Solving a Particle's Radiating Force Under Force F

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SUMMARY

The discussion focuses on deriving the radiating force of a charged particle under the influence of a force F = k x^(1/2). The key conclusion is that the power radiated by the particle at time 't' is given by the formula -dW/dt = q²k⁴t⁴ / (864)(π)(ε_0)(c³)(m⁴). The participant initially attempted to apply Newton's second law and the Larmor formula but encountered difficulties in correctly relating acceleration and position as functions of time.

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  • Understanding of classical mechanics, specifically Newton's laws of motion.
  • Familiarity with the Larmor formula for radiation from accelerating charges.
  • Knowledge of differential equations and their application in motion analysis.
  • Basic concepts of electromagnetism, including charge, mass, and constants like ε_0 and c.
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  • Study the derivation of the Larmor formula in detail.
  • Learn how to solve second-order differential equations related to motion.
  • Investigate the relationship between force, acceleration, and position in non-linear systems.
  • Explore the implications of radiation from accelerating charges in electromagnetic theory.
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Students and professionals in physics, particularly those studying electromagnetism and classical mechanics, as well as researchers interested in particle dynamics and radiation theory.

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Homework Statement



At time t = 0 a particle of charge 'q' and mass 'm' is at a position x = 0 and has a velocity v = 0. The particle is subject to a force F = k x^(1/2) , where 'k' is a constant. Show that at time 't' the particle radiates according to:

-dW/dt = q²k⁴t⁴ / (864)(π)(ε_0 )(c³)(m⁴)




The Attempt at a Solution



I first said F= ma = k x^1/2

--> a = k x^(1/2) / m

---> a² = k² x / m²


Then I substitute this into the larmor formula, but obviously this is wrong. I'm not sure where I went wrong though.

Thanks.
 
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hhhmortal said:
---> a² = k² x / m²


Then I substitute this into the larmor formula, but obviously this is wrong. I'm not sure where I went wrong though.

What makes you so certain that this is wrong? Remember, the particle is accelerating along the x-direction, so its x-coordinate will be a function of time. You can find the exact form of [itex]x(t)[/itex] by solving the differential equation [itex]\frac{d^2 x}{dt^2}=a[/itex].
 

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