A baby carriage is sitting at the top of a hill that is 21 m high....

A 2000 kg car reaches the top of a 100 meter high hill at A with...

A 2000 kg car reaches the top of a 100 meter high hill at A with a speed vA = 40 m/s . What is the speed vB at the top of the 150 m high hill at B if all sources of friction do work equal to −500,000 J on the car as it coasts in neutral from A to B? 13.5 m/s 11.0 m/s 18.6 m/s 10.1 m/s 14.9 m/s

A 2.0 kg stone slides from rest down a hill 5.0 m high and is observed...

A 2.0 kg stone slides from rest down a hill 5.0 m high and is observed to be moving at 6.0 m/s at the bottom. During this process, how much thermal energy have been produced due to the friction?

Which of the following statements about energy is NOT true? A rock sitting at the top...

Which of the following statements about energy is NOT true? A rock sitting at the top of a hill has thermal energy, gravitational energy, and mechanical energy. Total internal energy depends on temperature, the type of particles, and the number of particles. Energy is always transferred from the hotter to the cooler substance. Thermal energy increases with temperature.

A 1250 kg car drives up a hill that is 15.2 m high. During the drive,...

A 1250 kg car drives up a hill that is 15.2 m high. During the drive, two nonconservative forces do work on the car: (i) the force of friction, and (ii) the force generated by the car's engine. The work done by friction is −2.91×105 J ; the work done by the engine is 6.44×105 J . Part A Find the change in the car's kinetic energy from the bottom of the hill to the top of the hill.

A 2,000 kg car reaches the top of a 100 meter hill at A with a...

A 2,000 kg car reaches the top of a 100 meter hill at A with a speed vA = 40 m/s as shown in the figure below. A hill B is shown in the figure to the right of hill A. (a) Assume there is no frictional loss of energy between the car and the hills. What is the speed of the car (vB) when it gets to the top of the 150 meter hill at B? PHYS 201-001 Summer...

A small sports car and a pickup truck start coasting down a 12 m hill together,...

A small sports car and a pickup truck start coasting down a 12 m hill together, side by side. The mass of the sports car is 640 kg and the mass of the pickup truck is 1280 kg (twice the mass of the sports car). Assuming no friction or air resistance, what is the kinetic energy of each vehicle at the bottom of the hill? Give your answers in joules. HINT: How does the kinetic energy of a vehicle at...

A hollow sphere (mass M, radius R) starts from rest at the top of a hill...

A hollow sphere (mass M, radius R) starts from rest at the top of a hill of height H. It rolls down the hill without slipping. Find an expression for the speed of the ball's center of mass once it reaches the bottom of the hill.

A 41.0-kg skier with an initial speed of 1.5 X 101 m/s coasts up a 2.50-m-high...

A 41.0-kg skier with an initial speed of 1.5 X 101 m/s coasts up a 2.50-m-high rise as shown below. The coefficient of friction between her skis and the snow is 0.0800. a) Where do you define the gravitational potential energy Ug to equal 0 J? b) If the skier has energy at the bottom of the hill state what kind it is and determine its value. c) If the skier reaches the top of the hill what kind of...

Two objects of equal mass m are at rest at the top of a hill of...

Two objects of equal mass m are at rest at the top of a hill of height h. Object 1 is a circular hoop of radius r, and object 2 is a solid disc, also of radius r. The object are released from rest and roll without slipping. A) Provide expressions for the LINEAR VELOCITY of each object once it reaches the bottom of the hill. Careful - you should provide two answers! B) Considering your results from part A,...

A group of kids are racing hula hoops down a hill that is 0.8 m high....

A group of kids are racing hula hoops down a hill that is 0.8 m high. One hoop is .7kg with a radius of 67 cm and the other hoop is .5kg with a radius of 43cm. If both hoops are initially traveling at 1.2 m/s right after they are pushed off the top of the hill, what hoop will reach the bottom first use the conservation of energy to support your answer. What is the change in angular momentum...