Physics I Class 11 Conservative Forces, Non-Conservative Forces, and Collisions Rev. 19-Feb-06 GB 11-1 Conservation of Energy (Review) 1. Multi-dimensional form of work integral: xf W F dx xi 2. 3. Conservative force = work doesn’t depend on path. Potential Energy defined for a conservative force: U ( A ) F dx A 0 Ug m g ( y y0 ) m g h U s 12 k ( x x 0 ) 2 4. Gravity: 5. 6. Spring: Conservation of energy if only conservative forces operate: K U or | K U 0 | 11-2 Conservative Forces Non-Conservative Forces Examples of Conservative Forces: Gravity Ideal Spring (Hooke’s Law) Electrostatic Force (later in Physics 1) Examples of Non-Conservative Forces: Human Pushes and Pulls Friction 11-3 Is Mechanical Energy Always Conserved? Total Mechanical Energy EKU E K U 0 if only conservative forces act When Non-Conservative Forces Act E K U Wnon cons This is equivalent to K f U f K i U i Wnon cons Non-conservative forces add (+) or subtract (–) energy. 11-4 Example of Energy Lost to Friction (Non-Conservative Force) Kf 0 U f m g h 70 9.8 1.5 1029J K i 12 m v 2 12 70 64 2240J Ui 0 v d h h d sin( ) 3 12 1.5m A skateboarder with mass = 70 kg starts up a 30º incline going 8 m/s. He goes 3 m along the incline and comes to a temporary stop. What was the force of friction, assuming it was constant? 11-5 Example of Energy Lost to Friction (Non-Conservative Force) Kf 0 U f m g h 70 9.8 1.5 1029J K i 12 m v 2 12 70 64 2240J Ui 0 v d h Wfriction K f U f K i U i 1029 2240 1211J Wfriction 1211 Ffriction 403.7 N d 3 What do the – signs mean? 11-6 Elastic and Inelastic Collisions Momentum is conserved in a collision process because only internal forces are acting. External forces are considered separately. In many collisions a large percentage of the kinetic energy is lost. These are known as inelastic collisions. For example, any collision in which two objects stick together is always inelastic. If the kinetic energy after a collision is the same as before, then we have an elastic collision. During the collision process, some of the kinetic energy can convert to potential energy of various kinds, but after the collision is over all of the kinetic energy is restored. 11-7 Elastic Collisions in One Dimension +X Initial v1i Final v1f v2i v2f Conservation of Momentum: m1v1i m 2 v 2i m1v1f m 2 v 2 f Conservation of Energy: 1 2 m1v 21i 12 m 2 v 2 2i 12 m1v 21f 12 m 2 v 2 2 f Two equations, two unknowns (final velocities). 11-8 Elastic Collisions in One Dimension +X Initial Final v1i v2i v1f v2f m1 m 2 2 m2 v1f v1i v 2i m1 m 2 m1 m 2 2 m1 m 2 m1 v 2f v1i v 2i m1 m 2 m1 m 2 11-9 Elastic Collisions in One Dimension - Example m 2 2 m1 v1i 1 m/s v 2i 0 +X v1i v1f 1 2 2 2 1 v1f (1) (0) m/s 2 1 2 1 3 2 1 2 1 2 v2f (1) (0) m/s 2 1 2 1 3 v2f Initial: m1 has all of the momentum and KE. Final: m1 has –1/3 of the mom. and 1/9 of the KE. m2 has +4/3 of the mom. and 8/9 of the KE. 11-10 Class #11 Take-Away Concepts 1. Modification of energy conservation including nonconservative forces: E = K + U = Wnon-cons 2. 3. 4. Non-conservative work adds (+) or subtracts (–) energy from the system. Elastic collision preserves KE before and after. (Don’t assume all collisions are elastic, most are not.) Special equations for 1D elastic collisions. m1 m 2 2 m2 v1i v 2i m1 m 2 m1 m 2 2 m1 m m1 v 2f v1i 2 v 2i m1 m 2 m1 m 2 v1f 11-11 Class #11 Problems of the Day ___ 1. An elastic collision is one in which: A. momentum is not conserved but kinetic energy is the same before and after. B. a rubbery object bounces off something else. C. kinetic energy is the same before and after, and momentum is conserved. D. momentum is conserved but kinetic energy changes. E. the total impulse is equal to the change in kinetic energy. 11-12 Class #11 Problems of the Day 2. A bicycle rider with combined mass of rider+bicycle = 80 kg starts down a hill at 10 m/s. After coasting (not pedaling) 100 m, the rider has dropped 10m below his starting height and now has a speed of 15 m/s. What was the force of friction plus air resistance on the bicycle (magnitude) assuming it was constant? 11-13 Activity #11 Friction and Energy Objective of the Activity: 1. 2. Add friction and see how that affects conservation of energy. Practice everything we have learned in Physics I up to this point. 11-14 Class #11 Optional Material Elastic Collisions in 2/3D In order to solve 2D and 3D two-body elastic collision problems more easily, we need to introduce two key concepts. 1. 2. The laws of physics are identical in all inertial frames of reference. (See the optional material on Special Relativity.) Use a moving coordinate system called the Center of Momentum System in which the total momentum is zero. 11-15 Center of Momentum Reference Frame We introduce a moving reference frame in which the total momentum of the system is zero. The X' axis is aligned with the initial momenta. p1 Y' Laboratory frame of reference. p2 p1' X' p2' 11-16 Analyzing the Collision in the Center of Momentum p1' Before the collision: p1 ' p 2 ' p2' p1'' Original direction of momentum. depends on the details of the collision. p2'' After collision, to conserve momentum (zero): p1" p 2 " And to conserve kinetic energy: | p1"| | p1 ' | 11-17 Transform Back to the Laboratory Frame of Reference p1f This is just an example, not all elastic collisions turn out this way. p2f = 0 Apply the inverse coordinate transform to get back to the laboratory reference frame. In Special Relativity, this is complicated because time mixes into the transformation. The one-dimensional equations shown on previous slides can be derived using this method by setting = 180º. 11-18