Comprehension-2
A mono atomic ideal gas is filled in a non conducting container. The gas can be compressed by a movable non conducting piston. The gas is compressed slowly to `12.5%` of its initial volume.
The ratio of work done by the gas to the change in internal energy of the gas is

Comprehension-2 A mono atomic ideal gas is filled in a non conducting container. The gas can be compressed by a movable non conducting piston. The gas is compressed slowly to 12.5% of its initial volume. The percentage increases in the temperature of the gas is

Comprehension-2 A mono atomic ideal gas is filled in a non conducting container. The gas can be compressed by a movable non conducting piston. The gas is compressed slowly to 12.5% of its initial volume. The percentage increases in the temperature of the gas is

Comprehension-2 A mono atomic ideal gas is filled in a non conducting container. The gas can be compressed by a movable non conducting piston. The gas is compressed slowly to 12.5% of its initial volume. The ratio of initial adiabatic bulk molulus of the gas to the finla value of adiabatic bulk modulus of the gas is

Comprehension-2 A mono atomic ideal gas is filled in a non conducting container. The gas can be compressed by a movable non conducting piston. The gas is compressed slowly to 12.5% of its initial volume. The ratio of initial adiabatic bulk molulus of the gas to the finla value of adiabatic bulk modulus of the gas is

An ideal gas is compressed in a closed container its U

An ideal gas is compressed in a closed container its U

An ideal gas is compressed in a closed container its U

The internal energy of non-ideal gas depends on

The internal energy of non-ideal gas depends on

n moles of a gas fille in a a container temperature T is in thermodynamic equilibrium initially. If the gas is compressed slowly and isothermally so half its initial volume volume the work done by the atmosphere on the piston is :