Radiation MCQ Questions & Answers in Heat and Thermodynamics | Physics

$$\eqalign{ & {\text{According to Stefan's law}} \cr & E = \sigma {T^4} \cr & \sigma = {\text{Stefans constant}} \cr & T = {\text{temperature}} \cr & \frac{{{E_1}}}{{{E_2}}} = {\left[ {\frac{{{T_1}}}{{{T_2}}}} \right]^4} \Rightarrow {E_2} = 7{\left[ {\frac{{273 + 727}}{{273 + 227}}} \right]^4} = {\left[ {\frac{{1000}}{{500}}} \right]^4} \times 7 \cr & = 112\,cal - c{m^2}{s^{ - 1}} \cr} $$

By the law of conservation of energy, energy given by heater must be equal to the sum of energy gained by water and energy lost from the lid.
$$\eqalign{ & Pt = ms\Delta \theta + {\text{energy}}\,{\text{lost}} \cr & 2000t = 3 \times 4.2 \times {10^3} \times \left( {97 - 27} \right) + 130t \cr & \Rightarrow t = 472\sec \cr} $$

For $$\theta - t$$  plot, rate of cooling $$ = \frac{{dQ}}{{dt}} = $$   slope of the curve.
$$\eqalign{ & AT\,P,\frac{{dQ}}{{dt}} = \left| {\tan \left( {{{180}^ \circ } - {\phi _2}} \right)} \right| \cr & = \tan {\phi _2} = k\left( {{\theta _2} - {\theta _1}} \right) \cr} $$
where $$k$$ = constant.
At $$Q,$$
$$\eqalign{ & \frac{{dQ}}{{dt}} = \left| {\tan \left( {{{180}^ \circ } - {\varphi _1}} \right)} \right| = \tan {\varphi _1} = k\left( {{\theta _1} - {\theta _0}} \right) \cr & \therefore \frac{{\tan {\phi _2}}}{{\tan {\phi _1}}} = \frac{{{\theta _2} - {\theta _0}}}{{{\theta _1} - {\theta _0}}} \cr} $$

Pyrometer is used to detect infra-red radiation.

Wien’s displacement law is given by
$${\lambda _m}T = $$  constant
$${\lambda _m} = $$  Maximum wavelength radiation
$$T =$$  temperature of the body
So for two different cases, i.e. at two different temperatures
or $${\lambda _1}{T_1} = {\lambda _2}{T_2}$$
$${\lambda _2} = {\lambda _1}\left( {\frac{{{T_1}}}{{{T_2}}}} \right)$$
Given, $${T_1} = 2000\,K,{T_2} = 3000\,K,{\lambda _1} = \lambda $$
$$\therefore {\lambda _2} = \lambda \times \frac{{2000}}{{3000}} = \frac{2}{3}\lambda $$

According to Newton’s law of cooling, the temperature goes on decreasing with time non-linearly.

According to Kirchoff's law, good absorbers are good emitters as well.
At high temperature (in the furnace), since it absorbs more energy, it emits more radiations as well and hence is the brightest.