Two objects collide as shown below. If m_1 is 500 kg and m_2 is 200 kg,...
Two objects with masses of m_1 = 2.00 kg and m_2 = 8.00 kg are connected by a light string that passes over a frictionless pulley, as in the figure below. Determine the tension in the string. (Enter the magnitude only.) Determine the acceleration of each object. (Enter the magnitude only.) Determine the distance each object will move in the first second of motion if both objects start from rest.
Consider the system shown in the figure below with m_1 = 24.0 kg, m_2 = 12.6 kg, R = 0.260 m, and the mass of the pulley M = 5.00 kg. Object m_2 is resting on the floor, and object m_1 is 4.60 m above the floor when it is released from rest. The pulley axis is frictionless. The cord is light, does not stretch, and does not slip on the pulley. Calculate the time interval required for m_1 to...
6. Two balls weighing .200 kg collide head on. Their respective velocities before the collision are 10.0 m/s and -15.0 m/s. a. The collision is completely elastic. What are their respective velocities after the collision. (Hint both conservation laws need to be used) b. If the ba;;s are made of putty and they fuse after the collision what is their speed after the collision.
Referring to the figure above, answer the following questions: A particle of mass m_1 = 1.000 kg moves at speed nu_1 = 0.500 m/s. It collides with a particle of mass m_2 = 2.000 kg at rest. a. What is the total momentum of the system in the x direction before the collision? Answer: b. What is the total momentum of the system in the y direction before the collision? Answer: After the collision, m_1 moves with speed nu_3 at...
Problem 10: Two 1.0-kg balls, A and B, move as shown in the figure and collide. During the collision, half the kinetic energy A is lost. After the collision, ball A is going straight in the vA3m/s V- 2 m/s negative y direction. Find A and B's final velocities. Problem 10: Two 1.0-kg balls, A and B, move as shown in the figure and collide. During the collision, half the kinetic energy A is lost. After the collision, ball A...
Two 6.5 kg bodies, A and B, collide. The velocities before the collision are v→A=(45î+47ĵ)m/s and v→B=(5.4î+4.7ĵ)m/s. After the collision, v→A′=(4.1î+9.8ĵ)m/s. What are (a) the x-component and (b) the y-component of the final velocity of B? (c) What is the change in the total kinetic energy (including sign)?
Two 1.8 kg bodies, A and B, collide. The velocities before the collision are A = (12 + 25) m/s and B = (-10 + 10.0) m/s. After the collision, 'A = (-1.0 + 22) m/s. (a) What is the final velocity of B? = m/s (b) What is the change in the total kinetic energy (including sign)? J
Two 7.5 kg bodies, A and B, collide. The velocities before the collision are v Overscript right-arrow EndScripts Subscript Upper A Baseline equals left-parenthesis 40 i Overscript ̂ EndScripts plus 49 j Overscript ̂ EndScripts right-parenthesis m divided by s and v Overscript right-arrow EndScripts Subscript Upper B Baseline equals left-parenthesis 35 i Overscript ̂ EndScripts plus 11 j Overscript ̂ EndScripts right-parenthesis m divided by s. After the collision, v Overscript right-arrow EndScripts Subscript Upper A Superscript prime Baseline...
Two masses (marbles, clay, or kittens, whichever) 18 kg and 29 kg collide while traveling toward each other at 6 m/s each. If collision were elastic, the total kinetic energy before and after the collision would be the same. Compare the total kinetic energy before and after the collision if it were completely inelastic instead. How much is lost?
Two 2.0 kg bodies, A and B, collide. The velocities before the collision are (251101 m/s and i, - (-331+50))m/s. After the collision, VA= (-5.01 +40)m/s. What are(a) the final velocity of Band (b) the change in the total kinetic energy