Physics 207: Lecture 8, Pg 1 Physics 207, Lecture 8, Oct. 1, by Prof. Pupa Gilbert Agenda: Chapter 7 (Circular Motion, Dynamics III )  Uniform and non-uniform.

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Physics 207: Lecture 8, Pg 1 Physics 207, Lecture 8, Oct. 1, by Prof. Pupa Gilbert Agenda: Chapter 7 (Circular Motion, Dynamics III )  Uniform and non-uniform circular motion Next time: Problem Solving and Review for MidTerm I Assignment: (NOTE special time!) l MP Problem Set 4 due Oct. 3,Wednesday, 4 PM l MidTerm Thurs., Oct. 4, Chapters 1-6 & 7 (lite), 90 minutes, 7:15-8:45 PM Rooms: B102 & B130 in Van Vleck. Honors class this Friday 8.50 AM, in 5310 Chamberlin Hall Notice new location!!! this Friday only

Physics 207: Lecture 8, Pg 2 Rotation requires a new lexicon Arc traversed s =  r l Tangential velocity v t l Period and frequency l Angular position l Angular velocity Period (T): The time required to do one full revolution, 360 ° or 2  radians Frequency (f): 1/T, number of cycles per unit time Angular velocity or speed  = 2  f = 2  /T, number of radians traced out per unit time demo r  vtvt s

Physics 207: Lecture 8, Pg 3 Relating rotation motion to linear velocity l Assume a particle moves at constant tangential speed v t around a circle of radius r. l Distance = velocity x time Once around… 2  r = v t T or, rearranging (2  /T) r = v t  r = v t Definition: UCM is uniform circular motion (  constant ) r  vtvt s

Physics 207: Lecture 8, Pg 4 Angular displacement and velocity Arc traversed s =  r in time  t then  s =  r so  s /  t = (  /  t) r in the limit  t  0 one gets ds/dt = d  /dt r v t =  r  = d  /dt if  is constant, integrating  = d  /dt, we obtain:  =   +  t Counter-clockwise is positive, clockwise is negative and we note that v radial (or v r ) and v z (are both zero if UCM) bb3 r  vtvt s

Physics 207: Lecture 8, Pg 5 Lecture 7, Exercise 1 A Ladybug sits at the outer edge of a merry-go-round, and a June bug sits halfway between the outer one and the axis of rotation. The merry-go-round makes a complete revolution once each second. What is the June bug’s angular velocity? J L A.half the Ladybug’s. B.the same as the Ladybug’s. C.twice the Ladybug’s. D.impossible to determine.

Physics 207: Lecture 8, Pg 6 Lecture 7, Exercise 1 A Ladybug sits at the outer edge of a merry-go-round, and a June bug sits halfway between the outer one and the axis of rotation. The merry-go-round makes a complete revolution once each second. What is the June bug’s angular velocity? J L A.half the Ladybug’s. B.the same as the Ladybug’s. C.twice the Ladybug’s. D.impossible to determine. demo

Physics 207: Lecture 8, Pg 7 Then angular velocity is no longer constant so d  /dt ≠ 0 l Define tangential acceleration as a t =dv t /dt Can we relate a t to d  /dt?  =  o +  o t + t 2  =  o + t l Many analogies to linear motion but it isn’t one-to-one l Most importantly: even if the angular velocity is constant, there is always a radial acceleration. And if  is increasing… 1 2 atat r atat r bb4

Physics 207: Lecture 8, Pg 8 Newton’s Laws and Circular Motion (Chapter 7) Centripetal Acceleration a c = v t 2 /r Circular motion involves continuous radial acceleration and this means a central force. F c = ma c = mv t 2 /r = m  2 r vtvt r acac Uniform circular motion involves only changes in the direction of the velocity vector, thus acceleration is perpendicular to the trajectory at any point, acceleration is only in the radial direction. Quantitatively (see text) No central force…no UCM!

Physics 207: Lecture 8, Pg 9 Examples of central forces are: çT on the string holding the ball çGravity (moon, solar system, satellites, space crafts….) çPositive charge of the nucleus, for the e - çCentripetal friction acting on the ladybug çBall on a loop-the-loop track ( n on the track)

Physics 207: Lecture 8, Pg 10 Circular Motion l UCM enables high accelerations (g’s) in a small space l Comment: In automobile accidents involving rotation severe injury or death can occur even at modest speeds. [In physics speed doesn’t kill….acceleration (i.e., force) does.] demo: cut the string

Physics 207: Lecture 8, Pg 11 Mass-based separation with a centrifuge How many g’s? BeforeAfter a c =v 2 / r and f = 10 4 rpm is typical with r = 0.1 m and v =  r = 2  f r bb5

Physics 207: Lecture 8, Pg 12 Mass-based separation with a centrifuge How many g’s? BeforeAfter a c =v 2 / r and f = 10 4 rpm is typical with r = 0.1 m and v =  r = 2  f r v = (2  x 10 4 / 60) x 0.1 m/s =100 m/s a c = 1 x 10 4 / 0.1 m/s 2 = 10,000 g bb5

Physics 207: Lecture 8, Pg 13 g-forces with respect to humans l 1 gStanding l 1.2 gNormal elevator acceleration (up). l 1.5-2g Walking down stairs. l 2-3 gHopping down stairs. l 1.5 gCommercial airliner during takeoff run. l 2 gCommercial airliner at rotation l 3.5 gMaximum acceleration in amusement park rides (design guidelines). l 4 gIndy cars in the second turn at Disney World (side and down force). l 4+ gCarrier-based aircraft launch. l 10 gThreshold for blackout during violent maneuvers in high performance aircraft. l 11 gAlan Shepard in his historic sub orbital Mercury flight experience a maximum force of 11 g. l 20 gColonel Stapp’s experiments on acceleration in rocket sleds indicated that in the g range there was the possibility of injury because of organs moving inside the body. Beyond 20 g they concluded that there was the potential for death due to internal injuries. Their experiments were limited to 20 g. l 30 gThe design maximum for sleds used to test dummies with commercial restraint and air bag systems is 30 g.

Physics 207: Lecture 8, Pg 14 Acceleration has its limits “High speed motion picture camera frame: John Stapp is caught in the teeth of a massive deceleration. One might have expected that a test pilot or an astronaut candidate would be riding the sled; instead there was Stapp, a mild mannered physician and diligent physicist with a notable sense of humor. Source: US Air Force photoJohn StappUS Air Force

Physics 207: Lecture 8, Pg 15 A bad day at the lab…. l In 1998, a Cornell campus laboratory was seriously damaged when the rotor of an ultracentrifuge failed while in use. l Description of the Cornell Accident -- On December 16, 1998, milk samples were running in a Beckman. L2-65B ultracentrifuge using a large aluminum rotor. The rotor had been used for this procedure many times before. Approximately one hour into the operation, the rotor failed due to excessive mechanical stress caused by the g-forces of the high rotation speed. The subsequent explosion completely destroyed the centrifuge. The safety shielding in the unit did not contain all the metal fragments. The half inch thick sliding steel door on top of the unit buckled allowing fragments, including the steel rotor top, to escape. Fragments ruined a nearby refrigerator and an ultra-cold freezer in addition to making holes in the walls and ceiling. The unit itself was propelled sideways and damaged cabinets and shelving that contained over a hundred containers of chemicals. Sliding cabinet doors prevented the containers from falling to the floor and breaking. A shock wave from the accident shattered all four windows in the room. The shock wave also destroyed the control system for an incubator and shook an interior wall.

Physics 207: Lecture 8, Pg 16 Non-uniform Circular Motion For an object moving along a curved trajectory, with non-uniform speed a = a r + a t (radial and tangential) arar atat What are F r and F t ? ma r and ma t a r = v2v2 r dt d| | v a t =

Physics 207: Lecture 8, Pg 17 Lecture 7, Example Gravity, Normal Forces etc. Consider a person on a swing: When is the tension on the rope largest? And at that point is it : (A) greater than (B) the same as (C) less than the force due to gravity acting on the person?

Physics 207: Lecture 8, Pg 18 Lecture 7, Example Gravity, Normal Forces etc. v mgmg T at bottom of swing v t is max F c = m a c = m v t 2 / r = T - mg T = mg + m v t 2 / r T > mg mgmg T at top of swing v t =0 F c = m 0 2 / r = 0 = T – mg cos  T = mg cos  T < mg 

Physics 207: Lecture 8, Pg 19 A match box car is going to do a loop-the-loop of radius r. What must be its minimum speed v t at the top so that it can manage the loop successfully ? Loop-the-loop 1 demo

Physics 207: Lecture 8, Pg 20 To navigate the top of the circle its tangential velocity v t must be such that its centripetal acceleration at least equals the force due to gravity. At this point n, the normal force, goes to zero. Loop-the-loop 1 F c = ma c = mg = mv 2 /r v = (gr) 1/2 mgmg vtvt bb6

Physics 207: Lecture 8, Pg 21 The match box car is going to do a loop-the-loop. If the speed at the bottom is v B, what is the normal force, n, at that point? Hint: The car is constrained to the track. Loop-the-loop 3 mgmg v n F c = ma c = mv B 2 /r = n - mg n = mv B 2 /r + mg bb7

Physics 207: Lecture 8, Pg 22 Example Problem Swinging around a ball on a rope in a “nearly” horizontal circle over your head. Eventually the rope breaks. If the rope breaks at 64 N, the ball’s mass is 0.10 kg and the rope is 0.10 m How fast is the ball going when the rope breaks? (neglect g) (mg = 1 N) T = 40 N F c = m v t 2 / r v t = (r F c / m) 1/2 v t = (0.10 x 64 / 0.10) 1/2 m/s v t = 8 m/s bb8

Physics 207: Lecture 8, Pg 23 Lecture 8, Example Circular Motion Forces with Friction (recall ma c = m v 2 / r F f ≤  s n ) l How fast can the race car go? (How fast can it round a corner with this radius of curvature?) m car = 1600 kg  S = 0.5 for tire/road r = 80 m g = 10 m/s 2 r

Physics 207: Lecture 8, Pg 24 l Only one force, that of friction, is in the horizontal direction x-dir: F c = ma c = m v 2 / r = F s =  s n (at maximum) y-dir: ma = 0 = n – mg n = mg v = (  s m g r / m ) 1/2 v = (  s g r ) 1/2 = (  x 10 x 80) 1/2 v = 20 m/s Lecture 8, Example n mgmg FsFs m car = 1600 kg  S = 0.5 for tire/road r = 80 m g = 10 m/s 2

Physics 207: Lecture 8, Pg 25 Banked Curves In the previous scenario, we drew the following free body diagram for a race car going around a curve on a flat track. n mgmg FfFf What differs on a banked curve?

Physics 207: Lecture 8, Pg 26 Banked Curves Free Body Diagram for a banked curve. Use rotated x-y coordinates Resolve into components parallel and perpendicular to bank n mgmg FfFf For very small banking angles, one can approximate that F f is parallel to ma c. This is equivalent to the small angle approximation sin  = tan , but very effective at pushing the car toward the center of the curve!! macmaci j 

Physics 207: Lecture 8, Pg 27 Navigating a hill Knight concept exercise: A car is rolling over the top of a hill at speed v. At this instant, A. n > w. B. n = w. C. n < w. D.We can’t tell about n without knowing v. This occurs when the normal force goes to zero or, equivalently, when all the weight is used to achieve circular motion. F c = mg = m v 2 /r  v = (gr) 1/2 ½ (just like an object in orbit) Note this approach can also be used to estimate the maximum walking speed. At what speed does the car lose contact?

Physics 207: Lecture 8, Pg 28 Once again the car is going to execute a loop-the-loop. What must be its minimum speed at the bottom so that it can make the loop successfully? This is a difficult problem to solve using just forces. We will skip it now and revisit it using energy considerations later on… Loop-the-loop 2

Physics 207: Lecture 8, Pg 29 Lecture 8, Exercise l When a pilot executes a loop-the- loop (figure on the right) the aircraft moves in a vertical circle of radius R=2.70 km at a constant speed of v=225 m/s. Is the force exerted by the seat on the pilot: (A) Larger (B) Same (C) Smaller than the pilot’s weight (mg) at (I) the bottom and (II) at the top of the loop? 2.7 km