A conducting cylindrical rod of uniform cross-sectional area is kept between two large chambers which are at temperatures `100^(@)`C and `0^(@)`C, respectively. The cconductivety of the rod increases with x, where x is distance from `100^(@)`C end. The temperature profile of the rod in steady -state will be as

Two ends of a rod of uniform cross sectional area are kept at temperature 3T_(0) and T_(0) as shown. Thermal conductivity of rod varies as k=alphaT , (where alpha is a constant and T is absolute temperature). In steady state, the temperature of the middle section of the rod is

Twelve conducting rods from the sides of a uniform cube of side l. If in steady state, B and H ends of the cube are at 100^(@)C and 0^(@)C respectively. Find the temperature of the junction 'A' :-

Two rods of same dimensions, but made of different materials are joined end to end to end with their free end being maintained at 100^(@)C and 0^(@)C respectively. The temperature of the junction is 70^(@)C . Then the temperature of the junction if the rods are inerchanged will be equal to T^(@)C Find T :

Temperature of hot end and cold end of a rod, which is in steady state are 100^(@)C and 40^(@)C respectively. The area of cross section of rod and its thermal conductivity are uniform. The temperature of rod at its mid point is (Assume no heat loss thorugh lateral surface)

Two ends of a conducting rod of varying cross-section are maintained at 200^(@)C and 0^(@)C respectively. In steady state:

The ends of a metre stick are maintain at 100^(@)C and 0^(@)C . One end of a rod is maintained 25^(@)C . Where should its other end be touched on the metre stick so that there is no heat current in the rod in steady state?

A lagged stick of cross section area 1 cm^(2) and length 1 m is initially at a temperature of 0^(@)C . It is then kept between 2 reservoirs of temperature 100^(@)C "and" 0^(@)C . Specific heat capacity is 10J//kg^(@)C and linear mass density is 2kg//m . Find (i) Temperature gradient along the rod in steady state (ii) Total heat absorbed by the rod to reach steady state

A metal rod of length 2 m has cross sectional areas 2 A and A as shown in figure. The ends are maintained at temperatures 100° C and 70° C . The temperature at middle point C is

Two rods A and B of same cross-sectional area A and length l are connected in series between a source (T_(1)=100^(@)C) and a sink (T_(2)-0^(@)C) as shown in figure. The rod is laterally insulated. If T_(A) and T_(B) are the temperature drops across the rod A and B, then

Two rods A and B of same cross-sectional area A and length l are connected in series between a source (T_(1)=100^(@)C) and a sink (T_(2)-0^(@)C) as shown in figure. The rod is laterally insulated. If G_(A) and G_(B) are the temperature gradients across the rod A and B, then