A box of mass m is pressed against (but is not attached to) an idealspring of force constant k and negligible mass, compressing thespring a distance x. After it is released, the box slides up africtionless incline as shown in the figure and eventually stops. Ifwe repeat this experiment but instead use a spring having forceconstant 2kkSmooth0000000-Smooththe box will go up the incline twice as high as before.none of the choicesO just as it moves free of the spring, the speed of the box will be twotimes as great as before.tne block will go up the incline to half as high as before.O just as it moves free of the spring, the kinetic energy of the box will betwice as great as before.

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A box of mass m is pressed against (but is not attached to) an ideal spring of force constant k and negligible mass, compressing the spring a distance x. After it is released, the box slides up a frictionless incline as shown in the figure and eventually stops. If we repeat this experiment but instead use a spring having force constant 2k Smooth 000000 Smooth O the box will go up the incline twice as high as before. O none of the choices O just as it moves free of the spring, the speed of the box will be two times as great as before. O tne block will go up the incline to half as high as before. O just as it moves free of the spring, the kinetic energy of the box will be twice as great as before.

A box of mass m is pressed against (but is not attached to) an ideal spring of force constant k and negligible mass, compressing the spring a distance x. After it is released, the box slides up a frictionless incline as shown in the figure and eventually stops. If we repeat this experiment but instead use a spring having force constant 2k Smooth 000000 Smooth O the box will go up the incline twice as high as before. O none of the choices O just as it moves free of the spring, the speed of the box will be two times as great as before. O tne block will go up the incline to half as high as before. O just as it moves free of the spring, the kinetic energy of the box will be twice as great as before.

College Physics

11th Edition

ISBN:9781305952300

Author:Raymond A. Serway, Chris Vuille

Publisher:Raymond A. Serway, Chris Vuille

Chapter1: Units, Trigonometry. And Vectors

Section: Chapter Questions

Problem 1CQ: Estimate the order of magnitude of the length, in meters, of each of the following; (a) a mouse, (b)...

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Concept explainers

Spring Potential Energy

The potential energy is the energy possessed by a body by virtue of its position or the energy held by the object due to its position relative to other objects, its force like stresses, charge, and other factors affecting the particles of the body. The potential energy is the measure of the net work done by or on the body. The spring potential energy is the potential energy stored due to the deformation of an elastic spring and this elasticity is due to the stretched spring. The elasticity is the ability of a solid-state matter to come back to its equilibrium position or original position after any kind of external force is acted on it. It is also known as Elastic potential energy. The potential energy here is caused due to the displacement of the spring from its equilibrium position to another position and this potential energy is equal to the net work done due to the stretching of the spring. It also resembles the same mechanics of the oscillation of a simple pendulum, where due to the external force, the object moves from its equilibrium position to its maximum ends and the periodic motion continues till it comes back to the equilibrium position to rest. 

Question

A box of mass m is pressed against (but is not attached to) an ideal
spring of force constant k and negligible mass, compressing the
spring a distance x. After it is released, the box slides up a
frictionless incline as shown in the figure and eventually stops. If
we repeat this experiment but instead use a spring having force
constant 2k
k
Smooth
0000000-
Smooth
the box will go up the incline twice as high as before.
none of the choices
O just as it moves free of the spring, the speed of the box will be two
times as great as before.
tne block will go up the incline to half as high as before.
O just as it moves free of the spring, the kinetic energy of the box will be
twice as great as before.

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A box of mass m is pressed against (but is not attached to) an ideal spring of force constant and negligible mass, compressing the spring a distance x. After it is released, the box slides up a frictionless incline as shown in the figure and eventually stops. If we repeat this experiment (compressing the spring by the same amount) with a box of mass 2m: k m 0000000 Smooth Smooth both boxes will have the same speed just as they move free of the spring. both boxes will reach the same maximum height on the incline. the lighter box will go twice as high up the incline as the heavier box. just as it moves free of the spring, the heavier box will have twice as much kinetic energy as the lighter box. just as it moves free of the spring, the lighter box will be moving twice as fast as the heavier box.
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