From S.H.O.
Functions for a point charge [math]q'[/math]
The electric scalar potential [math]\mathbf{\varphi}[/math] at [math]\left(\mathbf{r},t\right)[/math] due to a point charge [math]q'[/math] at [math]\left(\mathbf{r'},t'\right)[/math] is:
[math]\mathbf{\varphi}\left(\mathbf{r},\mathbf{r'}\right) = \underset{constant}{\frac{q'}{4\pi\ \epsilon_0}} \times \underset{proximity}{\frac{1}{|\mathbf{r}-\mathbf{r'}|}}[/math]
The magnetic vector potential [math]A[/math] at [math]\left(\mathbf{r},t\right)[/math] due to a point charge [math]q'[/math] which had a velocity [math]\frac{d\mathbf{r'}}{dt}[/math] at [math]\left(\mathbf{r'},t'\right)[/math] is:
[math]\mathbf{A}\left(\mathbf{r},\mathbf{r'}\right) = \mathbf{\varphi}\left(\mathbf{r},\mathbf{r'}\right) \times \underset{constant}{\frac{1}{c^2}} \times \underset{dislocation}{\frac{d\mathbf{r'}}{dt}}[/math]
[math]\mathbf{A}\left(\mathbf{r},\mathbf{r'}\right) = \underset{constant}{\frac{\mu_0\ q'}{4\pi}} \times \underset{proximity}{\frac{1}{|\mathbf{r}-\mathbf{r'}|}} \times \underset{dislocation}{\frac{d\mathbf{r'}}{dt}}[/math]
Functions for an ordered pair of point charges [math](q,q')[/math]
A charge [math]q[/math] subject to an electric scalar potential [math]\varphi[/math] at [math]\left(\mathbf{r},t\right)[/math] due to a point charge [math]q'[/math] at [math]\left(\mathbf{r'},t'\right)[/math] has an electric potential energy of:
- [math]q\varphi_{(q,q')}\left(\mathbf{r},\mathbf{r'}\right) = \underset{constant}{\frac{qq'}{4\pi\ \epsilon_0}} \times \underset{proximity}{\frac{1}{|\mathbf{r}-\mathbf{r'}|}}[/math]
A charge [math]q[/math] subject to a magnetic vector potential [math]A[/math] at [math]\left(\mathbf{r},t\right)[/math] due to a point charge [math]q'[/math] which had a velocity [math]\frac{d\mathbf{r'}}{dt}[/math] at [math]\left(\mathbf{r'},t'\right)[/math] has a potential momentum of:
- [math]q\mathbf{A}_{(q,q')}\left(\mathbf{r},\mathbf{r'}\right) = q\varphi_{(q,q')}\left(\mathbf{r},\mathbf{r'}\right) \times \underset{constant}{\frac{1}{c^2}} \times \underset{dislocation}{\frac{d\mathbf{r'}}{dt}}[/math]
- [math]q\mathbf{A}_{(q,q')}\left(\mathbf{r},\mathbf{r'}\right) = \underset{constant}{\frac{\mu_0\ qq'}{4\pi}} \times \underset{proximity}{\frac{1}{|\mathbf{r}-\mathbf{r'}|}} \times \underset{dislocation}{\frac{d\mathbf{r'}}{dt}}[/math]
Lorentz Force for [math](q,q')[/math]
The Lorentz Force between charges [math](q,q')[/math] can be derived from the scalar potential [math]\varphi_{(q,q')}[/math] and the vector potential [math]\mathbf{A}_{(q,q')}[/math].
A charge [math]q[/math] which has a velocity of [math]\mathbf{v}[/math] at [math]\left(\mathbf{r},t\right)[/math] will experience a Lorentz force due to a point charge [math]q'[/math] at [math]\left(\mathbf{r'},t'\right)[/math] of:
- [math]\mathbf{F}_{(q,q')} = q\left[\mathbf{E}_{(q,q')} + \mathbf{v} \times \mathbf{B}_{(q,q')}\right][/math]
The electric field [math]\mathbf{E}_{(q,q')}[/math] is:
- [math]\mathbf{E}_{(q,q')} = - \nabla \varphi_{(q,q')} - \frac{∂\mathbf{A}_{(q,q')}}{∂t}[/math]
The magnetic field [math]\mathbf{B}_{(q,q')}[/math] is:
- [math]\mathbf{B}_{(q,q')} = \nabla \times \mathbf{A}_{(q,q')}[/math]
The Lorentz Force can be expressed directly in terms of the potentials:
- [math]\mathbf{F}_{(q,q')} = q\left[- \nabla \varphi_{(q,q')} - \frac{∂\mathbf{A}_{(q,q')}}{∂t} + \mathbf{v} \times \left( \nabla \times \mathbf{A}_{(q,q')} \right)\right][/math]
See also
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HQ ● Glossary ● April 2016 Presentation