Kinetic Energy - Change Calculation

In summary, the conversation discusses the relationship between energy, force, and motion in a moving object, specifically a mass with a rocket attached to it. It is concluded that the force and energy applied by the rocket are not affected by the object's initial velocity, but rather by the speed at which the rocket's exhaust is expelled. Additionally, it is noted that work and impulse are different ways of measuring the impact of the rocket's motion on the object. Ultimately, the concepts of work and energy are relative and depend on the observer's perspective.
  • #1
tardis
10
0
Is the energy required to accelerate mass m 1 meter/sec2 for 1 second, the same whether that mass is:
a) currently traveling at 3 meters per sec or
b) 300 meters per sec?
 
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  • #2
I suggest you put some numbers in and find out.

~H
 
  • #3
No. Since kinetic energy is proportional to [tex]v^2[/tex], a change of +1 m/s at 300 m/s will result in a 300.5J KE increase, whereas at 3 m/s it will only result in a 3.5J increase.
 
  • #4
Thanks that is consistent with the calculations. I'm having trouble understanding work and impulse. Specifically, consider a mass with a rocket on it - the rocket burns for 1 second regardless of how fast the mass is currently moving, and the total chemical potential energy in the rocket doesn't change when it's moving.

Is the force the rocket applies to the mass the same when the mass is stationary and when it's moving? If so, isn't it applying the same force over a larger distance and thus doing more work with the same amount of energy (clearly a contradiction)? If not, does that mean there is some "absolute" reference frame relative to which the mass's motion is measured?
 
  • #5
The rocket can't be creating thrust (thus, no force) if its not using some of the chemical potential energy.
 
  • #6
Tardis:

Work is Force x Distance, which you can translate into "Kinetic Energy". It's a way of thinking about "stopping distance". A rocket going twice as fast takes twice as much fuel to stop, and while it's stopping, it goes four times as far.

Impulse is Force x Time, which you can translate into Momentum. It's a way of thinking about "stopping time". A rocket going twice as fast takes twice as much fuel to stop, and stops in twice the time.

Both are just different ways of looking at a moving object. Think about the situation where the rocket kicks out its exhaust at 300m/s. At the start of the burn an outside observer sees the exhaust moving at 300m/s, and the rocket hardly moving at all. Hence most of the "work" is going into the exhaust. Later when the rocket reaches 300m/s, none of the "work" goes into the exhaust, because the observer notes that the exhaust is now moving at 0m/s. But inside the rocket you see a constant fuel consumption, acceleration, and "work" rate.

The observer is treating work as stopping distance. You're thinking of work as stopping time. And the bottom line is that work and energy here are just concepts to do with relative motion, and aren't real.
 
  • #7
Thank you Farsight. That is very helpful.
 

1. What is kinetic energy and how is it calculated?

Kinetic energy is the energy an object possesses due to its motion. The formula for calculating kinetic energy is KE = 1/2 * m * v^2, where m is the mass of the object and v is its velocity.

2. How does kinetic energy change when an object's mass changes?

Kinetic energy is directly proportional to an object's mass, meaning that as the mass increases, so does the kinetic energy. This is because a heavier object requires more energy to achieve the same velocity as a lighter object.

3. How does kinetic energy change when an object's velocity changes?

Kinetic energy is directly proportional to an object's velocity squared, meaning that as the velocity increases, the kinetic energy increases exponentially. This is because the energy required to move an object increases as its speed increases.

4. Can the kinetic energy of an object ever be negative?

No, kinetic energy is always a positive value. This is because it is a measure of an object's motion, and motion cannot have a negative value.

5. How is kinetic energy affected by friction and other external forces?

Friction and other external forces can decrease an object's kinetic energy by doing work against the object's motion. This means that the object will lose some of its kinetic energy and its velocity will decrease. However, the total energy of the system will remain constant due to the law of conservation of energy.

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