Ball 1 |
Ball 2 |
|
Mass (kg) |
0.5 |
1.5 |
Velocity (m/s) |
1.0 |
0 |
Momentum (kg*m/s) |
0.5 |
0 |
Predicted momentum ball 1?
Predicted momentum ball 2?
Ball 1 |
Ball 2 |
|
Mass (kg) |
0.5 |
1.5 |
Position |
X = 0.5 Y = 0 |
X = 1.5 Y = 0.2 |
Velocity (m/s) |
X = 1 Y = 0.3 |
X = - 0.50 Y = - 0.50 |
Momentum (kg*m/s) |
X = 0.5 Y = 0.15 |
X = - 0.75 Y = - 0.75 |
Predicted momentum ball 1?
Predicted momentum ball 2?
Elastic collisions: Predict the momentum of each object after the collision. One dimensional motion Ball 1...
3.08 Conservation of Momentum Lab 1. Use the given collisions and data to calculate the initial and final momentum for each collision. 2. Complete calculations totals in results table. Equations: p mv and2p Ep A. Elastic Collision between equal mass Momentum Final (kg"m/s) Momentum Initial (kg"m/s) Initial Velocity Final Velocity (m/s) Collision 1 Mass (kg) (m/s) Mass 1 2.0 +1.0 -1.0 Mass 2 2.0 -1.0 1.0 B. Elastic Collision between unequal mass: 2 Initial Velocity (m/s) Final Velocity (m/s) Momentum...
Name ate Partners HOMEWORK FOR LAB 8: ONE-DIMENSIONAL COLLISIONS Find the impulse of the force shown on the force-time graph below. Explain how you found your anser 1. Tme (o 2 An object of mass 25 kg is moving in the negative x direction at a velocity of 2.0 m/s. It experiences the force shown above for 3 S. What is the final velocity after the object has experienced the impulse Show your ca culations. 3 A ball of mass...
Contrast and compare elastic and inelastic collisions. Question 4 options: Both elastic and inelastic collisions have conservation of momentum if there are no outside forces. They are different in that elastic collisions bounce and inelastic collisions stick, and kinetic energy is conserved in inelastic collisions. They are basically the same thing, except the units are different. Elastic collisions do not have conservation of momentum and inelastic collisions have conservation of momentum if there are no outside forces. They are different...
A 3.0-kg object moving 8.0 m/s in the positive x direction has a one-dimensional elastic collision with an object (mass = M) initially at rest. After the collision, the object of unknown mass has a velocity of 6.0 m/s in the positive x direction. What is M? a. 6.0 kg b.5.0 kg c. 4.2 kg d. 7.5 kg e. 8.0 kg
Ball 1 Ball 2 The table summarizes the known values for a completely elastic collision. Given the information, what is the mass of ball 2? 5.4 ? mass (kg) initial velocity (m/s) final velocity (m/s) 3.0 -4.0 -4.86 2.2 m2= kg
Ball 2 The table summarizes the known values for a completely elastic collision. Given the information, what is the mass of ball 2? mass (kg) initial velocity (m/s) final velocity (m/s) Ball 1 6.7 2.0 -6.18 -5.0 0.83 m2 = m2 = kg
Two billiard balls undergo an elastic collision as shown in the figure below. Ball 1 is initially traveling along x with a speed of 15 m/s, and ball 2 is at rest. After the collision, ball 1 moves away with a speed of 7.5 m/s at an angle θ-60°. (For the following questions, assume the mass of ball 1 is equal to the mass of ball 2.) Ball Ball 1 Ball 21/<θ li (a) Find the speed of ball 2...
In Lab 8 you examined elastic collisions and one type of collision was the standing still (one cart at rest prior to collision) collision. What outcome do you expect from a standing still collisions if: Cart 1 with mass M is moving to the right with a velocity of V and Cart 2 with mass 3M is not moving? Cart 1 will rebound from Cart 2 with a negative velocity with magnitude less than V (moving left) and Cart 2...
The table summarizes the known values for a completely elastic collision. Given the information, what is the mass of ball 2? mass (kg) initial velocity (m/s) final velocity (m/s) Ball 1 4.3 2.0 -6.91 Ball 2 ? -5.0 0.11 kg
The table summarizes the known values for a completely elastic collision. Given the information, what is the mass of ball 27 Ball 1 Ball 2 4.3 ? mass (kg) initial velocity (m/s) final velocity (m/s) 2.0 -5.0 0.11 -6.91 7.49 kg