the original sound making the sound to be unheard and dull. This may take several seconds before the sound can die away. This effect is called reverberation. In a hall, some materials such as carpets, curtains and even the audience reduce reverberation by absorbing the sound. Some halls have specially designed sound absorbers suspended in ceilings. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 103 LIGHT REFLECTION OF LIGHT Reflection is the bouncing back of light when it falls on an object. When light falls on an object like a book, it bounces in all directions because the surface is a bit rough. This is called Diffuse or Irregular Reflection. When the surface is very smooth, like polished metal surface, light bounces in a regular manner. This is called Regular Reflection. Reflection of light at different surfaces Laws of Reflection The angle of incidence, i and the angle reflection, r are equal. The incident ray, reflected ray and the normal all, lie in the same plane. Plane Reflecting Surfaces Properties of images formed by plane mirrors PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 104 The image and the object are equidistant from the mirror. The image is the same size as the object. The image is virtual, The image is laterally inverted The image is upright/erect Experiment to determine the position of the image formed by a plane mirror. Apparatus: Pin board 8 pins A4 plain paper Plane mirror Procedure: 1. Attach the plain paper to the pin board with 4 pins. 2. Draw a line at the centre of the plane mirror and label it MM’. 3. Place a mirror vertically along the line MM’. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 105 4. Stick a pin O in front of the plane mirror. This is the object pin. 5. With the eye in a suitable position, place two pins in front of the mirror such that they are in line with image I of the object O seen in the mirror [These pins should be place as far apart as possible to improve accuracy]. Mark the positions of the pins P and Q and draw a straight line PQ through their positions. 6. Repeat steps 4 and 5 for pins R and S and line RS. 7. Remove the mirror and pins from the pin board. Extend lines PQ and RS beyond MM’ until they intersect. 8. The image is formed at the intersection of PQ and RS. Uses of Plane Mirrors. 1. Cosmetic purposes 2. Periscopes 3. Rear view mirrors in vehicles. 4. Decorations Curved Reflecting Surfaces Curved mirrors are of two types: concave mirror and convex mirror. A concave mirror makes a parallel beam of light to converge at a point called the principal focus of the mirror. Image formed depends on the position of the object. A convex mirror makes a parallel beam of light to diverge (spread out) and appear to come from the principal focus of the mirror. Image formed by convex mirror is smaller and upright. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 106 Uses of Convex Mirrors Convex mirrors can be used to give a wide field of view, such as a car driving side mirrors or a shop security mirror. Uses of Concave Mirrors Concave mirrors can be used to collect light energy, sound, heat radiation, radar and TV signals. Concave mirrors can produce a magnified image if the object is too close. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 107 REFRACTION OF LIGHT Refraction of light is the bending of light as it travels from one medium to another. [N.B. Even though the light bends it always travels in a straight line.] , When a light ray travels from an optically less dense medium to an optically denser medium, the rays are bent or refracted towards the normal ( i > r ). i is the angle of incidence and r is the angle of refraction. When a light ray travels from an optically denser medium to an optically less dense medium, the rays are bent or refracted away from the normal ( i < r ). i is the angle of incidence and r is the angle of refraction. If the light ray passes through a glass block which has parallel sides, the emerging ray will be parallel to the ray entering the glass block as seen in diagram below. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 108 Refractive Index (n). Light travels at different speeds in different materials. When light moves from one medium to another its speed changes and this causes it to change direction (refract) at the boundary of the mediums. The ratio of the speed of light in a vacuum to the ratio of the speed of light in a given material is called refractive index (n). Refractive Index (n) = Example 1: speed of light in air speed of light in a given material Speed of light in air is 3.0 x 108 m/s and in glass speed of light is 2.0 x 108 m/s Thus refractive index of glass = 3.0 x 10 8 2.0 x 10 8 = 1.5. Snell’s Law Refractive index can be calculated using the angle of incidence i and the angle of refraction r. The refractive index is given by sin i n sin r This relationship is known as Snell’s Law. Example 2: The refractive index of glass is 1.52. If the light ray is incident at an angle of 35º, what will be the angle of refraction? Solution n sin r sin i sin r 0.574 1.52 r = Sin-1(0.3774) PHYSICS NOTES: Physical Quantities & Measurement 1.52 sin 350 sin r sin r = 0.3774 r = 22.2º PREPARED BY RAYMOND 2017© 109 Real and Apparent Depth A river or a pond appears to be less deeper than it really is. The bottom of a swimming pool appears to be close the surface. The same thing applies to the fish swimming near the bottom of a pond, they appear to be close to the surface. All this are a result of refraction The light from the water bottom to the person’s eye is refracted away from the normal at the surface since it is travelling form an optically denser medium to a less dense medium. To an observer the rays of light appear as if they are coming from the image of the pebble. Refractive index can be calculated using the equation Real Depth Refractive index, n Apparent Depth Refractive index is a constant for any given material. water - 1.33, Diamond - 2.42, Glass, 1.5 Classwork 1. 2. 3. Given that the real depth of a pool of water is 4m and that the refractive index of the water is 1.33, calculate the apparent depth of the pool. When light moves from air into glass the angle of refraction r is 43º. Calculate the angle of incidence i. Calculate the refractive index of air. The speed of light in air is 3.0 x 108 m/s. Critical Angle (c) & Total Internal Reflection PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 110 The incidence angle for which the angle of refraction is 90º is called the critical angle(c). It only occurs when light travels from a denser medium to a less dense medium. The critical angle is a constant for any given material, e.g. water-49 º, Diamond-24 º, Glass-42 º. If the incidence angle exceeds the critical angle for any material then Total Internal Reflection takes place. If i < c then normal refraction takes place. If i < c then r = 90 º. If i > c then total internal reflection takes place. See diagram below PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 111 Critical angle and refractive Index Critical angle and refractive Index are related through the expression, 1 n sin c Example 3: Refractive index of glass is 1.5. Calculate its critical angle. Solution 1 1 1.5 = n sin c sin c Rearranging: sin c = 1 = 0.667 1 .5 c = Sin-1(0.667) c = 42º Consequences & application of total internal reflection Optical Fibres/Light Pipes Optical fibres are very thin, flexible rods made from a special glass. Light can be trapped by total internal reflection inside the optic fibre. The light rays meet the sides of the rod at an angle greater than the critical angle of the glass. The light rays are then totally internally reflected inside the glass rod. Surgeons use a device called an endoscope to examine the inside of patients’ bodies. This is made of bundles of fibre optics. Optical fibres can also carry telephone calls. In industry they are used to examine hidden parts. Security personnel use fibre optics to view inside rooms were hostages are held. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 112 Reflecting Prisms Glass prisms are used to change the direction of light rays through total internal reflection. In periscopes, 45o prisms are used instead of plane mirrors. In car or bicycle rear reflectors, the direction of the incoming light can be reversed by two total internal reflections. Mirages Mirages are common in hot deserts or even in a hot day in a tarred road. A traveler often sees a pool of water ahead of him/her which is an optical illusion. Mirages are caused by the progressive and continuous refraction of light as it passes into warmer layers of air of changing refractive index. The rays of light eventually become parallel to the ground, and then proceed to bend upwards as a result of total internal reflection. To the observer the rays of light appear to come from the road. This creates an image of the sky on the road which looks like a pool of water. LENSES Lenses refract light and form images. There are two main types of lenses: The Convex (converging) lens and Concave (diverging) lens. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 113 Action of a thin converging lens on parallel light beams Definition of Terms Principal Axis: A path followed by a light ray as it passes through the centre of the lens and is perpendicular to the lens. Principal focus (F): A point on the principal axis at which all the rays seem to converge after passing through the lens. Optical Centre(c): The geometric centre of a lens. Focal length (f): Length between the optical centre and the principal focus. This is a constant for any given lens. Characteristics Of Images Formed By Convex Lenses This can be shown with the help of ray diagrams. Ray diagrams are used to locate the image formed by drawing two of the following standard rays. 1. A ray passing through the centre of the lens is not refracted (it passes as a straight line). 2. A ray parallel to the principal axis passes through F after leaving the lens. NB: All rays begin from the top of the object and the bending takes place at the line passing through the middle of the lens. Object beyond 2F PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 114 The image is Inverted Real Smaller than the object Formed between F and 2F. The lens is used in this manner in a camera. Object Between F and 2F The image is Real Bigger than the object (magnified) Inverted formed beyond 2F. When used in a slide projector or a photographic enlarger. Object at 2F The image is Inverted Real Same size as the object Formed between F and 2F. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 115 The lens is used in this way in various optical instruments to provide an upright image. Object Between F and C The image is Virtual Upright Bigger than the object (Magnified) formed behind the object A lens can be used in this manner in a magnifying glass. Object at 2F The image will be formed at infinity, similarly, when the object is at infinity, the image will be formed at F. Uses of Lenses in Optical Instruments The camera uses a convex lens to form an image that is real, small, inverted on a piece of film at the back. The image is formed between F and 2F of the lens. The image is formed on the film. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 116 A slide projector forms a real image on a screen of a slide or a film in a cine-projector. The image is usually smaller than the real object (slide or frame of film), and is further away from the lens. Good illumination of the slide is needed in order for the image to be bright. This is achieved by focusing the light beam by a concave mirror and two condenser lenses as shown in the diagram below. A Photographic Enlarger uses a magnified image of the negative to produce a well magnified print of a photograph. It works the same way as a slide projector. Simple microscope (magnifying glass) A convex lens forms an enlarged, upright virtual image of an object placed between F and the lens. It acts as a magnifying glass as shown below. PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 117 Finding Focal length of a Lens Method 1 Place a lens in front of a screen. Adjust the position of the lens until a sharp image of a distant object is seen on the screen. The distance between the image lens and the screen gives the focal length. Method 2 A more accurate method of finding focal length is by using the expression 1 1 1 f v u which is known as the lens equation. Where v is image distance and u is object distance. Place a candle along a metre rule and place a screen at the other end. Place a lens in between them and adjust its position until the image of the candle is seen on the screen. Measure and record u and v, then calculate f using the expression above. Magnification PHYSICS NOTES: Physical Quantities & Measurement PREPARED BY RAYMOND 2017© 118 magnification magnification image distance (v) object distance (u) magnification PHYSICS NOTES: Physical Quantities & Measurement image size object size or or image height(v) object height (u) PREPARED BY RAYMOND 2017©
