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Chapter 11: Q8Q (page 458)

What is required for the angular momentum of a system to be constant? (a) zero net torque, (b) zero impulse, (c) no energy transfers, (d) zero net force

Short Answer

Expert verified

The angular momentum of the system remains constant, if net torque acting on the system zero.

Step by step solution

01

Definition of Angular Momentum and Torque.

The rotating inertia of an object or system of objects in motion about an axis that may or may not pass through the object or system is described by angular momentum.

The force that can cause an object to twist along an axis is measured as torque. In linear kinematics, force is what causes an object to accelerate.

02

Concept about the torque.

The rate of change in angular momentum of the system is numerically equal to the torque exerted on it. a mathematical expression, a mathematical expression, a

mathematical expression, a mathematical expression

${\overset{鈫�}{蟿}}_{N e t} = \frac{d \overset{鈫�}{L}}{d t} . . . . . . . (1)$

Using equation (1), for angular momentum of the system to be a constant, $L = c o n s \tan t$

$\begin{array}{rcl} {\overset{鈫�}{蟿}}_{N e t} & = & \frac{d \overset{鈫�}{L}}{d t} \\ = & \frac{d (c o n s \tan t)}{d t} \\ = & 0 \end{array}$

As a result, if the net torque operating on the system is zero, the angular momentum of the system remains constant.

Correct option: A

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Most popular questions from this chapter

In Figure11.89depicts a device that can rotate freely with little friction with the axle. The radius is $0.4 m,$ and each of the eight balls has a mass of $0.3 k g .$ The device is initially not rotating. A piece of clay falls and sticks to one of the balls as shown in the figure. The mass of the clay is $0.066 k g$ and its speed just before the collision is $10 m / s .$

(a) Which of the following statements are true, for angular momentum relative to the axle of the wheel? (1) Just before the collision, $r 鈯� = 0.4 \sqrt{2} / 2 = 0.4 c o s (45 掳)$ (for the clay). (2) The angular momentum of the wheel is the same before and after the collision. (3) Just before the collision, the angular momentum of the wheel is $0$ . (4) The angular momentum of the wheel is the sum of the angular momentum of the wheel + clay after the collision is equal to the initial angular momentum of the clay. (6) The angular momentum of the falling clay is zero because the clay is moving in a straight line. (b) Just after the collision, what is the speed of one of the balls?

A rod rotates in the vertical plane around a horizontal axle. A wheel is free to rotate on the rod, as shown in Figure 11.74. A vertical stripe is painted on the wheel remains vertical. Is the translational angular momentum of the wheel relative to location A zero or non-zero? If non-zero, what is its direction? Is the rotational angular momentum of the wheel zero or non-zero? If non-zero, what is its direction? Consider a similar system, but with the wheel welded to the rod (not free to turn). As the rod rotates clock wise, does the stripe on the wheel remain vertical? Is the translational angular momentum of the wheel relatives to location A zero or non-zero? If non-zero, what is its direction? Is the rotational angular momentum of the wheel zero or non-zero? If non-zero, what is its direction?

A board of length $2 d = 6 m$ rests on a cylinder (the 鈥減ivot鈥�). A ball of mass $5 k g$ is placed on the end of the board. Figure 11.104 shows the objects at a particular instant. (a) On a free-body diagram, show the forces acting on the ball + board system, in their correct locations. (b) Take the point at which the board touches the cylinder as location $A .$ What is the magnitude of the torque on the system of (ball + board) about location $A ?$ (c) Which of the following statements are correct? (1) Because there is a torque, the angular momentum of the system will change in the next tenth of a second. (2) The forces balances, so the angular momentum of the system about location $A$ will not change. (3) The forces by the cylinder on the board contributes nothing to the torque about the location $A$ .

Design a decorative 鈥渕obile鈥� to consist of a low-mass rod of length $0.49 m$ suspended from a string so that the rod is horizontal, with two balls hanging from the ends of the rod. At the left end of the rod hangs a ball with mass $0.484 kg$ .At the right end of the rod hangs a ball with mass $0.273 kg$ .You need to decide how far from the left end of the rod you should attach the string that will hold up the mobile, so that the mobile hangs motionless with the rod horizontal (鈥渆quilibrium鈥�). You also need to determine the tension in the string supporting the mobile. (a) What is the tension in the string that supports the mobile? (b) How far from the left end of the rod should you attach the support string?

The Bohr model currently predicts the main energy levels not only for atomic hydrogen but also for other 鈥渙ne-electron鈥� atoms where all but one of the atomic electrons has been removed, such as in ${He}^{+}$ (one electron removed) or (two electrons removed) ${Li}^{+ +}$ . (a) Predict the energy levels in for a system consisting of a nucleus containing protons and just one electron. You need no recapitulate the entire derivation for the Bohr model, but do explain the changes you have to make to take into account the factor . (b) The negative muon $(渭^{-})$ behaves like a heavy electron, with the same charge as the electron but with a mass 207 times as large as the electron mass. As a moving $渭^{-}$ comes to rest in matter, it tends to knock electrons out of atoms and settle down onto a nucleus to form a 鈥渙ne-muon鈥� atom. For a system consisting of a lead nucleus ( ${Pb}^{208}$ has 82 protons and 126 neutrons) and just one negative muon, predict the energy in of a photon emitted in a transition from the first excited state to the ground state. The high-energy photons emitted by transitions between energy levels in such 鈥渕uonic atoms鈥� are easily observed in experiments with muons. (c) Calculate the radius of the smallest Bohr orbit for a $渭^{-}$ bound to a lead nucleus ( ${Pb}^{208}$ has 82 protons and 126 neutrons). Compare with the approximate radius of the lead nucleus (remember that the radius of a proton or neutron is about $1 脳 10^{- 15} m$ , and the nucleons are packed closely together in the nucleus).

Comments: This analysis in terms of the simple Bohr model hints at the results of a full quantum-mechanical analysis, which shows that in the ground state of the lead-muon system there is a rather high probability for finding the muon inside the lead nucleus. Nothing in quantum mechanics forbids this penetration, especially since the muon does not participate in the strong intersection. Electrons in an atom can also be found inside the nucleus, but the probability is very low, because on average the electrons are very far from the nucleus, unlike the muon.

The eventual fate of the $渭^{-}$ in a muonic atom is that it either decays into an electron, neutrino, and antineutrino, or it reacts through the weak interaction with a proton in the nucleus to produce a neutron and a neutrino. This 鈥渕uon capture鈥� reaction is more likely if the probability is high for the muon to be found inside the nucleus, as is the case with heavy nuclei such as lead.

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