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Physics 215 – Fall 2014Lecture 11-21 Welcome back to Physics 215 Today’s agenda: Angular Momentum Rolling.

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Presentation on theme: "Physics 215 – Fall 2014Lecture 11-21 Welcome back to Physics 215 Today’s agenda: Angular Momentum Rolling."— Presentation transcript:

1 Physics 215 – Fall 2014Lecture 11-21 Welcome back to Physics 215 Today’s agenda: Angular Momentum Rolling

2 Physics 215 – Fall 2014Lecture 11-22 Current homework assignment HW9: –Knight Textbook Ch.12: 74, 80, 82, 86 –2 exam-style web problems

3 Physics 215 – Fall 2014Lecture 11-23 Angular Momentum can define rotational analog of linear momentum called angular momentum in absence of external torque it will be conserved in time True even in situations where Newton’s laws fail ….

4 Physics 215 – Fall 2014Lecture 11-24 Definition of Angular Momentum * Back to slide on rotational dynamics: m i r i 2  /  t =  i * Rewrite, using l i = m i r i 2   l i /  t =  i * Summing over all particles in body :  L/  t =  ext L = angular momentum = I  pivot  riri mimi FiFi

5 Physics 215 – Fall 2014Lecture 11-25 An ice skater spins about a vertical axis through her body with her arms held out. As she draws her arms in, her angular velocity 1. increases 2. decreases 3. remains the same 4. need more information

6 Physics 215 – Fall 2014Lecture 11-26 Angular Momentum 1.  p r O Point particle: |L| = |r||p|sin(  ) = m|r||v| sin(  ) vector form  L = r x p – direction of L given by right hand rule (into paper here) L = mvr if v is at 90 0 to r for single particle

7 Physics 215 – Fall 2014Lecture 11-27 Angular Momentum 2. o  rigid body: * |L| = I  fixed axis of rotation) * direction – along axis – into paper here

8 Physics 215 – Fall 2014Lecture 11-28 Rotational Dynamics     L/  t =   These are equivalent statements  If no net external torque:    * L is constant in time  * Conservation of Angular Momentum  * Internal forces/torques do not contribute  to external torque.

9 Physics 215 – Fall 2014Lecture 11-29 Bicycle wheel demo Spin wheel, then step onto platform Apply force to tilt axle of wheel

10 Physics 215 – Fall 2014Lecture 11-210 Linear and rotational motion Force Acceleration Momentum Kinetic energy Torque Angular acceleration Angular momentum Kinetic energy *rotations about fixed pivot or symmetry axis

11 Physics 215 – Fall 2014Lecture 11-211 A hammer is held horizontally and then released. Which way will it fall?

12 Physics 215 – Fall 2014Lecture 11-212 General motion of extended objects Net force  acceleration of CM Net torque about CM  angular acceleration (rotation) about CM Resultant motion is superposition of these two motions Total kinetic energy K = K CM + K rot

13 Physics 215 – Fall 2014Lecture 11-213 1.A. 2.B. 3.C. 4.A and C. Three identical rectangular blocks are at rest on a flat, frictionless table. The same force is exerted on each of the three blocks for a very short time interval. The force is exerted at a different point on each block, as shown. After the force has stopped acting on each block, which block will spin the fastest? Top-view diagram

14 Physics 215 – Fall 2014Lecture 11-214 1.A. 2.B. 3.C. 4.A, B, and C have the same C.O.M. speed. Three identical rectangular blocks are at rest on a flat, frictionless table. The same force is exerted on each of the three blocks for a very short time interval. The force is exerted at a different point on each block, as shown. After each force has stopped acting, which block’s center of mass will have the greatest speed? Top-view diagram

15 Physics 215 – Fall 2014Lecture 11-215 Rolling without slipping translationrotation v cm = a cm =

16 Physics 215 – Fall 2014Lecture 11-216 Rolling without slipping N W F   F = ma CM   = I  Now a CM = R  if no slipping So, m a CM and F =

17 Physics 215 – Fall 2014Lecture 11-217 A ribbon is wound up on a spool. A person pulls the ribbon as shown. Will the spool move to the left, to the right, or will it not move at all? 1.The spool will move to the left. 2.The spool will move to the right. 3.The spool will not move at all.

18 Physics 215 – Fall 2014Lecture 11-218 1.The spool will move to the left. 2.The spool will move to the right. 3.The spool will not move at all. A ribbon is wound up on a spool. A person pulls the ribbon as shown. Will the spool move to the left, to the right, or will it not move at all?

19 Physics 215 – Fall 2014Lecture 11-219 A ribbon is wound up on a spool. A person pulls the ribbon as shown. Will the spool move to the left, to the right, or will it not move at all? 1.The spool will move to the left. 2.The spool will move to the right. 3.The spool will not move at all.

20 Physics 215 – Fall 2014Lecture 11-220

21 Physics 215 – Fall 2014Lecture 11-221

22 Physics 215 – Fall 2014Lecture 11-222 Reading assignment Gravitation -- Ch. 13 in textbook

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