Two bodies A and B having equal surface areas are maintained at temperatures `10^(@)C` . And `20^(@)C` . The thermal radiation emitted in a given time by A and B are in the ratio

A spherical ball A of surface area 20cm^(2) is kept at the centre of a hollow spherical shell B of area 80cm^(2) . The surface of A and the inner surface of B emit as blackbodies. Both A and B are at 300K. (a) How much is the radiation energy emitted per second by the ball A? (b) How much is the radiation energy emitted per second by the inner surface of B? (c) How much of the energy emitted by the inner surface of B falls back on this surface itself?

Two parallel plates A and B are joined together to form a compound plate . The thicknesses of the plate are 4.0cm and 2.5cm respectively and the area of cross section is 100cm^(2) for each plate. The thermal conductivities are K_(A)=200Wm^(-1) C^(-1) for plate A and K_(B)=400Wm^(-1) C^(-1) for the plate B. The outer surface of the plate A is maintained at 100^(@)C and the outer surface of the plate B is maintained at 0^(@)C . Find (a) the rate of heat flow through any cross section, (b) the temperature at the interface and (c) the equivalent thermal conductivity of the compound plate.

There are two Carnot engines A and B operating in two different temperature regions. For Engine A the temperatures of the two reservoirs are 150^(@)C and 100^(@)C . For engine B the temperatures of the reservoirs are 350^(@)C and 300^(@)C . Which engine has lesser efficiency?

The velocity-time graph for two bodies Aand B are shown in figure. Then, the acceleration of A and B are in the ratio:

A charged partical having a charge of -2.0 xx 10^(-6) C is placed close to a nonconducting plate having a surface charge density 4.0 xx 10^(-6) C m^(-2) . Fine the force of attraction between the particle and the plate.

Three bodies A, B and C are in thermal equilibrium. The temperature of B is 45^@ C. then the temperature of C is

A spherical ball of surface area 20cm^(2) absorbs any radiation that falls on it. It is suspended in a closed box maintained at 57^(@)C . (a) Find the amount of radiation falling on the ball per second. (b) Find the net rate of heat flow to or from the ball at an instant when its temperature is 200^(@)C . Stefan constant =6.0xx10^(-s)Wm^(-2)K^(-4) .

One face of a copper cube of edge 10 cm is maintained at 100^(@)C and the opposite face is maintained at 0^(@)C . All other surfaces are covered with an insulating material. Find the amount of heat flowing per second through the cube. Thermal conductivity of copper is 385Wm^(-1) C^(-1) .

Figure shows an aluminium rod joined to a copper rod. Each of the rods has a length of 20cm and area of cross section 0.20cm^(2) . The junction is maintained at a constant temperature 40^(@)C and the two ends are maintained at 80^(@)C . Calculate the amount of heat taken out from the cold junction in one minute after the steady state is reached. The conductivities are K_(Al)=200Wm^(-1)C^(-1) . and K_(Cu)=400Wm^(-1)C^(-1) .