Inside a closed furnace held at a temperature of 400,, K, we have a black body. A hole of area 10,, cm^2 is opened in

Q: Inside a closed furnace held at a temperature of $400\,\, K,$ we have a black body. A hole of area $10\,\, cm^2$ is opened in the furnace so that sunlight starts falling on black body. The intensity of sunlight is $2000\, W/m^2.$ In the steady state

b $\frac{\mathrm{d} \mathrm{H}}{\mathrm{dt}}=\mathrm{A} \sigma \mathrm{T}^{4}$ $\frac{d H}{d t A}=5.67 \times 10^{-8} \times(400)^{4}$ $=5.67 \times 64 \times 64>2000 \mathrm{W} / \mathrm{m}^{2}$

SECTION - A [PHYSICS - MCQ]

GSEB - English Medium

Inside a closed furnace held at a temperature of $400\,\, K,$ we have a black body. A hole of area $10\,\, cm^2$ is opened in the furnace so that sunlight starts falling on black body. The intensity of sunlight is $2000\, W/m^2.$ In the steady state

A
The black body and furnace can't be distinguished
B
The black body will appear darker than the furnace
C
The black body will appear brighter than the furnace
D
Information insufficient

Medium

STD 11 Science
NEET
STD 11 - 10.2. transmission of heat
Physics

Download our app
and get started for free

Experience the future of education. Simply download our apps or reach out to us for more information. Let's shape the future of learning together!No signup needed.*

Download App

Similar Questions

1
A heated body maintained at $T\,K$ emits thermal radiation of total energy $E$ with a maximum intensity at frequency $v$ . The emissivity of the material is $0.5$ . If the temperature of the body be increased and maintained at temperature $3T\,K$ , then

$(i)$ The maximum intensity of the emitted radiation will occur at frequency $v /3$

$(ii)$ The maximum intensity of the emitted radiation will occur at frequency $3v $

$(iii)$ The total energy of emitted radiation will become $81\,E$

$(iv)$ The total energy of emitted radiation will become $27\,E$
View Solution
2
A body cools from $80^{\circ}\,C$ to $60^{\circ}\,C$ in $5$ minutes. The temperature of the surrounding is $20^{\circ} C$. The time it takes to cool from $60^{\circ}\,C$ to $40^{\circ}\,C$ is........... $s$
View Solution
3
The radiant energy from the sun incident normally at the surface of earth is $20\, \frac{{k\;cal}}{{{m^2}\;min}}$. What would have been the radiant energy incident normally on the earth, if the sun had a temperature twice of the present one ....... $kcal/m ^2 \,min$
View Solution
4
Find effective thermal resistance between $A$ & $B$ of cube made up of $12$ rods of same dimensions and shown given thermal conductivity. [ $l =$ length of rod, $a =$ cross section area of rod]
View Solution
5
A body cools in $7$ minutes from $60^{\circ}\,C$ to $40^{\circ}\,C$. The temperature of the surrounding is $10^{\circ}\,C$. The temperature of the body after the next $7$ minutes will be
View Solution
6
Two rods of same material have same length and area. The heat $\Delta Q$ flows through them for $12\,minutes$ when they are jointed in series. If now both the rods are joined in parallel, then the same amount of heat $\Delta Q$ will flow in ........ $\min$
View Solution
7
Two rods of same length and cross section are joined along the length. Thermal conductivities of first and second rod are ${K_1}\,\,{\rm{and}}\,\,{K_2}$. The temperature of the free ends of the first and second rods are maintained at ${\theta _1}\,\,{\rm{and }}{\theta _2}$ respectively. The temperature of the common junction is
View Solution
8
A spherical black body with a radius of $24\;cm$ radiates $440\;W$ power at $500\;K$. If the radius were halved and the temperature doubled, the power radiated in watt would be
View Solution
9
The total radiative power emitted by spherical black body with radius $R$ and temperature $T$ is $P$. If the radius is doubled and the temperature is halved, then the radiative power will be
View Solution
10
How is the temperature of stars determined by
View Solution

Download our appand get started for free

Similar Questions

Download our app
and get started for free