What will be the change in internal energy of 128 g of oxygen gas at constant volume when it is heated from `30^(@)C` to `45^(@)C`? The molar specific heat of oxygen at constant pressure is `C_(p) = 7.03 cal cdot mol^(-1) cdot^(@)C^(-1)` and `R = 8.31 J cdot mol^(-1) cdot^(@)C^(-1)`.

The specific heat of oxygen gas at constant volume is 0.155 cal cdot g^(-1) cdot^(@)C^(-1) . What is its specific heat at constant pressure? Given, the molecular mass of oxygen = 32 and R = 2 cal cdot mol^(-1) cdot^(@)C^(-1) .

The temperature of 20 g of oxygen gas is raised from 10^(@)C to 90^(@)C . Find out the heat supplied, the rise in internal energy and the work done by the gas, if the temperature rises at (i) constant volume. (ii) constant pressure. Given the specific heats of oxygen are 0.155 cal cdot g^(-1) cdot^(@)C^(-1) at constant volume, and 0.218 cal cdot g^(-1) cdot^(@)C^(-1) at constant pressure.

What will be the change in internal energy if 10 g of air is heated from 20^(@)C to 30^(@)C at constant volume? Given , for air, c_(v) = 0.17 cal cdot g^(-1) cdot^(@)C^(-1) .

Which is greater - specific heat at constant volume, C_(v) or specific heat at constant pressure, C_(p) ?

Find out the molar specific heats C_(p) an C_(v) of an ideal gas having gamma = 1.67 . Given, R = 2 cal cdot mol^(-1) cdot^(@)C^(-1) .

The temperature of 20 g of oxygen gas is raised from 50^(@)C to 100^(@)C . (ii) At constant pressure. Find out the amount of heat supplied and the rise in internal energy in case. Given , R = 2 cal cdot mol^(-1) cdot K^(-1) , for oxygen, c_(v) = 0.155 cal cdot g^(-1) cdot^(@)C^(-1) .

For an ideal gas, gamma = 1.4 . Find out the two molar specific heats of this gas. [R = 2 cal cdot mol^(-1) cdot^(@)C^(-1)]

Calculate heat of combustion of benzene at constant pressure at 27^@C . (R=8.3 J mol^-1 K^-1)