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mmmboh
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Hi, so I did the question, but apparently my answer is off by a factor of 2.
An accelerated electron radiates energy at the rate Ke2a2/c3...e is the electron charge, a is the instantaneous acceleration, c is the speed of light, K=6x109Nm2/C2...whatever that is.
So first I had to find how much energy an electron oscillating in a straight line would radiate over one cycle, the motion is describe by x=Asin(2\pift), I did that and according to the answer book I am right, it is Ke28A2pi4f3/c3.
For the next part I have to find the quality factor...I know that is 2\pi x energy stored/energy dissipated per cycle, and the energy stored is 1/2 kA2, and since k=w0m the energy stored becomes (1/2)4pi2f2mA2...when I do that times 2\pi, and then divide that by the energy dissipated over one cycle that I found in the first part, I get as an answer mc3/(2Ke2pif)...but according to the answer book the denominator should be multiplied by a factor of 4, not two...
Am I missing something here? I can't figure out where my mistake is..
An accelerated electron radiates energy at the rate Ke2a2/c3...e is the electron charge, a is the instantaneous acceleration, c is the speed of light, K=6x109Nm2/C2...whatever that is.
So first I had to find how much energy an electron oscillating in a straight line would radiate over one cycle, the motion is describe by x=Asin(2\pift), I did that and according to the answer book I am right, it is Ke28A2pi4f3/c3.
For the next part I have to find the quality factor...I know that is 2\pi x energy stored/energy dissipated per cycle, and the energy stored is 1/2 kA2, and since k=w0m the energy stored becomes (1/2)4pi2f2mA2...when I do that times 2\pi, and then divide that by the energy dissipated over one cycle that I found in the first part, I get as an answer mc3/(2Ke2pif)...but according to the answer book the denominator should be multiplied by a factor of 4, not two...
Am I missing something here? I can't figure out where my mistake is..
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