How Does the Kinetic Energy Theorem Apply to Bonny Blair's Skating Problem?

AI Thread Summary
The discussion focuses on applying the kinetic energy theorem to Bonny Blair's skating scenario, where she skates a distance of 500 meters at an average speed of 12.92 m/s before slowing to 8.00 m/s. The kinetic energy theorem states that the change in kinetic energy equals the work done on her, specifically by friction in this case. Participants are encouraged to calculate the change in kinetic energy to determine the work done by friction, using the formula ΔK = W. The conversation suggests considering quasar's method for a potentially simpler solution. Understanding these principles is essential for solving the problem accurately.
Femme06Fatale
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Bonny Blair skated 5.00 x 10^2 m with an average speed of 12.92 m/s. Suppose she corssed the finish line at this speed and then skated freely until her speed was 8.00 m/s. If her was mwas 55.0 kg, how much work was done by friction?

Can anybody explain the kinetic energy theorem or help me work through this problem?
 
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The kinetic energy theorem says her variation in kinetic energy is equal to the work done on her.

If you can find by how many Joules her kinetic energy varied, then this same number is equal to the work done on her:

\Delta K = W
 
W_{friction}=F_{friction}d\cos{\theta}

F_{net}=ma

Can you figure it out using those (careful what you use for d)?
 
Oh, yes, quasar's method may be easier.
 

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