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)]

The specific heat at constant pressure is greater than that for the same gas at constant volume because

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

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

743 J of heat energy is needed to raise the temperature of 5 moles of an ideal gas by 2 K at constant pressure. How much heat energy is needed to raise the temperature of the same mass of the gas by 2 K at constant volume ?

The specific heat of gas under constant pressure as compared to specific heat under constant volume at the same temperature is

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?

294 joules of heat is requied to rise the temperature of 2 mole of an ideal gas at constant pressure from 30^(@)C to 35^(@)C . The amount of heat required to rise the temperature of the same gas through the same range of temperature at constant volume (R=8.3 "Joules/mole"-K) is

70 calories of heat is required to raise the temperature 2 moles of an ideal gas at constant pressure from 30^@C to 35^@C . What is the amount of heat required to raise the temperature of the same gas from 30^@C to 35^@C at constant volume?

One mole of an ideal gas at an initial temperature true of TK does 6R joule of work adiabatically. If the ratio of specific heats of this gas at constant pressure and at constant volume is 5//3 , the final temperature of the gas will be