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 10 g ice cube is dropped into 45 g of water kept in a glass. If the water was initially at a temperature of 28^(@)C and the temperature of ice -15^(@)C , find the final temperature (in ^(@)C ) of water. (Specific heat of ice =0.5" "cal//g-""^(@)C" and "L=80" "cal//g)

A body cools in a surrounding of constant temperature 30^@C Its heat capacity is 2 J//^@C . Initial temeprature of cooling is valid. The body cools to 38^@C in 10 min The temperature of the body In .^@C denoted by theta . The veriation of theta versus time t is best denoted as

A closed cubical box is made of perfectly insulating material and the only way for heat to enter or leave the box is through two solid cylindrical metal plugs, each of cross sectional area 12cm^(2) and length 8cm fixed in the opposite walls of the box. The outer surface of one plug is kept at a temperature of 100^(@)C . while the outer surface of the plug is maintained at a temperature of 4(@)C . The thermal conductivity of the material of the plug is 2.0Wm^(-1).^(@)C^(-1) . A source of energy generating 13W is enclosed inside the box. Find the equilibrium temperature of the inner surface of the box assuming that it is the same at all points on the inner surface.

The two ends of a metal rod are maintained at temperatures 100^(@)C and 110^(@)C . The rate of heat flow in the rod is found to be 4.0" Js"^(-1) . If the ends are maintained at temperatures 200^(@)C and 210^(@)C , the rate of heat flow will be :

An air bubble of volume 1.0 cm^(3) rises from the bottom of a lake 40 m deep at a temperature of 12^(@)C . To what volume does it grow when it reaches the surface. which is at a temperature of 35^(@)C ?

2g ice at 0^(@)C is mixed with 1 g steam at 100^(@)C . Find the final temperature of the mixture.

An electric heater is used in a room of total wall area 137m^(2) to maintain a temperature of +20^(@)C inside it when the outside temperature is -10^(@)C . The walls have three different layers materials . The innermost layer is of wood of thickness 2.5 cm, in the middle layer is od cement of thickness 1.0 cm and the outermost layer is of brick of thickness 25.0 cm. find the power of the electric heater. Assume that there is no heat loss through the floor and the ceiling. The thermal conductives of wood, cement and brick are 0.125, 1.5 and 1.0 watt//m// .^(@)C respectively.

The temperatures T_(1) and T(2) of two heat reservoirs in an ideal carnot engine are 1500^(@)C and 500^(@)C . Which of these (a) increasing T_(1) by 100^(@)C or (b) decreasing T_(2) by 100^(@)C would result in greater improvement of the efficiency of the engine?

In thermal steady state of rod, temperature gradient is 5^(@) C/cm and temperature of its hot end is 100^(@)C , then at . . . . . . cm distance from hot end its temperature becomes 60^(@)C .

Value of temperature gradient is 80^(@) C/m on a rod of 0.5 m length. Temperature of hot end is 30^(@)C , then what is the temperature of cold end ?