A glider with mass m=0.200kg sits on a frictionless horizontal air track, connected to a spring of negligible mass with force constant k=5.00N/m. Suppose the glider is initially at rest at x=0, with the spring unstretched. Then you apply a constant force F⃗ with magnitude 0.583 N to the glider. What is the glider’s speed when it has moved to x=0.100m? If the 0.583 N force is removed when the glider reaches the 0.100 m point, at what distance from the starting point does the glider come to rest?
A glider with mass m=0.200kg sits on a frictionless horizontal air track, connected to a spring...
A glider with mass m=0.200kg sits on a frictionless horizontal air track, connected to a spring of negligible mass with force constant k=5.00N/m. Suppose the glider is initially at rest at x=0, with the spring unstretched. Then you apply a constant force F⃗ with magnitude 0.650 N to the glider. What is the glider’s speed when it has moved to x=0.100m? If the 0.650 N force is removed when the glider reaches the 0.100 m point, at what distance from the...
A glider with mass m = 0.200 kg sits on a frictionless horizontal air track, connected to a spring with force constant k = 5.20 N/m . You pull on the glider, stretching the spring 0.130 m , and then release it with no initial velocity. The glider begins to move back toward its equilibrium position ( x=0 ). Part A What is the speed of the glider when it returns to x=0 ? Part B What must the initial...
A glider with mass m = 0.5 kg sits on a frictionless air track. It is connected to a massless spring with force constant k = 40 N/m. The glider is initially at x=0, and the spring is relaxed. You then hit the glider with a hammer, which gives it an initial velocity of υ0 = 5 m/s in the positive x direction. At what x positions will the speed of the glider be zero?
Now let’s use the concept of elastic potential energy to solve a problem involving a spring. A glider with mass m=0.200kg sits on a frictionless horizontal air track, connected to a spring of negligible mass with force constant k=5.00N/m. You pull on the glider, stretching the spring 0.100 m, and then release it with no initial velocity. The glider begins to move back toward its equilibrium position (x=0). What is its speed when x=0.0800m? Part a: What is the value...
An air-track glider of mass 0.100 kg is attached to the end of a horizontal air track by a spring with force constant 20.0 N/m. Initially the spring is unstreched and the glider is moving at 1.50 m/s to the right. With the air track turned off, the coefficient of kinetic friction is μk=0.47. It can be shown that with the air track turned off, the glider travels 8.6 cm before it stops instantaneously. How large would the coefficient of...
An air-track glider of mass 0.100 kg is attached to the end of a horizontal air track by a spring with force constant 20.0 N/m. Initially the spring is unstreched and the glider is moving at 1.50 m/s to the right. With the air track turned off, the coefficient of kinetic friction is μk=0.47. It can be shown that with the air track turned off, the glider travels 8.6 cm before it stops instantaneously. If the coefficient of static friction...
Page 205 Practice Problem 7.12: If the 0.610 N force is removed when the glider reaches the O. is removed when the glider reaches the 0.10 m point, at what distance from the starting point does the glider come to rest? Answer: EXAMPLE 7.12 Work and energy on an air track DH Video Tutor Solution Now let's revisit Example 7.8, adding a nonconservative force to the system. Suppose the glider is initially at rest at x = 0, with the...
A 700 g air-track glider attached to a spring with spring constant 12 N/m is sitting at rest on a frictionless air track. A 250 g glider is pushed toward it from the far end of the track at a speed of 170 cm/s . It collides with and sticks to the 700 g glider.
Problem 2 A 0.175-kg glider on a horizontal, frictionless air track is attached to a fixed ideal spring with spring constant 155 N/m. When the glider is 3.00 cm from its equilibrium point, it is moving at 0.815 m/s. (a) Find the frequency of the oscillations. (b) Find the amplitude of the motion. (c) Find the maximum speed of the glider. Hint: For (b) and (c), use the energy conservation.
A 330 g air-track glider attached to a spring with spring constant 11 N/m is sitting at rest on a frictionless air track. A 330 g glider is pushed toward it from the far end of the track at a speed of 120 cm/s . It collides with and sticks to the 330g glider. What is the amplitude of the subsequent oscillations? What is their period?