Linear Momentum and Collisions of meteor

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SUMMARY

A meteor with a mass of 108 kg collided with Earth, which has a mass of 6.0 x 1024 kg, at a speed of 11 km/s, resulting in a completely inelastic collision where the meteor came to rest within the Earth. The Earth's recoil speed can be calculated using the conservation of momentum formula, leading to a specific value for v'. The kinetic energy transformation indicates that a fraction of the meteor's kinetic energy is transferred to the Earth, which can be quantified in terms of joules. The discussion emphasizes the principles of conservation of momentum and energy in analyzing such collisions.

PREREQUISITES
  • Understanding of conservation of momentum principles
  • Knowledge of completely inelastic collisions
  • Familiarity with kinetic energy calculations
  • Basic algebra for solving equations
NEXT STEPS
  • Calculate the Earth's recoil speed using the formula Mav = (Ma + Me)v'
  • Determine the fraction of kinetic energy transferred to Earth post-collision
  • Analyze the change in Earth's kinetic energy as a result of the collision
  • Explore additional examples of completely inelastic collisions in physics
USEFUL FOR

Physics students, educators, and anyone interested in understanding the dynamics of collisions and energy transformations in astrophysical contexts.

wildr0id
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A meteor whose mass was about 10^8 kg struck the Earth (m = 6.0 X10^24 kg) with a speed of about 11 km/s and came to rest in the Earth.
(a) What was the Earth's recoil speed? (m/s)

(b) What fraction of the meteor's kinetic energy was transformed to kinetic energy of the Earth? (%)

(c) By how much did the Earth's kinetic energy change as a result of this collision? (J)

I know this problem requires a look at conservation of momentum and conservation of energy principles, but I am having trouble just trying to start this problem out
 
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You know that u need to apply the law of conservation of momentum.Well,then do it...I'm afraid you're dealing with a plastic collision for which the KE is not really conserved...

Daniel.
 
This is a "completely inelastic" collision- Kinetic energy is not conserved so you cannot use that.

You do, however, know that the Earth has 0 velocity initially and that both the Earth and the asteroid have the same velocity after.

Mava+ Meve= Mav'a+ Mev'e ("e" subscripts are "earth", "a" subscripts are "asteroid". v' is after the collision.) becomes Mav= (Ma+ Me)v'.

You know Ma, Me, and v. Solve for v'. Once you know that you can calculate the kinetic energy of the asteroid and Earth after the collision and compare it with those values before the collision.
 

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