Physics I Class 16 Conservation of Angular Momentum Rev. 18-Mar-03 GB 16-1 Important Announcements Exam 2 will be 7 PM on March 25 in the same rooms as Exam 1. Conflict exams at 6, 7, 8, 9, and 10 PM on March 25 in SC 2C06. If you get extra time, you need to come to a conflict exam. Review session on March 24 at 7 PM in DCC 330. Review activity for March 24/25 classes: Similar format, extended time, on WebAssign in near future. All sections will have the same time frame to do this assignment. The due date/time for everyone will be March 25 at 7 PM. Try to do as many of the problems as possible before class. Work with your team in class on problems you couldn’t do. Attendance is mandatory if you want activity credit. 16-2 Angular Momentum of a Particle Review center of rotation (defined) r p mv Angular momentum of a particle once a center is defined: l r p (What is the direction of angular momentum here?) Once we define a center (or axis) of rotation, any object with a linear momentum that does not move directly through that point has an angular momentum defined relative to the chosen center. 16-3 Angular Momentum of a Particle Angular Momentum of an Object For a solid object, each atom has its own angular momentum: l i ri p i ri ( m i v i ) The direction is the same as the direction of angular velocity. The magnitude is 2 | l i | | ri | | p i | sin( ) m i | ri | | v i | m i ri ri m i ri so 2 l i m i ri The total angular momentum, summing all atoms, is 2 L l i m i ri I 16-4 How Does Angular Momentum of a Particle Change with Time? Take the time derivative of angular momentum: dl d d r dp ( r p) p r dt dt dt dt Find each term separately: so dr p v p 0 (Why?) dt dp r r Fnet net (Why?) dt dl net (Newton’s 2nd Law for angular momentum.) dt 16-5 Angular Momentum of a Particle: Does It Change if = 0? Y (0,0) r r (blue) (0,–3) X (red) (4,–3) p m v = 1 kg m/s (+X dir.) The figure at the left shows the same particle at two different times. No forces (or torques) act on the particle. Is its angular momentum constant? (Check magnitudes at the two times.) Blue angle: = 90º l = r p sin() = (3) (1) sin(90º) = 3 kg m2/s Red angle: = arctan(3/4) = 36.87º l = r p sin() = (5) (1) sin(36.87º) = 3 kg m2/s [r sin()] is the component of r at a right angle to p . It is constant. It is also the distance at closest approach to the center. 16-6 Conservation of Angular Momentum Take (for example) two rotating objects that interact. dl1 on 1 from 2 ext on 1 dt dl2 on 2 from 1 ext on 2 dt The total angular momentum is the sum of 1 and 2: dL d l 1 d l 2 ext on 1 ext on 2 (Why?) dt dt dt If there are no external torques, then dL 0 dt 16-7 Example 1 An ice skater spins at 6 rad/sec with out-stretched hands. Her rotational inertia is 50 kg m2. She then pulls her arms in, thereby changing her rotational inertial to 40 kg m2. What is her angular speed now? No external torque, so L remains constant I before before L I after after after I before before 50 6 7.5 rad/sec I after 40 16-8 Example 2 A wheel is rotating freely with an angular speed of 30 rad/sec on a shaft whose rotational inertia is negligible. A second wheel, initially at rest and with twice the rotational inertia of the first is suddenly coupled to the same shaft. What is the angular speed of the resultant combination of the shaft and two wheels? No external torque, so L remains constant I1 before L I1 after I 2 after after I1 before I1 before 1 30 10 rad/sec I1 I 2 I1 2 I1 3 16-9 Class #16 Take-Away Concepts 1. Angular momentum of a particle (review): l r p . 2. Newton’s 2nd Law for angular momentum: 3. Conservation of angular momentum (no ext. torque): dl net dt dL 0 dt 16-10 Class #16 Problems of the Day ___1. When a woman on a frictionless rotating turntable extends her arms out horizontally, her angular momentum: A. must increase B. must decrease C. must remain the same D. may increase or decrease depending on her initial angular velocity E. changes into kinetic energy 16-11 Class #16 Problems of the Day 2. Two ice skaters of equal mass perform the following trick: Skater A is at rest on the ice while skater B approaches. As skater B passes by at 10 m/s, his center of mass is 1.8 m from skater A’s center of mass at the instant of closest approach. At that instant, the skaters reach out and clasp each other’s hands. Find the rotational speed of the skaters, find the speed of their center of mass, and describe the subsequent path of the center of mass in terms of geometric shape. Treat the skaters as point masses and ignore the friction of the skates on the ice. 16-12 Activity #16 - Conservation of Angular Momentum Objective of the Activity: 1. 2. 3. Think about conservation of angular momentum. Use conservation of momentum to predict the change in rotational speed in a simple system. Compare measurements with predictions. 16-13