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5. Natalie and Angela are doing The Cart and the Brick Lab. They drop a brick...
A cart of mass 0.20 kg starts moving at velocity 3.0 m/s collides inelastically with an...
A cart of mass 0.20 kg starts moving at velocity 3.0 m/s collides inelastically with an initially stationary cart of mass 0.40 kg. (A) If the carts stick together, what is their combined velocity immediately after the collision? (B) How much kinetic energy is lost in the collision?
Problem 4 In a lab experiment, a cart of mass 2 kg, moving initially to the...
Problem 4 In a lab experiment, a cart of mass 2 kg, moving initially to the right at 3 m/s, collides head-on with a cart of unknown mass, moving initially to the left at 2 m/s. As a result of the collision, the carts bounce back with exactly the opposite velocity of what they had going in. Assume the system is effectively isolated (a)What is the mass of the second cart? (b)What is the total momentum of the system? (c)What...
In a physics lab, a 0.500-kg cart (Cart A) moving with a speed of 130 m/s...
In a physics lab, a 0.500-kg cart (Cart A) moving with a speed of 130 m/s encounters a magnetic collision with a 1.50-kg cart (Cart B) which is initially at rest. The 0.500-kg cart rebounds with a speed of 50 m/s in the opposite direction. Determine the post-collision speed of the 1.50-kg cart.
You have two carts labeled A and B as shown in the figure above. Cart A...
You have two carts labeled A and B as shown in the figure above. Cart A is twice the mass of cart B and is moving with a velocity of 5 m/s towards cart B. Cart Bis stationary. The magnitude of the total linear momentum of the system before the collision is 50 kg m/s. After the collision, both the carts stick and move together. What is the magnitude of the final velocity of the system? VA=5 m/s Vp=0 А...
4. Two carts collide and stick together in a lab experiment. Cart 1 has a mass...
4. Two carts collide and stick together in a lab experiment. Cart 1 has a mass of 550 g and a speed before the collision of 2.5 m/s. Cart 2 has a mass of 320 g and a speed of -4.1 m/s. Consider the 2 carts to be the system. A. What is the total momentum of the system before the collision? B. What is the velocity of the 2 carts after the collision? C. If the collision takes 0.15s,...
4. Two carts collide and stick together in a lab experiment. Cart 1 has a mass...
4. Two carts collide and stick together in a lab experiment. Cart 1 has a mass of 550 g and a speed before the collision of 2.5 m/s. Cart 2 has a mass of 320 g and a speed of -4.1 m/s. Consider the 2 carts to be the system. A. What is the total momentum of the system before the collision? B. What is the velocity of the 2 carts after the collision? C. If the collision takes 0.15s,...
4. Energy and Momentum for 15 points: A 200 gram lab cart is initially at rest...
4. Energy and Momentum for 15 points: A 200 gram lab cart is initially at rest on top of a 50 cm ramp, as shown. Note that the wheels are very light and the axle has no friction in it. You push the cart as it moves through a distance of 20 cm with a constant force of 10N in a direction oriented 20 degrees below horizontal. After you stop pushing on the cart, it encounters a ramp, and rolls...
what is the percent error? In the Collisions lab, say you are doing case 2 (elastic)...
what is the percent error?
In the Collisions lab, say you are doing case 2 (elastic) and your obtained values were Mass of cart A Mass of cart B Initial velocity of cart A (VA) Final velocity of cart A (VAS) Initial velocity of cart B (VB) Final velocity of cart B (VB.) 156.8 g 160.2 g 22 cm/s 56 cm/s 42 cm/s 34 cm/s 12% 81% 40% 113% 59%
Assume momentum is conserved in this case. Cart A of unknown mass is moving on a...
Assume momentum is conserved in this case. Cart A of unknown mass is moving on a friction balanced track with a speed 0.422m/s. It then collides with cart B of mass 0.42kg which is at rest, becoming stuck together with a speed 0.24m/s. What is the mass of cart A in (kg) after collision?
Mass of Cart 1: 0.263 kg Mass of Cart 2:0.273 kg Run # Velocity Cart 2...
Mass of Cart 1: 0.263 kg Mass of Cart 2:0.273 kg Run # Velocity Cart 2 before collision (m/s) Bumper Type Magnetic Magnetic Hook-n-pile Hook-n-pile Both Both Velocity Cart 1 before collision (m/s) 0.3940 0.2142 0.4397 0.3251 0.4282 0.3483 1 2 3 4 5 6 Velocity Cart 1 before collision (m/s) -0.01857 0.000335 0.2053 0.1548 0.07012 0.06005 Velocity Cart 2 after collision (m/s) 0.3728 0.2043 0.2010 0.1557 0.2982 0.2527 0 Run # Momentum Momentum Momentum Momentum 1 before 2 before...
Problem 4 In a lab experiment, a cart of mass 2 kg, moving initially to the right at 3 m/s, collides head-on with a cart of unknown mass, moving initially to the left at 2 m/s. As a result of the collision, the carts bounce back with exactly the opposite velocity of what they had going in. Assume the system is effectively isolated (a)What is the mass of the second cart? (b)What is the total momentum of the system? (c)What...
You have two carts labeled A and B as shown in the figure above. Cart A is twice the mass of cart B and is moving with a velocity of 5 m/s towards cart B. Cart Bis stationary. The magnitude of the total linear momentum of the system before the collision is 50 kg m/s. After the collision, both the carts stick and move together. What is the magnitude of the final velocity of the system? VA=5 m/s Vp=0 А...
4. Energy and Momentum for 15 points: A 200 gram lab cart is initially at rest on top of a 50 cm ramp, as shown. Note that the wheels are very light and the axle has no friction in it. You push the cart as it moves through a distance of 20 cm with a constant force of 10N in a direction oriented 20 degrees below horizontal. After you stop pushing on the cart, it encounters a ramp, and rolls...
what is the percent error?
In the Collisions lab, say you are doing case 2 (elastic) and your obtained values were Mass of cart A Mass of cart B Initial velocity of cart A (VA) Final velocity of cart A (VAS) Initial velocity of cart B (VB) Final velocity of cart B (VB.) 156.8 g 160.2 g 22 cm/s 56 cm/s 42 cm/s 34 cm/s 12% 81% 40% 113% 59%
Mass of Cart 1: 0.263 kg Mass of Cart 2:0.273 kg Run # Velocity Cart 2 before collision (m/s) Bumper Type Magnetic Magnetic Hook-n-pile Hook-n-pile Both Both Velocity Cart 1 before collision (m/s) 0.3940 0.2142 0.4397 0.3251 0.4282 0.3483 1 2 3 4 5 6 Velocity Cart 1 before collision (m/s) -0.01857 0.000335 0.2053 0.1548 0.07012 0.06005 Velocity Cart 2 after collision (m/s) 0.3728 0.2043 0.2010 0.1557 0.2982 0.2527 0 Run # Momentum Momentum Momentum Momentum 1 before 2 before...
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