Minkowsky force and physical interpretation.

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SUMMARY

The discussion centers on the calculation of the \(\mu=0\) component of the Minkowski force law, represented as \(K^\mu=q\eta_\nu F^{\mu\nu}\). The Minkowski metric \(\eta_\nu\) is defined as \(\frac{1}{\sqrt{1-u^2/c^2}}(-c,u_x,u_y,u_z)\), and the field tensor \(F^{\mu\nu}\) is specified with components including \(F^{01}=\frac{E_x}{c}\) and \(F^{02}=\frac{E_y}{c}\). The solution derived is \(K^0=\frac{q \gamma}{c}(\mathbf{u}\cdot\mathbf{E})\), indicating that \(K^0\) represents the time component of the Minkowski force, which is the projection of the electric field vector onto the velocity vector.

PREREQUISITES
  • Understanding of Minkowski spacetime and the Minkowski metric
  • Familiarity with the electromagnetic field tensor \(F^{\mu\nu}\)
  • Knowledge of special relativity principles, including four-momentum
  • Basic vector calculus, particularly dot products
NEXT STEPS
  • Study the derivation and implications of the Minkowski force law in special relativity
  • Learn about the physical interpretation of the dot product in the context of vector fields
  • Explore the relationship between four-momentum and force in relativistic physics
  • Review the role of the Lorentz factor \(\gamma\) in relativistic equations
USEFUL FOR

Students and researchers in theoretical physics, particularly those focusing on special relativity and electromagnetism, will benefit from this discussion.

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Homework Statement



Compute the \mu=0 component of the Minkowski force law K^\mu=q\eta_\nu F^{\mu\nu}. (einstein summation convention applies.)

Homework Equations



\eta_\nu=\frac{1}{\sqrt{1-u^2/c^2}}(-c,u_x,u_y,u_z)
F^{\mu\nu} is the field tensor where
F^{00}=0,F^{01}=\frac{E_x}{c},F^{02}=\frac{E_y}{c},F^{03}=\frac{E_x}{c}.

The Attempt at a Solution



K^0=q(\eta_0 F^{00} +\eta_1 F^{01} +\eta_2 F^{02} +\eta_3 F^{03}) = \frac {q \gamma}{c}(u_x E_x + u_y E_y +u_z E_z) = \frac {q \gamma}{c}(\bf{u}.\bf{E})


This all seems ok to me, but I have no idea what it actually means. What does K^0 physically represent and what does \bf{u}.\bf{E} mean.

Thank you for your help.
 
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I think Chris's answer is okay, but not nearly sufficient.

The dot product is the magnitude of the projection of one vector onto the other. In this case, we are projecting the electric field vector onto the velocity vector (or vice versa). So the time component of the Minkowski 4-force is the magnitude of the electric field vector in direction of the velocity.
 
Newton's second law

F^\mu = \frac{dp^\mu}{d\tau}

still holds in special relativity. Think about what the time component of the four-momentum is. Also, it might help to rewrite K0 slightly to get

K^0 = \frac{\gamma}{c}[\textbf{u}\cdot (q\textbf{E})]

to see what it physically means.
 

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