Learning Goal:To apply the law of conservation of energy to anobject launched upward in the gravitational field ofthe earth.In the absence of nonconservative forces such asfriction and air resistance, the total mechanicalenergy in a closed system is conserved. This is oneparticular case of the law of conservation of energy.In this problem, you will apply the law ofconservation of energy to different objects launchedfrom the earth. The energy transformations thattake place involve the object's kinetic energyK = (1/2)mv² and its gravitational potentialenergy U = mgh. The law of conservation ofenergy for such cases implies that the sum of theobject's kinetic energy and potential energy doesnot change with time. This idea can be expressedby the equationKị+U=Kf+Uf.where "i" denotes the "initial" moment and "f"denotes the "final" moment. Since any twomoments will work, the choice of the moments toconsider is, technically, up to you. That choice,though, is usually suggested by the question posedin the problem.Part HA ball is launched with initial speed v from ground level up a frictionless slope. The slope makes an angle with thehorizontal. Using conservation of energy, find the maximum vertical height hmax to which the ball will climb.Express your answer in terms of v, g, and 0. You may or may not use all of these quantities.hmax =SubmitPart IRequest AnswerA ball is launched with initial speed v from the ground level up a frictionless hill. The hill becomes steeper as the ball slides up;however, the ball remains in contact with the hill at all times. Using conservation of energy, find the maximum vertical heighthmax to which the ball will climb.Express your answer in terms of u and g.hmax =SubmitRequest Answer

Name: Learning Goal:To apply the law of conservation of energy to anobject
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Description: Learning Goal:To apply the law of conservation of energy to anobject launched upward in the gravitational field ofthe earth.In the absence of nonconservative forces such asfriction and air resistance, the total mechanicalenergy in a closed system is

Given, In the absence of nonconservative forces such as friction and air resistance , the total mechanical energy in closed system is conserved. This is called law of energy and expressed by Ki + Ui = Kf + Uf , K is kinetic energy = 12mv2 and U is potential energy = mgh m is mass , v is velocity and g is gravitational acceleration and h is height.Part H. frictionless slope initial velocity v vertical component of initial velocity = vsinθ From conservation of energy , 12m(vsinθ)2 = mghmax , at hmax , vertical velovity will be 0 and initially h is 0. hmax = v2sin2θ2gPart I. frictionless hill initial velocity v vertical component of initial velocity = v From conservation of energy , 12mv2 = mghmax , at hmax , vertical velovity will be 0 and initially h is 0. hmax = v22g

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Part H A ball is launched with initial speed v from ground level up a frictionless slope. The slope makes an angle with the horizontal. Using conservation of energy, find the maximum vertical height max to which the ball will climb. Express your answer in terms of v, g, and 8. You may or may not use all of these quantities. hmax = Submit Part I Request Answer A ball is launched with initial speed from the ground level up a frictionless hill. The hill becomes steeper as the ball slides up; however, the ball remains in contact with the hill at all times. Using conservation of energy, find the maximum vertical height hmax to which the ball will climb. Express your answer in terms of u and g. hmax =

Part H A ball is launched with initial speed v from ground level up a frictionless slope. The slope makes an angle with the horizontal. Using conservation of energy, find the maximum vertical height max to which the ball will climb. Express your answer in terms of v, g, and 8. You may or may not use all of these quantities. hmax = Submit Part I Request Answer A ball is launched with initial speed from the ground level up a frictionless hill. The hill becomes steeper as the ball slides up; however, the ball remains in contact with the hill at all times. Using conservation of energy, find the maximum vertical height hmax to which the ball will climb. Express your answer in terms of u and g. hmax =

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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