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Chapter 11: Q4CP (page 426)

Pinocchio rides a horse on a merry-go-round turning counterclockwise as viewed from above, with his long nose always pointing forwards, in the direction of his velocity. Is Pinocchio’s translational angular momentum relative to the center of the merry-go-round zero or nonzero? In nonzero, what is its direction? Is his rational angular momentum zero or nonzero? If nonzero, what is its direction?

Short Answer

Expert verified

The angular momentum from the right-hand rule points upwards (or) towards the sky.

Step by step solution

01

Definition of Angular Momentum.

Angular momentum is a property that describes an object's or a system of items' rotational inertia in motion around an axis that may or may not pass through the object or system

02

Find the direction of Angular momentum.

The rider's translational angular momentum is nonzero in relation to the merry go round's center of mass.

As the horse on the merry go round turns counter-clockwise, the direction of the animal's motion, as seen from above, is counter-clockwise.

The direction of the position vector from the merry go round's center is towards the horse, and it is heading away from the merry go round's center.

The translational angular momentum of the rider relative to the center of the merry-go-round is equal to the cross product of the position vector and the linear momentum, according to the definition of angular momentum. The angular momentum from the right-hand rule points upwards (or) towards the sky.

The rider's rational angular momentum in relation to the merry go round's center of mass is nonzero.

As the horse on the merry go round turns counterclockwise, the direction of the animal's motion, as seen from above, is counterclockwise.

The direction of the position vector from the merry go round's center is towards the horse, and it is heading away from the merry go round's center.

The cross product of the position vector and the linear momentum is equal to the rational angular momentum of the rider relative to the center of the merry go round, according to the definition of angular momentum. The angular momentum from the right-hand rule is pointing upwards (or) towards the sky.

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Most popular questions from this chapter

Suppose that an asteroid of mass2×1021is nearly at rest outside the solar system, far beyond Pluto. It falls toward the Sun andcrashes into the Earth at theequator, coming in at angle of30°to the vertical as shown, against the direction of rotation of the Earth (Figure 11.101; not to scale). It is so large that its motion is barely affected by the atmosphere.

(a) Calculate the impact speed. (b) Calculate the change in the length of a day due to the impact.

A common amusement park ride is a Ferris wheel (see figure, which is not drawn to scale). Riders sit in chairs that are on pivots so they remain level as the wheel turns at a constant rate. A particular Ferris wheel has a radius of 24 meters, and it make one complete revolution around its axle (at location A) in 20sIn all of the following questions, consider location A(at the center of the axle) as the location around which we will calculate the angular momentum. At the instant shown in the diagram, a child of mass40kg, sitting at location F, is traveling with velocity <7.5,0,0>m/s.

(a.) What is the linear momentum of the child? (b) In the definition L→=r→×p→,what is the vector r→? (c) what is r→⊥? (d) what is the magnitude of the angular momentum of the child about location A? (e) What is the plane defined by r→andp→(that is, the plane containing both of these vectors)? (f) Use the right-hand rule to determine thecomponent of the angular momentum of the child about locationA. (g) You used the right-hand rule to determine the zcomponent of the angular momentum, but as a check, calculate in terms of position and momentum: What isypx? Therefore, what iszthe component of the angular momentum of the child about locationA? (h) The Ferris wheel keeps turning, and at a later time, the same child is at locationEwith coordinates<16.971,-16.971,0>m relative to location A, moving with velocity<5.303,5.303,0>m/s.Now what is the magnitude of the angular momentum of the child about location A?

A uniform-density wheel of mass and radius rotates on a low-friction axle. Starting from rest, a string wrapped around the edge exerts a constant force of 15Nfor0.6s (a) what is the final angular speed? (b) what is the average angular speed? (c) Through how big an angle did the wheel turn? (d) How much string come off the wheel?

A device consists of eight balls, each of massattached to the ends of low-mass spokes of length L so the radius of rotation of ball is L/2. The device is mounted in the vertical plane, as shown in Figure 11.73. The axle is help up by supports that are not shown, and the wheel is free to rotate on the nearly frictionless axle. A lump of clay with massm falls and sticks to one of the balls at the location shown, when the spoke attached to that ball is 45°to the horizontal. Just before the impact the clay has a speed v, and the wheel is rotating counter clock wise with angular speedӬ .

(a.) Which of the following statements are true about the device and the clay, for angular momentum relative to the axle of the device? (1) the angular momentum of the device + clay just after the collision is equal to the angular momentum of the device +clay just before the collision. (2) The angular momentum of the falling clay is zero because the clay is moving in a straight line. (3) Just before the collision, the angular momentum of the wheel is 0. (4) The angular momentum of the device is the sum of the angular momenta of all eight balls. (5) The angular momentum of the device is the same before and after the collision. (b) Just before the impact, what is the (vector) angular momentum of the combined system of device plus clay about the center C? (As usual, xis to the right, yis up, and zis out of the screen, toward you) (c) Just after the impact, what is the angular momentum of the combined system of device plus clay about the center C? (d) Just after the impact, what is the (vector) angular velocity of the device? (e) Qualitatively. What happens to the total linear momentum is changed system? Why? (1) some of the linear momentum is changed into energy. (2) some of the linear momentum is changed into angular momentum. (3) There is no change because linear momentum is always conserved. (4) The downward linear momentum decreases because the axle exerts an upwards force. (f) qualitatively, what happens to the total kinetic energy of the combined system? Why? (1) some of the kinetic energy is changed into linear momentum. (2) some of the kinetic energy is changed into angular momentum. (3) The total kinetic energy decreases because there is an increase of internal energy in this inelastic collision. (4) There is no change because kinetic energy is always conserved.

A barbell is mounted on a nearly frictionless axle through its center (Figure 11.105). At this instant, there are two forces of equal magnitude applied to the system as shown, with the directions indicated, and at this instant, the angular velocity is 60 Rad/s, counterclockwise. In the next 0.001s,the angular momentum relative to the center increases by an amount 2.5 kg.meter square per second. What is the magnitude of each force? What is the net force?
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