Work-Energy Theorem: Find Final Speed of Ship

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To find the final speed of a spaceship using the work-energy theorem, first calculate the work done by the engine, which is the product of the force (4.00 x 10^5 N) and the distance traveled (2.50 x 10^6 m), resulting in 1.00 x 10^12 J. This work represents the change in kinetic energy of the ship. By setting the work equal to the change in kinetic energy formula, 1/2mv^2 - 1/2mv(o)^2, and substituting the known values, the final speed can be solved. The initial speed is 1.15 x 10^4 m/s, and solving the equation will yield the correct final speed of the ship. This approach effectively applies the work-energy theorem to determine the final velocity.
PhysicsDud
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I'm having trouble with where to begin with this question, if anyone has guidance I'd be grateful.

A spaceship of mass 5.00 x 10^4 kg is traveling at a speed 1.15 x 10^4m/s in outer space. Except for the force generated by its own engine, no other force acts on the ship. As the engine exerts a constant force of 4.00 x 10^5 N, the ship moves a distance of 2.50 x 10^6 m in the direction of the force of the engine.
a) Determine the final speed of the ship using the work-energy Theorem.
 
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The work is just a name people gave to "change in kinetic energy". If you find the work "done by the engine" in the ship going a distance of 2.50 x 10^6 m, then you've found the change in kinectic energy of the ship. And work in one dimension is simply

W =Fd[/itex]<br /> <br /> where d is the distance traveled and F the force applied during this travel.
 
Thanks, so If I solve for W, I get 1.00 x 10^12, then I make this answer equal to 1/2mv^2 - 1/2mv(o)^2, and plug in everything I have and solve for v, this should give me the correct answer?
 
Correct-o-mundo!

Edit: except for the answer to W!
 
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