For a given one mole of ideal gas kept at 6.5 atm in a container of capacity 2.463L, the Avogadro proportionality constant for the hypothesis is ( see figure )

Calculate the amount of work done when one mole of an ideal gas contained in a bulb of 2 L capacity at 1 atm is allowed to enter in evacuted bulb of 10 L capacity and in another case if is allowed to expand from 1 L to 5 L against a pressure of 1 atm.

Calculate the amount of work done when one mole of an ideal gas contained in a bulb of 2 L capacity at 1 atm is allowed to enter in evacuted bulb of 10 L capacity and in another case if is allowed to expand from 1 L to 5 L against a pressure of 1 atm.

One mole of an ideal gas is expanded from a volume of 3L to 5L under a constant pressure of 1 atm. Calculate the work done by the gas.

If one mole of monoatomic ideal gas expanded from 2 atm to 0.5 atm at 27°C, then the entropy change will be

An ideal gas of one mole is kept in a rigid container of negligible heat capacity. If 25J of heat is supplied the gas temperature raises by 2^(@)C . Then the gas may be

Calculate the moles of an ideal gas at pressure 2 atm and volume 1 L at a temperature of 97.5 K

One mole of an ideal monatomic gas undergoes a process described by the equation PV^(3) = constant. The heat capacity of the gas during this process is

one mole of an ideal gas at 300k in thermal contact with surroundings expands isothermally from 1.0 L to 2.0 L against a constant presses of 3.0 atm. In this process. The change in entropy of surrroundings (DeltaS) in J^(-1) is (1 L atm = 101.3 J)

A quantity of 4.0 moles of an ideal gas at 20^(@)C expands isothermally against a constant pressure of 2.0 atm from 1.0 L to 10.0L. What is the entropy change of the system (in cals)?

For a closed container containing 10 moles of an ideal gas, at constant pressure of 0.82 atm, which graph correctly represent, variation of log V us log T where volume is in litre and temp. in kelvin :