a black body at 227 pow circ c radiates heat at the rate of

A black body at $${227^ \circ }C$$ radiates heat at the rate of $$7cal\,c{m^{ - 2}}{s^{ - 1}}.$$ At a temperature of $${727^ \circ }C,$$ the rate of heat radiated in the same units will be

A. 60

B. 50

C. 112

D. 80

Answer : 112

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

Releted MCQ Question on
Heat and Thermodynamics >> Radiation

Releted Question 1

Two metallic spheres $${S_1}$$ and $${S_2}$$ are made of the same material and have got identical surface finish. The mass of $${S_1}$$ is thrice that of $${S_2}.$$ Both the spheres are heated to the same high temperature and placed in the same room having lower temperature but are thermally insulated from each other. The ratio of the initial rate of cooling of $${S_1}$$ to that of $${S_2}$$ is

A. $$\frac{1}{3}$$

B. $${\frac{1}{{\sqrt 3 }}}$$

C. $${\frac{{\sqrt 3 }}{1}}$$

D. $${\left( {\frac{1}{3}} \right)^{\frac{1}{3}}}$$

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Releted Question 2

A spherical black body with a radius of $$12\,cm$$ radiates 450 $$W$$ power at 500 $$K.$$ if the radius were halved and the temperature doubled, the power radiated in watt would be

A. 225

B. 450

C. 900

D. 1800

View Answer

Releted Question 3

A spherical black body with a radius of $$12\,cm$$ radiates $$450\,W$$ power at 500 $$K.$$ If the radius were halved and the temperature doubled, the power radiated in watt would be

A. 225

B. 450

C. 900

D. 1800

View Answer

Releted Question 4

The plots of intensity versus wavelength for three black bodies at temperature $${T_1},$$ $${T_2}$$ and $${T_3}$$ respectively are as shown. Their temperatures are such that

A. $${T_1} > {T_2} > {T_3}$$

B. $${T_1} > {T_3} > {T_2}$$

C. $${T_2} > {T_3} > {T_1}$$

D. $${T_3} > {T_2} > {T_1}$$

View Answer

A black body at $${227^ \circ }C$$ radiates heat at the rate of $$7cal\,c{m^{ - 2}}{s^{ - 1}}.$$ At a temperature of $${727^ \circ }C,$$ the rate of heat radiated in the same units will be

Releted MCQ Question on
Heat and Thermodynamics >> Radiation

A spherical black body with a radius of $$12\,cm$$ radiates 450 $$W$$ power at 500 $$K.$$ if the radius were halved and the temperature doubled, the power radiated in watt would be

A spherical black body with a radius of $$12\,cm$$ radiates $$450\,W$$ power at 500 $$K.$$ If the radius were halved and the temperature doubled, the power radiated in watt would be

The plots of intensity versus wavelength for three black bodies at temperature $${T_1},$$ $${T_2}$$ and $${T_3}$$ respectively are as shown. Their temperatures are such that

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Radiation

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A black body at $${227^ \circ }C$$ radiates heat at the rate of $$7cal\,c{m^{ - 2}}{s^{ - 1}}.$$ At a temperature of $${727^ \circ }C,$$ the rate of heat radiated in the same units will be

Releted MCQ Question on Heat and Thermodynamics >> Radiation

A spherical black body with a radius of $$12\,cm$$ radiates 450 $$W$$ power at 500 $$K.$$ if the radius were halved and the temperature doubled, the power radiated in watt would be

A spherical black body with a radius of $$12\,cm$$ radiates $$450\,W$$ power at 500 $$K.$$ If the radius were halved and the temperature doubled, the power radiated in watt would be

The plots of intensity versus wavelength for three black bodies at temperature $${T_1},$$ $${T_2}$$ and $${T_3}$$ respectively are as shown. Their temperatures are such that

Practice More Releted MCQ Question on Radiation

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Heat and Thermodynamics >> Radiation

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Radiation