Physics, 27.08.2021 01:40, rudybelizaire

1) Momentum conservation in 1D: two asteroids collide head-on and stick together. Before the collision, asteroid A (mass = 1,000kg) was moving at a speed of 100m/s, and asteroid B (mass = 2,000kg) was moving at a speed of 80m/s in the opposite direction. Use momentum conservation to find the velocity of the asteroids after the collision. Make a complete momentum chart to help you solve the problem. Note, that you do not need to complete the entire chart to find the final velocity. (That is, you don't need to find the change in momentum of each asteroid separately. Still, finding the individual changes is a good opportunity to check your understanding of momentum conservation.) 2) Momentum conservation in 2D: two asteroids identical to the ones described in 1) collide at right angles and stick together. Let us choose asteroid A to be initially moving to the right (defined as ta direction), and B to be initially moving upward (defined as ty direction). Use momentum conservation to find the velocity of the asteroids after the collision. To express velocity, your answer should have magnitude and direction given as an angle in the x-y plane. Make a complete momentum chart to help you solve the problem.
3) Is the total kinetic energy of the two asteroids in the previous two problems conserved when they collide? Why or why not? Write down an energy conservation equation for the two asteroids, including all the energies that change before and after the collision. Assuming that the asteroids started at the same temperature and that their average specific heat is that of ice (2.05kJ/kg°C), by how much does the temperature of the combined asteroids rise as a result of each of the two collisions described above?

Answers: 3

Show answers

Other questions on the subject: Physics

Physics, 22.06.2019 00:30, powberier6979

Consider an ordinary, helium-filled party balloon with a volume of 2.2 ft3. the lifting force on the balloon due to the outside air is the net resultant of the pressure distribution exerted on the exterior surface of the balloon. using this fact, we can derive archimedes’ principle, namely that the upward force on the balloon is equal to the weight of the air displaced by the balloon. assuming that the balloon is at sea level, where the air density is 0.002377 slug/ft3, calculate the maximum weight that can be lifted by the balloon. note: the molecular weight of air is 28.8 and that of helium is 4.

Answers: 2

continue

Physics, 22.06.2019 03:30, munchyswish

Astudent is working in the lab to determine how time affect impulse the student keeps the force the same in each row but changes impact the time some data is shown witch trial has the greatest a student is working in the lab to determine how time affect impulse the student keeps the fours the same in each row but change is the impact time some data shown witch trial has the greatest impulse

Answers: 3

continue

Physics, 22.06.2019 10:50, dontcareanyonemo

The temperature at a point (x, y) is t(x, y), measured in degrees celsius. a bug crawls so that its position after t seconds is given by x = 6 + t , y = 8 + 1 3 t, where x and y are measured in centimeters. the temperature function satisfies tx(3, 9) = 5 and ty(3, 9) = 4. how fast is the temperature rising on the bug's path after 3 seconds? (round your answer to two decimal places.)

Answers: 3

continue

Physics, 22.06.2019 15:30, tiffuuu

At 20∘c, the hole in an aluminum ring is 2.800 cm in diameter. you need to slip this ring over a steel shaft that has a room-temperature diameter of 2.804 cm . 1. to what common temperature should the ring and the shaft be heated so that the ring will just fit onto the shaft? coefficients of linear thermal expansion of steel and aluminum are 12×10−6 k−1 and23×10−6 k−1 respectively.

Answers: 1

continue

Do you know the correct answer?

1) Momentum conservation in 1D: two asteroids collide head-on and stick together. Before the collisi...