`50 gm `of copper is heated to increase its temperature by `10^(@)C.` If the same quantity of heat is given to `10 gm `of water, the rise in its temperature is (Specific heat of copper`=420 Joule-kg^(-1)@C^(-1)`

50 g of copper is heated to increase its temperature by 10^@C . If the same quantity of heat is given to 10g of water, the rise in its temperature is (specific heat of copper =420J//kg^(@)//C )

75 gm of copper is heated to increase its temperature by 10^@ C . If the same quantity of heat is given to 'm' gm of water, to have same rise in temperature is (specific heat of copper = 420 J//Kg-^@ C ).

Certain amount of heat is given to 100 g of copper to increase its temperature by 21^@C . If same amount of heat is given to 50 g of water, then the rise in its temperature is (specific heat capacity of copper = 400 J kg^(-1) K^(-1) and that for water = 4200 J kg^(-1) K^(-1))

30 gram copper is heated to increase its temperature by 20^@ C if the same quantity of heat is given to 20 gram of water the rise in its temperature. (S_(w)=4200J//kg-K & S_(cu) = 420 J//kg-K) .

Heat given to a body which raises its temperature by 1^@C is

Heat required to increases the temperature of 1kg water by 20^(@)C

10 mol of a gas is heated at constant pressure to raise its temperature by 1^(@) C. The work done in joules is

1 calorie is the heat required to increased the temperature of 1 gm of water by 1°C from

Quantity of heat lost in condensation of 10 gm of steam at 100^@ C is

A calorimeter takes 200 cal of heat to rise its temperature through 10^@C . Its water equivalent in gm is