Show that the magnetic field of an infinite solenoid runs parallel to the axis, regardless of the cross-sectional shape of the coil,as long as that shape is constant along the length of the solenoid. What is the magnitude of the field, inside and outside of such a coil? Show that the toroid field (Eq. 5.60) reduces to the solenoid field, when the radius of the donut is so large that a segment can be considered essentially straight.

According to Biot-Savart’s law, write the expression of magnetic field at point at distance $r$.

$\mathbf{B}\mathbf{=}\frac{{\mathbf{\mu }}_0\mathbf{I}}{4\pi }\int \frac{\mathrm{dI}\times r}{{\mathbf{r}}^3}$ …… (1)

Here,${\mu }_0$ is the permeability for free space,$I$ is the current, $r$is the distance and$dl$ is the element.

Consider the elements $d{l}_1$and $d{l}_2$at points $P(x^{\text{'}},y^{\text{'}},z^{\text{'}})$and $P^{\text{'}}(x^{\text{'}},y^{\text{'}},-z^{\text{'}})$respectively.

The points $P$and $P^{\text{'}}$lie symmetrically with respect to x-y plane. Also assume a point$M(0,y,0)$ located on y-axis.

Write the expression for the magnetic field due to the elements.

$dB=\frac{{\mu }_{0}I}{4\pi }\left(\frac{d{I}_1\times r_1}{r_1^3}+\frac{d{I}_2\times r_2}{r_2^3}\right)$ …… (2)

Here,$r_1$and$r_2$are the position vectors of point$P$and$P\text{'}$from $M$respectively.

From the above figure,

Write the expression for position vector $r_1$.

$r_1=r_M-r_P$

Substitute $y\widehat{y}$for $r_M$and $x^{\text{'}}\widehat{x}+y^{\text{'}}\widehat{y}+z^{\text{'}}\widehat{z}$for $r_P$in above equation.

$\begin{array}{c}{r}_1=r_M-r_P\\ =y\widehat{y}-(x^{\text{'}}\widehat{x}+y^{\text{'}}\widehat{y}+z^{\text{'}}\widehat{z})\\ =-x^{\text{'}}\widehat{x}+(y-y^{\text{'}})\widehat{y}-z^{\text{'}}\widehat{z}\end{array}$

Write the magnitude of $r_1$.

$\begin{array}{c}{r}_1=\sqrt{{(-x^{\text{'}})}^2+{(y-y^{\text{'}})}^2+{(-z^{\text{'}})}^2}\\ =\sqrt{{x^{\text{'}}}^2+{(y-y^{\text{'}})}^2+{z^{\text{'}}}^2}\end{array}$

From the above figure,

Write the expression for position vector $r_2$.

$r_2=r_M-r_{P^{\text{'}}}$

Substitute$y\widehat{y}$for$r_M$and$x^{\text{'}}\widehat{x}+y^{\text{'}}\widehat{y}-z^{\text{'}}\widehat{z}$ for$r_P$in above equation.

$\begin{array}{c}{r}_2=r_M-r_{P^{\text{'}}}\\ =y\widehat{y}-(x^{\text{'}}\widehat{x}+y^{\text{'}}\widehat{y}-z^{\text{'}}\widehat{z})\\ =-x^{\text{'}}\widehat{x}+(y-y^{\text{'}})\widehat{y}+z^{\text{'}}\widehat{z}\end{array}$

Write the magnitude of $r_1$.

$\begin{array}{c}{r}_2=\sqrt{{(-x^{\text{'}})}^2+{(y-y^{\text{'}})}^2+{(-z^{\text{'}})}^2}\\ =\sqrt{{x^{\text{'}}}^2+{(y-y^{\text{'}})}^2+{z^{\text{'}}}^2}\end{array}$

Thus, the magnitude of $r_1$and$r_2$are equal.

$r_1=r_2=r$

Write the expression for$d{l}_1$and$d{l}_2$.

$\begin{array}{l}d{I}_1=d{x}^{\text{'}}\widehat{x}+d{y}^{\text{'}}\widehat{y}\\ d{I}_2=d{x}^{\text{'}}\widehat{x}+d{y}^{\text{'}}\widehat{y}\end{array}$

Thus, the two elements are equal.

$d{I}_1=d{I}_2=dI$

Substitute $dl$for $d{I}_1,d{I}_2$and $r$for$r_1$ and$r_2$ in equation (2)

$\begin{array}{c}dB=\frac{{\mu }_{0}I}{4\pi }\left(\frac{d{I}_1\times r_1}{r_1^3}+\frac{d{I}_2\times r_2}{r_2^3}\right)\\ =\frac{{\mu }_{0}I}{4\pi }\left(\frac{dI\times (r_1+r_2)}{r^2}\right)\end{array}$ …… (3)

As$d{l}_1$and$(r_1+r_2)$are in the same x-y plane, $dB\Vert d{I}_1\times (r_1+r_2)$is along with z axis which is perpendicular to x-y plane.

Substitute $(d{x}^{\text{'}}\widehat{x}+d{y}^{\text{'}}\widehat{y})$for $dl$, $-x^{\text{'}}\widehat{x}+(y-y^{\text{'}})\widehat{y}-z^{\text{'}}\widehat{z}$for $r_1$, $-x^{\text{'}}\widehat{x}+(y-y^{\text{'}})\widehat{y}+z^{\text{'}}\widehat{z}$for $r_2$,

$\sqrt{{x^{\text{'}}}^2+{(y-y^{\text{'}})}^2+{z^{\text{'}}}^2}$ for $r$in equation (3).

$\begin{array}{c}dB=\frac{{\mu }_{0}I}{4\pi }\left(\frac{dI\times (r_1+r_2)}{r^2}\right)\\ =\frac{{\mu }_{0}I}{4\pi }\left(\frac{(d{x}^{\text{'}}\widehat{x}+d{y}^{\text{'}}\widehat{y})\times (-x^{\text{'}}\widehat{x}+(y-y^{\text{'}})\widehat{y}-z^{\text{'}}\widehat{z})+(-x^{\text{'}}\widehat{x}+(y-y^{\text{'}})\widehat{y}+z^{\text{'}}\widehat{z})}{{\left(\sqrt{{x^{\text{'}}}^2+{(y-y^{\text{'}})}^2+{z^{\text{'}}}^2}\right)}^3}\right)\\ =\frac{{\mu }_{0}I}{4\pi }\left(\frac{(d{x}^{\text{'}}\widehat{x}+d{y}^{\text{'}}\widehat{y})\times (-2x^{\text{'}}\widehat{x}+2(y-y^{\text{'}}))\widehat{y}}{\left(\sqrt{{x^{\text{'}}}^2+{(y-y^{\text{'}})}^2+{z^{\text{'}}}^2}\right)}\right)\\ =\frac{{\mu }_{0}I}{4\pi }\left(\frac{2(y-y^{\text{'}})d{x}^{\text{'}}+2x^{\text{'}}d{y}^{\text{'}}}{{({\left(x^{\text{'}}\right)}^2+{(y-y^{\text{'}})}^2+{\left(z^{\text{'}}\right)}^2)}^{\frac{3}{2}}}\right)\widehat{z}\end{array}$

From above it is clear that, the filed is running parallel to the axis of solenoid that is along z axis.

Therefore, the magnetic field runs parallel to the axis of solenoid regardless of the shape, as along the shape is constant along the length of the solenoid.