Calculating Speed in Special Relativity: A Grade 12 Physics Problem

AI Thread Summary
The discussion revolves around a Grade 12 physics problem involving special relativity and time dilation. Ludwig von Drake measures the half-life of a radioactive material, while Donald Duck, on a bomb moving at speed v, finds the half-life to be half of Drake's measurement. The key equation used is the time dilation formula, t = t0 / sqrt(1 - v²/c²), where t is Drake's time and t0 is Donald's proper time. By setting up equations based on their measurements and solving, the value of v is determined to be approximately 0.87c. The solution highlights the importance of understanding inertial frames of reference in special relativity.
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Thanks for taking a look. The following question is that is that from a grade 12 academic physics course.

Homework Statement



Scientist Ludwig von Drake, while in his laboratory, measures the half-life of some radioactive material which is in a bomb, approaching with speed v. Donald Duck, who is riding on the bomb, also measures the half-life. His answer is a factor of 2 smaller than Ludwig's. What is the value of v, expressed as a fraction of c?

Answer: .87

Homework Equations



Special relativity equation: t=t0/square root (1-v2/c2) Note: 2 = squared
Other: I know there is at least one more I must use but for the life of me don't know what it is.

The Attempt at a Solution



First we set V=Drakes. If this is so than Donald's equation must be equal to:

t=[t0/square root (1-v2/c2)]/2

Therefore to= 2t[square root (1-v2/c2)]

The problem is in equating the equations. They end up cancelling out because one is a direct derivative of the other. This leads me to believe I need at least 1 more equation.

It must also be noted that while von Drake may use the special equation of relativity Donald duck cannot (at least this is what I figure). I say this because Donald duck is viewing the half-life from the bomb at rest, meaning he would be more in the realm of inertial frame of reference. What equation i now use knowing that I have no idea.

Thanks in Advance guys.
 
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t=t0/square root (1-v2/c2) (this is the time dilation formula)

t is Drake's time

t0 is the proper time which is Donald's time.

we are given that t = 2t0.

so you have equations:

t=t0/square root (1-v2/c2)
t = 2t0

so solve these 2 equations.
 
Donal Duck is measuring the proper time interval t_0, so the interval measured by Drake is t=t_o\lambda. We're given that t=2t_o. Dividing both equations we get that \lambda=(1-\frac{v^2}{c^2})^{-1/2}=2. Solving the equation yields the solution.
 
Thanks guys. My solution set is similar to both of yours.

I used 2T= To/sqreroot(1-v2/c2) and 2T = To/x where x=.5

This yields sqreroot(1-v2/c2) = .5

Through squaring both sides and moving the variables/numbers around you obtain

.75c2=v2

Simply square root that to get the answer which is .866c=v

Once again thanks for your help!
 

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