Question

A light of wavelength $3540\mathring{A}$ falls on a metal having work function of $2.5eV$. The ejected electron collides with another target metal inelastically and its total kinetic energy is utilized to raise the temperature of target metal. The mass of target metal is $10^{-3}kg$ and its specific heat is $160Jk{g}^{-1}{}^{\circ }{C}^{-1}$. If $10^{18}$ electrons are ejected per second, then find the rate of raise of temperature $($ in ${}^{\circ }C/s)$ of the metal. (Assume there is no loss of energy of ejected electron by any other process, all the electron are reaching the target metal with maximum kinetic energy and $hc=12400eV\mathring{A}$ )

Answer 1

Answer: 1

Energy of photon $=\frac{hc}{\lambda }=\frac{12400}{3540}eV\approx 3.5eV$
Thus, $K{E}_{\max }$ of ejected electron $=1eV$
Thus, energy lost per electron
$=1eV=1\times 1.6\times 10^{-19}J$
Total energy gained by target metal per second
$=1.6\times 10^{-19}\times 10^{18}J=0.16J$
Thus, $0.16=ms\frac{dT}{dt}$
$\Rightarrow \cdot \frac{dT}{dt}={\frac{0.16}{10^{-3}\times 160}}^{\circ }C/s$