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\sect{Radiation from 1D blackbody fiber}

Consider an optical fiber that has a length ${L}$. Its section area is ${A}$. 
The fiber is in thermal equilibrium at temperature ${T}$.
Assume the fiber is a one dimensional medium for the electromagnetic
field. Regard the system as a 1D photon gas.

\begin {itemize}

\item[(a)]
What is the electromagnetic energy density per unit length?

\item[(b)]
What is the radiation pressure on the fiber edges?

\item[(c)]
Assuming that the radiation is freely emitted from the boundary of the fiber,
find the energy flow per unit time.

\item[(d)]
What is the spectral distribution ${J(\omega)}$ of the emitted radiation?

\item[(e)]
What is the entropy and what is the heat capacity of the system?

\end {itemize}

You can use the following integral 
\[\int_{0}^{\infty}\frac{x}{e^{x}-1}dx=\frac{\pi^{2}}{6}\]