EDEXCEL IGCSE PHYSICS 1-2 Forces & Shape Edexcel IGCSE Physics pages 12 to 22 Content applying to Triple Science only is shown in red type on the next slide and is indicated on subsequent slides by ‘TRIPLE ONLY’ July 13th 2011 Edexcel IGCSE Specification Section 1: Forces and motion c) Forces, movement, shape and momentum express a force as a push or pull of one body on another identify various types of force (for example gravitational, electrostatic etc) distinguish between vector and scalar quantities appreciate the vector nature of a force add forces that act along a line understand that friction is a force that opposes motion describe how extension varies with applied force for helical springs, metal wires and rubber bands recall that the initial linear region of a force-extension graph is associated with Hooke’s law associate elastic behaviour with the ability of a material to recover its original shape after the forces causing deformation have been removed. Red type: Triple Science Only Force newtonmeters A force is a push or a pull. A force can cause an object to: – speed up – slow down – change direction – change shape Force is measured in newtons (N). Force is measured with a newtonmeter. Some types of force 1. Gravitational This is the attractive force exerted between bodies because of their masses. This force increases if either or both of the masses is increased and decreases if they are moved further apart. Weight is the gravitational force of the Earth on an object. Bathroom scales measure weight. A mass of 1kg weighs about 10N 1 stone is about 63N. 2. Normal reaction or contact This is the repulsive force that stops two touching bodies moving into each other. normal reaction forces The word ’normal’ means that this force acts at 90° to the surfaces of the bodies. weight It is caused by repulsive molecular forces. The two upward reaction forces on the tyres balance the downward weight of the car 3. Friction This is the force that opposes motion. The kinetic energy of the moving object is converted to heat energy by the force of friction. Friction is needed for racing cars to grip the road Friction is needed for walking! 4. Air resistance or drag This is the force that opposes the movement of objects through air. Drag is a more general term used for the opposition force in any gas or liquid. Objects are often streamlined to reduce this force. streamlined car a parachute maximises drag force 5. Upthrust This is the force experienced by objects when they are placed into a fluid (liquid or gas). An object will float on a liquid if the upthrust force equals its weight. A hot air balloon rises when the upthrust from the surrounding air is greater than the balloon’s weight. 6. Magnetic Between magnets but also the force that allows electric motors to work. 7. Electrostatic Attractive and repulsive forces due to bodies being charged. Electrostatic force causes the girls’ hair to rise when they touch the Van der Graaff generator. Choose appropriate words to fill in the gaps below: force is a push or a pull. A force can cause an object to A _____ accelerate ___________ or change shape. newtons (N) with a newtonmeter. Force is measured in _______ contact force occurs when There are many types of force. ________ two bodies touch each other. motion of one body opposes the _______ Friction is a force that _______ attractive forces relative to another. It is caused by the _________ molecules between ___________. WORD SELECTION: newtons opposes accelerate force molecules contact attractive motion TRIPLE ONLY Vectors and Scalars All physical quantities (e.g. speed and force) are described by a magnitude and a unit. VECTORS – also need to have their direction specified examples: displacement, velocity, acceleration, force. SCALARS – do not have a direction examples: distance, speed, mass, work, energy. TRIPLE ONLY Representing Vectors An arrowed straight line is used. The arrow indicates the direction and the length of the line is proportional to the magnitude. Displacement 50m EAST Displacement 25m at 45o North of East TRIPLE ONLY Addition of vectors 1 4N object 4N 6N 6N object resultant = 10N object The original vectors are called COMPONENT vectors. The final overall vector is called the RESULTANT vector. 4N 6N 6N object 4N object resultant = 2N object TRIPLE ONLY Resultant force A number of forces acting on a body may be replaced by a single force which has the same effect on the body as the original forces all acting together. 3N 2N This overall force is called resultant force. In the example opposite, 5N is the resultant force of the 3N and 2N forces. 5N TRIPLE ONLY Determine the resultant force in the cases below: 4N 6N 10N 1. 3. 3N 4. 2. 6N 4N 4N 7N 2N 3N 4N 1N 5. 4N There is no resultant 4N case force in this TRIPLE ONLY Resultant force and motion Resultant force Effect on the motion of an object Zero Object’s velocity stays the same including staying stationary Object accelerates In the direction the object is moving In the opposite direction in which the object is moving Object decelerates TRIPLE ONLY Examples 1 & 2 The box will move when the man’s push force is greater than the friction force. The plane will accelerate provided that the engine force is greater than the drag force. TRIPLE ONLY Examples 3 & 4 The brakes exert a resultant force in the opposite direction to the car’s motion causing the car to decelerate. Once released, the glider moves at a near constant velocity as it experiences a nearly zero horizontal resultant force. TRIPLE ONLY Choose appropriate words to fill in the gaps below: resultant force, can be used to replace A single force, called _________ number of forces that act on a body. a _______ zero then the body will either If the resultant force is _____ rest or continue to move at a constant ________. velocity remain at _____ direction as an object’s If the resultant force is in the same _________ motion, the object will __________. A car is decelerated when accelerate opposite the braking force acts in the _________ direction to the car’s motion. WORD SELECTION: number rest direction zero opposite velocity accelerate resultant Changing shape Force can also change the shape of an object. A stretching force puts an object such as a wire or spring under tension. A squashing force puts an object under compression. Brittle materials such as glass do not change shape easily and break before noticeably stretching. Resilient materials do not break easily. Elastic materials return to their original shape when the forces on them are removed. Plastic materials retain their new shape. Stretching Springs Experimental procedure: 1. Place the weight holder only on the spring and note the position of the pin against the metre rule. 2. Add 1N (100g) to the holder and note the new position of the pin. 3. Calculate the extension of the spring. 4. Repeat stages 1 to 3 for 2N, 3N, 4N, 5N and 6N. DO NOT EXCEED 6N. spring weights pin metre rule Typical results Pin position with holder only (mm) Added weight or Force (N) Pin position with weight (mm) Extension (mm) 450 1 480 30 450 2 509 59 450 3 541 91 450 4 570 120 450 5 601 151 450 6 629 179 Force (N) Force against extension graph 0 0 Extension (mm) Hooke’s law Hooke’s law states that the extension of a spring force is proportional to the force used to stretch the spring. ‘Proportional’ means that if the force is doubled then the extension also doubles. The line on a graph of force against extension will be a straight AND go through the origin. Question A spring of original length 150mm is extended by 30mm by a force of 4N. Calculate the length of the spring if a force of 12N is applied. 12N is three times 4N Therefore the new extension should be 3 x 30mm = 90mm New spring length = 150mm + 90mm = 240mm Elastic limit Up to a certain extension if the force is removed the spring will return to its original length. The spring is behaving elastically. If this critical extension is exceeded, known as the elastic limit, the spring will be permanently stretched. Hooke’s law is no longer obeyed by the spring if its elastic limit is exceeded. The right hand spring has been stretched beyond its elastic limit Force (N) Force against extension graph if the elastic limit is exceeded elastic limit 0 0 Extension (mm) Force Stretching an elastic band An elastic band does not obey Hooke’s law. 0 0 Extension Choose appropriate words to fill in the gaps below: stretched the Hooke’s law states that when a wire or spring is _________ extension is proportional to the load increase in length or _________ force applied. ______ elastic This law is not obeyed if the spring is taken beyond its ______ permanently limit after which it will become _____________ stretched. A ________ rubber band does not obey Hooke’s law. A graph illustrating Hooke’s law will have a line that is straight origin ___________ and passes through the _______. WORD SELECTION: stretched elastic permanently extension origin force rubber straight Online Simulations Effect of forces on motion using a space module Freezeray.com Force combination balloon game - eChalk Electric & Magnetic Forces - 'Whys Guy' Video Clip (3:30mins) - Shows Charged Balloon & Effect of a magnet on a TV screen. Resultant of two forces - Fendt Forces on objects immersed in liquids - NTNU BBC KS3 Bitesize Revision: What is a force Balanced forces Unbalanced forces BBC AQA GCSE Bitesize Revision: Resultant force Types of forces Vector Addition - PhET - Learn how to add vectors. Drag vectors onto a graph, change their length and angle, and sum them together. The magnitude, angle, and components of each vector can be displayed in several formats. Representing vectors - eChalk Vectors & Scalars - eChalk Vector addition - eChalk Vector Chains - eChalk Fifty-Fifty Game on Vectors & Scalars - by KT Microsoft WORD Vector addition - Explore Science Stretching Springs - PhET - A realistic mass and spring laboratory. Hang masses from springs and adjust the spring stiffness and damping. You can even slow time. Transport the lab to different planets. A chart shows the kinetic, potential, and thermal energy for each spring. TRIPLE ONLY Forces & Shape Notes questions from pages 4 and 12 to 22 1. 2. 3. 4. 5. 6. 7. (a) What is force? (b) Explain the meaning of the following types of force: gravitational, normal reaction, drag, electrostatic and friction. (see pages 12 to 17) Explain the difference between vectors and scalars quantities and give two examples of each. (see pages 4 and 13) State what is meant by Hooke’s law and explain how a graph can be drawn to verify that a spring obeys this law. What is meant by ‘elastic limit’? Sketch a graph showing how the loading force varies with extension when extending an elastic band. Answer the questions on pages 21 & 22. Verify that you can do all of the items listed in the end of chapter checklist on page 21 DOUBLE ONLY Forces & Shape Notes questions from pages 12 to 22 1. 2. 3. 4. 5. (a) What is force? (b) Explain the meaning of the following types of force: gravitational, normal reaction, drag, electrostatic and friction. (see pages 12 to 17) State what is meant by Hooke’s law and explain how a graph can be drawn to verify that a spring obeys this law. What is meant by ‘elastic limit’? Sketch a graph showing how the loading force varies with extension when extending an elastic band. Answer questions 1, 2, 6 and 9 on pages 21 & 22.