A bicyclist is stopped at the entrance to a valley, as sketched below: F D Where would the bicyclist have the highest potential energy? (choose one) v Where would the bicyclist have the lowest potential energy? (choose one) v Where would the bicyclist have the highest kinetic energy? (choose one) v Where would the bicyclist have the highest speed? (choose one) v Would the bicyclist's kinetic energy be higher at A or D? (choose one) Would the bicyclist's potential energy be higher at A or D? (choose one) Would the bicyclist's total energy be higher at A or D? (choose one) Suppose the bicyclist lets off the brakes and coasts down into the valley without pedaling. Even if there is no friction or air resistance to slow him down, what is the farthest point the bicyclist could reach without pedaling? (choose one)

A bicyclist is stopped at the entrance to a valley, as sketched below: F D Where would the bicyclist have the highest potential energy? (choose one) v Where would the bicyclist have the lowest potential energy? (choose one) v Where would the bicyclist have the highest kinetic energy? (choose one) v Where would the bicyclist have the highest speed? (choose one) v Would the bicyclist's kinetic energy be higher at A or D? (choose one) Would the bicyclist's potential energy be higher at A or D? (choose one) Would the bicyclist's total energy be higher at A or D? (choose one) Suppose the bicyclist lets off the brakes and coasts down into the valley without pedaling. Even if there is no friction or air resistance to slow him down, what is the farthest point the bicyclist could reach without pedaling? (choose one)

Name: O THERMOCHEMISTRYUsing conservation of energy to predict the qualitat
Uploaded: 2024-03-20T06:57:16.000Z
Channel: Bartleby
Description: O THERMOCHEMISTRYUsing conservation of energy to predict the qualitative exchang...A bicyclist is stopped at the entrance to a valley, as sketched below:BWhere would the bicyclist have the highest potential energy?(choose one) vWhere would the bicyc

College Physics

1st Edition

ISBN:9781938168000

Author:Paul Peter Urone, Roger Hinrichs

Publisher:Paul Peter Urone, Roger Hinrichs

Chapter7: Work, Energy, And Energy Resources

Section: Chapter Questions

Problem 13CQ: Consider the following scenario. A car for which friction is not negligible accelerates from rest...

See similar textbooks

Similar questions

Give an example of something we think of as work in everyday circumstances that is not work in the scientific sense. Is energy transferred or changed in form in your example? If so, explain how this is accomplished without doing work.
The man of the preceding problem consumes approximately 1.05107J (2500 food calories) of energy per day in maintaining a constant weight. What is the average power he produces over a day? Compare this with his power production when he runs up the stairs.
Ignoring details associated with friction, extra forces exerted by arm and leg muscles, and other factors, we can consider a pole vault as the conversion of an athlete’s running kinetic energy to gravitational potential energy. If an athlete is to lift his body 4.8 m during a vault, what speed must he have when he plants his pole?
In an iconic movie scene, Forrest Gump (https://openstaxcollege.org/l/21ForrGumpvid) runs around the country. If he is running at a constant speed of 3 m/s, would it take him more or less energy to run uphill or downhill and why?
If you hold this textbook out at shoulder height and let go, at the instant you let go, does the book have potential energy? Kinetic energy?
Consider the following scenario. A car for which friction is not negligible accelerates from rest down a hill, running out of gasoline after a short distance (see below). The driver lets the car coast farther down the hill, then up and over a small crest. He then coasts down that hill into a gas station, where he brakes to a stop and fills that tank with gasoline. Identify the forms of energy the car has, and how they are changed and transferred in this series of events.
(a) How fast must a 3000-kg elephant move to have the same kinetic energy as a 65.0-kg sprinter running at 10.0 m/s? (b) Discuss how the larger energies needed for the movement of larger animals would relate to metabolic rates.
When released, a 100-g block slides down the path shown below, reaching the bottom with a speed of 4.0 m/s. How much work does the force of friction do?
Suppose you are jogging at constant velocity. Are you doing any work on the environment and vice versa?
At hokey puck of mass 0.17 kg is shot across a rough floor with the roughness different at different places, which can be described by a position-dependent coefficient of kinetic friction. For a puck moving along the x-axis, the coefficient of kinetic friction is the following function of x, where x is in m: (x)=0.1+0.05x . Find the work done by the kinetic frictional forte on the hockey puck when it h moved (a) from x=0 to x=2 m, and (b) from x=2 m to x=4 m.
Consider the following scenario. A car for which friction is not negligible accelerates from rest down a hill, running out of gasoline after a short distance. The driver lets the car coast farther down the hill, then up and over a small crest. He then coasts down that hill into a gas station, where he brakes to a stop and fills the tank with gasoline. Identify the forms of energy the car has, and how they are changed and transferred in this series of events. (See Figure 7.34.) Figure 7.34 A car experiencing non-negligible friction coasts down a hill, over a small crest then dill again, and comes to a stop at a gas station.
Describe a situation in 4iich a force is exerted for a long time but does no work. Explain.