物理代写|Physics6561 Electrodynamics

For convenience we place the cube with one corner at the origin and the cube in the positive quadrant. Then the vectors of the two body diagonals are $\vec{b}_1=(1,1,1)$ and $\vec{b}_2=(-1,1,1)$. The angle between the two vectors is found from the definition of the dot product,
$$
\vec{b}_1 \cdot \vec{b}_2=\left|\vec{b}_1\right|\left|\overrightarrow{b_2}\right| \cos (\theta) \text { so that } 1=3 \cos (\theta)
$$

The two vectors $\vec{v}_1=(0,2,0)-(1,0,0)=(-1,2,0)$ and $\vec{v}_2=(0,0,3)-(1,0,0)=(-1,0,3)$ define the plane of the surface of interest. The cross product of these two vectors, $\vec{v}_1 \wedge \vec{v}_2=(6,-3,2)$, is normal to the plane of interest. The unit normal of interest is then $(6 / 7,-3 / 7,2 / 7)$.

In these calculations we can usually just look at one component and then note that the other components have a similar behavior, with the appropriate change of variables. a) The gradient operator is $\vec{\nabla}=$ $\hat{x} \partial_x+\hat{y} \partial_y+\hat{z} \partial_z$ and $r^2=x^2+y^2+z^2$. Since $\partial_x\left(r^2\right)=2 x$, with similar expressions for the other components, it is clear that $\vec{\nabla}\left(r^2\right)=2 \vec{r}=2 r \hat{r}$.
b) We have,
$$
\vec{\nabla}\left(\frac{1}{r}\right)=\left(\hat{x} \partial_x+\hat{y} \partial_y+\hat{z} \partial_z\right)\left(\frac{1}{\left(x^2+y^2+z^2\right)^{1 / 2}}\right)
$$
Since $\partial_x(1 / r)=-x / r^3$, it is clear that $\vec{\nabla}\left(\frac{1}{r}\right)=-\vec{r} / r^3=-\hat{r} / r^2$. c) Using a similar procedure to that used in b) it can be shown that $\vec{\nabla} r^n=n r^{n-1} \hat{r}$

In these proofs we can do the calculation for one component and then extend to the other components. For the first quotient formula we have,
$$
\vec{\nabla}\left(\frac{f}{g}\right)=\hat{x} \partial_x\left(\frac{f}{g}\right)+\hat{y} \partial_y\left(\frac{f}{g}\right)+\hat{z} \partial_z\left(\frac{f}{g}\right)
$$
For the first component we have,
$$
\frac{\partial}{\partial x}\left(\frac{f}{g}\right)=\frac{g \frac{\partial f}{\partial x}-f \frac{\partial g}{\partial x}}{g^2}=\left(\frac{1}{g} \vec{\nabla} f-\frac{f}{g^2} \vec{\nabla} g\right)_x
$$
The other components proceed in the same way, completing the proof. The second quotient formula is
$$
\vec{\nabla} \cdot\left(\frac{\vec{A}}{g}\right)=\partial_x\left(\frac{A_x}{g}\right)+\partial_y\left(\frac{A_y}{g}\right)+\partial_z\left(\frac{A_z}{g}\right)
$$
The first term gives,
$$
\frac{\partial}{\partial x}\left(\frac{A_x}{g}\right)=\frac{g \frac{\partial A_x}{\partial x}-A_x \frac{\partial g}{\partial x}}{g^2}
$$
Similar terms occur for the second term, using $x \rightarrow y$, and third term, using $x \rightarrow z$. It is then evident that this is equivalent to $\vec{\nabla} \cdot \vec{A} / g-\vec{A} \cdot(\vec{\nabla} g) / g^2$ as required. The third quotient rule considers,
$$
\vec{\nabla} \wedge\left(\frac{\vec{A}}{g}\right)=\left|\begin{array}{ccc}
\hat{x} & \hat{y} & \hat{z} \
A_x & A_y & A_z \
B_x & B_y & B_z
\end{array}\right|=\hat{x}\left(\partial_y\left(\frac{A_z}{g}\right)-\partial_z\left(\frac{A_y}{g}\right)\right)-\hat{y}\left(\partial_x\left(\frac{A_z}{g}\right)-\partial_z\left(\frac{A_x}{g}\right)\right)+\hat{z}\left(\partial_x\left(\frac{A_y}{g}\right)-\partial_y\left(\frac{A_x}{g}\right)\right)
$$
The $\mathrm{x}$-component of this expression gives,
$$
\frac{g \frac{\partial A_z}{\partial y}-A_z \frac{\partial g}{\partial y}}{g^2}-\frac{g \frac{\partial A_y}{\partial z}-A_y \frac{\partial g}{\partial z}}{g^2}=\left(\frac{1}{g}(\vec{\nabla} \wedge \vec{A})+\frac{1}{g^2} \vec{A} \wedge(\vec{\nabla} g)\right)_x
$$
The other components follow in the same way.