`14 g of N_(2)` gas is heated in a closed rigid container to increase its temperature from `23^(@)C` to `43^(@)C`. The amount of heat supplied to the gas is

310 J of heat is required to rise the temperature of 2 moles of an ideal gas at constant pressure from 25^(@)C to 35^(@)C . The amount of heat required to raise the temperature of the gas through the same range at constant volume, is

One mole of a non linear triatomic gas is heated in a closed rigid container from 500^(@)C to 1500^(@)C . Calculate the amount of energy required if vibrational degree of freedom become effective only above 1000^(@)C .

310 J of heat is required to raise the temperature of 2 moles of an ideal gas at constant pressure from 25^(@)C to 35^(@)C .The amount of heat required to raise the temperature of the gas through the same range at constant volume is

105 calories of heat is required to raise the temperature of 3 moles of an ideaol gas at constant pressure from 30^(@)C to 35^(@)C. The amount of heat required in calories to raise the temperature of the gas though the range (60 ^(@)C to 65^(@)C) at constant volume is (gamma = (C_(p))/( C_(v)) = 1.4)

105 calories of heat is required to raise the temperature of 3 moles of an ideaol gas at constant pressure from 30^(@)C to 35^(@)C. The amount of heat required in calories to raise the temperature of the gas though the range (60 ^(@)C to 65^(@)C) at constant volume is (gamma = (C_(p))/( C_(v)) = 1.4)

5g of a gas is contained in a rigid container and is heated from 15^@C to 25^@C . Specific heat capacity of the gas at constant volume is 0.172 cal g ^(-1)^@C^(-1) and the mechanical equivalent of heat is 4.2 J cal . Calculate the change in the internal energy of the gas.

5g of a gas is contained in a rigid container and is heated from 15^@C to 25^@C . Specific heat capacity of the gas at constant volume is 0.172 cal g ^(-1)^@C^(-1) and the mechanical equivalent of heat is 4.2 J cal . Calculate the change in the internal energy of the gas.