1. Chapters 7 & 8 Rotational Motion and The Law of Gravity

2. Homework Problems: CH 7: 1,4,5,7,10,12,14,18,19,21,24,25,29,31,34, 36,40 CH 7: 1,4,5,7,10,12,14,18,19,21,24,25,29,31,34, 36,40 CH8: CH8: 17,21, 23 17,21, 23

3. Angular Displacement Axis of rotation is the center of the disk Axis of rotation is the center of the disk Need a fixed reference line Need a fixed reference line During time t, the reference line moves through angle θ During time t, the reference line moves through angle θ

4. Angular Displacement, cont. Every point on the object undergoes circular motion about the point O Every point on the object undergoes circular motion about the point O Angles generally need to be measured in radians Angles generally need to be measured in radians s is the length of arc and r is the radius s is the length of arc and r is the radius

5. More About Radians Comparing degrees and radians Comparing degrees and radians Converting from degrees to radians Converting from degrees to radians

6. Angular Displacement, cont. The angular displacement is defined as the angle the object rotates through during some time interval The angular displacement is defined as the angle the object rotates through during some time interval Every point on the disc undergoes the same angular displacement in any given time interval Every point on the disc undergoes the same angular displacement in any given time interval

7. Angular Speed The average angular speed, ω, of a rotating rigid object is the ratio of the angular displacement to the time interval The average angular speed, ω, of a rotating rigid object is the ratio of the angular displacement to the time interval

8. Angular Speed, cont. The instantaneous angular speed is defined as the limit of the average speed as the time interval approaches zero The instantaneous angular speed is defined as the limit of the average speed as the time interval approaches zero Units of angular speed are radians/sec Units of angular speed are radians/sec rad/s rad/s Speed will be positive if θ is increasing (counterclockwise) Speed will be positive if θ is increasing (counterclockwise) Speed will be negative if θ is decreasing (clockwise) Speed will be negative if θ is decreasing (clockwise)

9. Angular Acceleration The average angular acceleration,, The average angular acceleration,, of an object is defined as the ratio of the change in the angular speed to the time it takes for the object to undergo the change: of an object is defined as the ratio of the change in the angular speed to the time it takes for the object to undergo the change:

10. Tangential Acceleration

11. More About Angular Acceleration Units of angular acceleration are rad/s² Units of angular acceleration are rad/s² When a rigid object rotates about a fixed axis, every portion of the object has the same angular speed and the same angular acceleration When a rigid object rotates about a fixed axis, every portion of the object has the same angular speed and the same angular acceleration

12. Problem Solving Hints Similar to the techniques used in linear motion problems Similar to the techniques used in linear motion problems With constant angular acceleration, the techniques are much like those with constant linear acceleration With constant angular acceleration, the techniques are much like those with constant linear acceleration There are some differences to keep in mind There are some differences to keep in mind For rotational motion, define a rotational axis For rotational motion, define a rotational axis The object keeps returning to its original orientation, so you can find the number of revolutions made by the body The object keeps returning to its original orientation, so you can find the number of revolutions made by the body

13. Analogies Between Linear and Rotational Motion Rotational Motion About a Fixed Axis with Constant Acceleration Linear Motion with Constant Acceleration

14. Relationship Between Angular and Linear Quantities Displacements Displacements Speeds Speeds Accelerations Accelerations Every point on the rotating object has the same angular motion Every point on the rotating object does not have the same linear motion

15. Centripetal Acceleration An object traveling in a circle, even though it moves with a constant speed, will have an acceleration An object traveling in a circle, even though it moves with a constant speed, will have an acceleration The centripetal acceleration is due to the change in the direction of the velocity The centripetal acceleration is due to the change in the direction of the velocity

16. Centripetal Acceleration, cont. Centripetal refers to “center-seeking” Centripetal refers to “center-seeking” The direction of the velocity changes The direction of the velocity changes The acceleration is directed toward the center of the circle of motion The acceleration is directed toward the center of the circle of motion

17. Centripetal Acceleration and Angular Velocity The angular velocity and the linear velocity are related (v = ωr) The angular velocity and the linear velocity are related (v = ωr) The centripetal acceleration can also be related to the angular velocity The centripetal acceleration can also be related to the angular velocity See page 198 for derivation OR

18. Total Acceleration The tangential component of the acceleration is due to changing speed The tangential component of the acceleration is due to changing speed The centripetal component of the acceleration is due to changing direction The centripetal component of the acceleration is due to changing direction Total acceleration can be found from these components Total acceleration can be found from these components Pythagorean theorem

19. Vector Nature of Angular Quantities Assign a positive or negative direction in the problem Assign a positive or negative direction in the problem A more complete way is by using the right hand rule A more complete way is by using the right hand rule Grasp the axis of rotation with your right hand Grasp the axis of rotation with your right hand Wrap your fingers in the direction of rotation Wrap your fingers in the direction of rotation Your thumb points in the direction of ω Your thumb points in the direction of ω

20. Forces Causing Centripetal Acceleration Newton’s Second Law says that the centripetal acceleration is accompanied by a force Newton’s Second Law says that the centripetal acceleration is accompanied by a force F stands for any force that keeps an object following a circular path Tension in a string Tension in a string Gravity Gravity Force of friction Force of friction

21. Problem Solving Strategy Draw a free body diagram, showing and labeling all the forces acting on the object(s) Draw a free body diagram, showing and labeling all the forces acting on the object(s) Choose a coordinate system that has one axis perpendicular to the circular path and the other axis tangent to the circular path Choose a coordinate system that has one axis perpendicular to the circular path and the other axis tangent to the circular path

22. Problem Solving Strategy, cont. Find the net force toward the center of the circular path (this is the force that causes the centripetal acceleration) Find the net force toward the center of the circular path (this is the force that causes the centripetal acceleration) Solve as in Newton’s second law problems Solve as in Newton’s second law problems The directions will be radial and tangential The directions will be radial and tangential The acceleration will be the centripetal acceleration The acceleration will be the centripetal acceleration

23. Applications of Forces Causing Centripetal Acceleration Many specific situations will use forces that cause centripetal acceleration Many specific situations will use forces that cause centripetal acceleration Level curves Level curves Banked curves Banked curves Horizontal circles Horizontal circles Vertical circles Vertical circles

24. Level Curves Friction is the force that produces the centripetal acceleration Friction is the force that produces the centripetal acceleration Can find the frictional force, µ, v Can find the frictional force, µ, v But what about the mass???

25. At what maximum speed can a car negotiate a turn on a wet road with coefficient of static friction 0.230 without sliding out of control? At what maximum speed can a car negotiate a turn on a wet road with coefficient of static friction 0.230 without sliding out of control?

26. Banked Curves A component of the normal force adds to the frictional force to allow higher speeds A component of the normal force adds to the frictional force to allow higher speeds remember from See p. 204

28. A race track is to have a banked curve with a radius of 25m. What should be the angle of the bank if the normal force alone is to allow safe travel around the curve at 58.0 m/s? A race track is to have a banked curve with a radius of 25m. What should be the angle of the bank if the normal force alone is to allow safe travel around the curve at 58.0 m/s?

29. Horizontal Circle The horizontal component of the tension causes the centripetal acceleration The horizontal component of the tension causes the centripetal acceleration See next page for derivation

30. Derivation What about mass???

31. Vertical Circle Look at the forces at the top of the circle Look at the forces at the top of the circle The minimum speed at the top of the circle can be found The minimum speed at the top of the circle can be found See ex. 7.9 on page 205

32. A jet traveling at a speed of 1.20 x 10 2 m/s executes a vertical loop with a radius 5.00 x 10 2 m. Find the magnitude of the force of the seat on a 70.0 kg pilot (a) at the top (b)the bottom of the loop. A jet traveling at a speed of 1.20 x 10 2 m/s executes a vertical loop with a radius 5.00 x 10 2 m. Find the magnitude of the force of the seat on a 70.0 kg pilot (a) at the top (b)the bottom of the loop.

33. Forces in Accelerating Reference Frames Distinguish real forces from fictitious forces Distinguish real forces from fictitious forces Centrifugal force is a fictitious force Centrifugal force is a fictitious force Real forces always represent interactions between objects Real forces always represent interactions between objects

34. Newton’s Law of Universal Gravitation Every particle in the Universe attracts every other particle with a force that is directly proportional to the product of the masses and inversely proportional to the square of the distance between them. Every particle in the Universe attracts every other particle with a force that is directly proportional to the product of the masses and inversely proportional to the square of the distance between them. or

35. Law of Gravitation G is the constant of universal gravitational G is the constant of universal gravitational G = 6.673 x 10 -11 N m² /kg² G = 6.673 x 10 -11 N m² /kg² This is an example of an inverse square law This is an example of an inverse square law

36. Gravitation Constant Determined experimentally Determined experimentally Henry Cavendish Henry Cavendish 1798 1798 The light beam and mirror serve to amplify the motion The light beam and mirror serve to amplify the motion

37. Applications of Universal Gravitation Mass of the earth Mass of the earth Use an example of an object close to the surface of the earth Use an example of an object close to the surface of the earth r ~ R E r ~ R E

38. Applications of Universal Gravitation Acceleration due to gravity Acceleration due to gravity g will vary with altitude g will vary with altitude

39. Gravitational Field Lines Gravitational Field Strength is considered force per unit mass Gravitational Field Strength is considered force per unit mass

40. Gravitational Potential Energy PE = mgy is valid only near the earth’s surface PE = mgy is valid only near the earth’s surface For objects high above the earth’s surface, an alternate expression is needed For objects high above the earth’s surface, an alternate expression is needed Zero reference level is infinitely far from the earth Zero reference level is infinitely far from the earth

41. Einstein’s view of Gravity Space-Time

43. Kepler’s Laws All planets move in elliptical orbits with the Sun at one of the focal points. All planets move in elliptical orbits with the Sun at one of the focal points. A line drawn from the Sun to any planet sweeps out equal areas in equal time intervals. A line drawn from the Sun to any planet sweeps out equal areas in equal time intervals. The square of the orbital period of any planet is proportional to cube of the average distance from the Sun to the planet. The square of the orbital period of any planet is proportional to cube of the average distance from the Sun to the planet.

44. Kepler’s Laws, cont. Based on observations made by Brahe Based on observations made by Brahe Newton later demonstrated that these laws were consequences of the gravitational force between any two objects together with Newton’s laws of motion Newton later demonstrated that these laws were consequences of the gravitational force between any two objects together with Newton’s laws of motion

45. Kepler’s First Law All planets move in elliptical orbits with the Sun at one focus. All planets move in elliptical orbits with the Sun at one focus. Any object bound to another by an inverse square law will move in an elliptical path Any object bound to another by an inverse square law will move in an elliptical path Second focus is empty Second focus is empty

46. Kepler’s Second Law A line drawn from the Sun to any planet will sweep out equal areas in equal times A line drawn from the Sun to any planet will sweep out equal areas in equal times Area from A to B and C to D are the same Area from A to B and C to D are the same

47. Kepler’s Third Law The square of the orbital period of any planet is proportional to cube of the average distance from the Sun to the planet. The square of the orbital period of any planet is proportional to cube of the average distance from the Sun to the planet. For orbit around the Sun, K S = 2.97x10 -19 s 2 /m 3 For orbit around the Sun, K S = 2.97x10 -19 s 2 /m 3 K is independent of the mass of the planet K is independent of the mass of the planet

48. Derivation So…

49. Kepler’s Third Law application Mass of the Sun or other celestial body that has something orbiting it Mass of the Sun or other celestial body that has something orbiting it Assuming a circular orbit is a good approximation Assuming a circular orbit is a good approximation