A sphere with radius 0.195 m has density p that decreases with distance from the center of the sphere according to p=3.00 × 10³ kg/m³ - (9.50 × 10³ kg/m²)r. Part A Calculate the total mass of the sphere. Express your answer with the appropriate units. ? M = Value Units Submit Request Answer Part B Calculate the moment of inertia of the sphere for an axis along a diameter. Express your answer with the appropriate units. pag ? I= Value Units

A sphere with radius 0.195 m has density p that decreases with distance from the center of the sphere according to p=3.00 × 10³ kg/m³ - (9.50 × 10³ kg/m²)r. Part A Calculate the total mass of the sphere. Express your answer with the appropriate units. ? M = Value Units Submit Request Answer Part B Calculate the moment of inertia of the sphere for an axis along a diameter. Express your answer with the appropriate units. pag ? I= Value Units

University Physics Volume 1

18th Edition

ISBN:9781938168277

Author:William Moebs, Samuel J. Ling, Jeff Sanny

Publisher:William Moebs, Samuel J. Ling, Jeff Sanny

Chapter11: Angular Momentum

Section: Chapter Questions

Problem 39P: Suppose the particles in the preceding problem have masses m1=0.10kg , m2=0.20kg , m3=0.30kg ,...

See similar textbooks

Similar questions

The centrifuge at NASA Ames Research Center has a radius of 8.8 m and can produce farces on its payload of 20 gs or 20 times the force of gravity on Earth. (a) What is the angular momentum of a 20-kg payload that experiences 10 gs in the centrifuge? (b) If the driver motor was turned off in (a) and the payload lost 10 kg, what would be its new spin rate, taking into account there are no frictional forces present?
Suppose the particles in the preceding problem have masses m1=0.10kg , m2=0.20kg , m3=0.30kg , m4=0.40kg . The velocities of the particles are . (a) Calculate the angular momentum of each particle about the origin. (b) What is the total angular momentum of the tour-particle system about the origin?
While sunbathing on the balcony of your 3rd floor apartment, you notice a gorilla drop a m = 38.2 kg crate from rest from the roof of the 5-story building across the street. Since you just completed a course on surveying, you know that the two identical buildings are d = 29 m apart, and have floors that are h = 5.1 m tall. The first floor is at ground level, as shown.a. Determine the magnitude of the angular momentum of the crate, in kilogram meters squared per second, as observed by you as it passes the floor of the 4th floor balcony of the other building. Lb =b. Determine the magnitude of the angular momentum of the crate, in kilogram meters squared per second, as observed by you as it passes the floor of the 3rd floor balcony of the other building, directly across from you. Lc =c. Determine the magnitude of the angular momentum of the crate, in kilogram meters squared per second, as observed by you as it passes the floor of the 2nd floor balcony of the other building. Ld =d.…
A ship's wheel can be approximated as an annular cylinder (different from a ring) of mass 6.7 kilograms, inner radius 25 centimeters, and outer radius 32 centimeters; and eight spokes of mass 0.50 kilograms and length 49 centimeters. a. What is the moment of inertia? Include units in your answer. b. Disagreeing over which way to go, the captain and the helmsman try to turn the wheel in opposite directions. The captain applies a force of 311 newtons at the inner radius, while the helmsman applies a force of 287 newtons at the outer radius. What is the magnitude of the angular acceleration of the wheel? Include units in your answer. PLEASE ANSWER IN HANDWRITING
At a particular instant, a 1.0 kg particle's position is r = (4.0î − 2.0ĵ + 3.0) m, its velocity is v = (−1.0î + 2.0ĵ + 1.0) m/s, and the force on it is F = (12.0î + 17.0ĵ) N. (Express your answers in vector form.) (a) What is the angular momentum (in kg · m2/s) of the particle about the origin? (b) What is the torque (in N · m) on the particle about the origin? (c) What is the time rate of change of the particle's angular momentum about the origin at this instant (in kg · m2/s2)?
Prove that the moment of inertia of a solid sphere of uniform density, when rotating around a diameter,is 2MR2/5, where M is the mass of the sphere and R is the radius.Hint: integrate the infinitesimal volume element in spherical coordinates.
A particle of mass m is dropped at the point (−d, 0) and falls vertically in Earth’s gravitational field −gj ^ . (a) What is the expression for the angular momentum of the particle around the z-axis, which points directly out of the page as shown below? (b) Calculate the torque on the particle around the z-axis. (c) Is the torque equal to the time rate of change of the angular momentum?
Modeled after the triatomic molecule problem that is let's consider the three atoms composing the molecule have different masses and coordinate, while the axis of rotation is still y-axis. The first atom has a mass of 6.778 kg, with x coordinate at 2.814 m and y coordinate at 9.967 m. The second atom has a mass of 48.003 kg, with x coordinate at 47.145 m and y coordinate at 17.003 m. The third atom has a mass of 43.312 kg, with x coordinate at 44.89 m and y coordinate at 22.657 m. What is the moment of inertia in the unit of kg m2 with respect to the y axis?
Consider the force vector F=<1,1,1/2>. If the magnitude of the torque T=OP*F is equal to the area of the equilateral triangle formed by the origin, P, and (1,-1,1), then determine the acute angle formed by OP and F. Give your answer in degrees.
a constant horizontal force of magnitude 74.6 N is applied to a uniform solid cylinder by fishing line wrapped around the cylinder. The mass of the cylinder is 19.3 kg, its radius is 0.723 m, and the cylinder rolls smoothly on the horizontal surface. (a) What is the magnitude of the acceleration of the center of mass of the cylinder? (b) What is the magnitude of the angular acceleration of the cylinder about the center of mass? (c) In unit-vector notation, what is the frictional force acting on the cylinder?
two particles A and B at xyz coordinates (1 m, 1 m, 0) and (1 m, 0, 1 m). Acting on each particle are three numbered forces, all of the same magnitude and each directed parallel to an axis. (a) Which of the forces produce a torque about the origin that is directed parallel to y? (b) Rank the forces according to the magnitudes of the torques they produce on the particles about the origin, greatest first
According to one model, the density of Earth varies with the distance r from the center of Earth as ρ = C[1.22 − (r/R)], where R is the radius of Earth and C is a constant. (a) Find C in terms of the total mass M and the radius R. (solved)C = 3M1.88πR3 (b) According to this model, what is the moment of inertia of Earth about an axis through its center? (Use the following as necessary: M and R.) (unsolved)