During an isobaric heating process the work done by oxygen gas is 4 J. Calculate the amount of heat transferred to the gas. `[gamma = 1.4]`

In a isobaric process the work done by a di-atomic gas is 10 J , the heat given to the gas will be :

An ideal gas of adiabatic exponent gamma is expanded so that the amount of heat transferred to the gas is equal to the decrease of its internal energy. Then, the equation of the process in terms of the variables T and V is

In isobaric process of ideal gas (f=5) work done by gas is equal of 10J . Then heat given to gas during process:

Statement 1: Heat supplied to a gas is process is 100 J and work done by the gas in the same process is 120 J, then pressure of he gas in the process should increase. because Statement2: Work done by the gas is greater than the heat supplied to the gas. Hence, internal energy of the gas should decrease.

In a given process work done on a gas is 40 J and increase in its internal energy is 10J. Find heat given or taken to/from the gas in this process.

An ideal gas with adiabatic exponent ( gamma=1.5 ) undergoes a process in which work done by the gas is same as increase in internal energy of the gas. Here R is gas constant. The molar heat capacity C of gas for the process is:

During an expansion of ideal gas the work done by gas is 100 J and the heat capacity to process is found to be +2J//^(@)C . Find Delta E fo gas if the final temperature of gas is 25^(@)C higher than its initial temperature.

In the P-V diagram (Fig 15.14.1) given below, three thermodynamic processes occur for an ideal gas. Processes 1 to 2, 2 to 3 and 3 to 1 are isothermal, isochoric and adiabatic processes respectively. The total amt of work done is 10 J. During the process 3 to 1, 20 J of work is done on the system. The amount of heat added to the system during the process 1 to 2 is

In an isobaric process, heat is supplied to a monoatomic ideal gas. The fraction of heat that goes itno mechanical work is

One mole of an ideal gas is heated isobarically from the freezing point to the boiling point of water, each under normal pressure. Find out the work done by the gas and the change in its internal energy. The amount of heat involved is 1 kJ. Given gas constant R= 8.3 J/mol K.