If a gas is heated at constant pressure, its isothermal compressibility

When a gas is heated at constant pressure, its volume changes and hence

When an ideal diatomic gas is heated at constant pressure, the fraction of the heat energy supplied, which increases the internal energy of the gas, is

Practice problems : A 1 L bottle half-filled with a hydrogen gas is heated at constant pressure such that , its temperature changes by 20 ⁰C . What will be the volume of the hudrogen gas in the bottle after heating ?

The specific heat of a gas at constant volume is 20J/mol ^@K . When two moles of such gas is heated through 10^@C at constant pressure, what is the increase in internal energy and work done ? (R= 8J/mol ^@ K)

Why do we consider two specific heats of a gas? OR Why specific heat at constant pressure is greater than specific heat at constant volume?

One mole of an ideal gas requires 135 J of heat to raise its temperature by 15 ^@ K when heated at constant pressure. If the same gas is heated at constant volume to raise the temperature by the same, then the heat required will be (R = 8.3J /mole ^@K)

One mole of an ideal gas requires 207 J heat to raise the temperature by 10 K, when heated at constant pressure. If the same gas is heated at constant volume to raise the temperature by 10 K, then heat required is [given gas constant. R = 8.31/(mol -K)]

1 litre of an ideal gas at 27 °C is heated at a constant pressure to 297 °C. The final volume is approximately

When an ideal gas (Y = 5/3) is heated under constant pressure , then what percentage of given heat energy will be utilised in doing external work

For an ideal gas, in an isothermal process