Percent Length Contraction (check solution)

AI Thread Summary
The discussion centers on calculating the percent length contraction of an aircraft traveling at Mach 2, equivalent to 680.58 m/s. The formula used is L'/L = √(1 - (v/c)²), where c is the speed of light at 300,000,000 m/s. Participants clarify that the resulting contraction is minimal due to the aircraft's speed being significantly lower than the speed of light, leading to a contraction percentage that approaches 1%. The importance of precise calculations and avoiding premature rounding is emphasized, as this affects the accuracy of the contraction result. Overall, the percent length contraction is confirmed to be very small, consistent with relativistic effects at such speeds.
Quelsita
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Question:
What is the percent length contraction of an aircraft traveling at Mach 2?

So, we know that Mach 2= 680.58 m/s
and that L'=L\sqrt{1-(v/c)^2}

If you divide over the L to get:

L'/L=\sqrt{1-(v/c)^2}=% length contraction

Plug-n-chug from here to get:

L'/L=\sqrt{1-(680.58/c)^2}
=\sqrt{1-(5.15X10^-12)}
=\sqrt{1}
=1

Is this correct? It only contracts 1%?
 
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I'd recheck your calculation and be careful in taking your square root.

680/300,000 is what you were intending I trust?
 
LowlyPion said:
680/300,000 is what you were intending I trust?

Yep. That's why I thought it was off because it's such a small number that you'll have 1 under the radical...

Or is the percent contraction supposed to be very small since the aircraft, compared to the speed of light, is going extremely slow?
 
Yes it is a small number.

And when you take the square root it gets closer to 1.

Use a calculator, and don't approximate or round until you have an expression for the percentage.
 
LowlyPion said:
I'd recheck your calculation and be careful in taking your square root.

680/300,000 is what you were intending I trust?

c = 300,000,000 m/s
 
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