A gas absorbs 400 J of heat and expands by `2 xx 10^(-3)m^(3)` against a constant pressure of `1 xx 10^5 Nm^(-2)`. The change in internal energy is (1 L atm = 100 J)

If a gas absorbs 200J of heat and expands by 500 cm^(3) against a constant pressure of 2 xx 10^(5) Nm^(-2) then change in internal energy is

An ideal gas expands in volume from 10^(-3) m^(3) to 10^(-2)m^(3) at 300 K against a constant pressure of 10^(5) Nm^(-2) . The work done is

A gas absorbs 100 J of heat and is simultaneously compressed by a constant external pressure of 1.5 atm from a volume of 8.0L to 2.0L. The change in internal energy for the gas in Joules is (1L - atm = 101.32 J))

The internal energy of an ideal gas is given by U = 1.5 PV. It expands from 10 cm^(3) to 20 cm^(3) against a constant pressure of 2 xx 10^(5) Pa. heat absorbed by the gas in the process is

A gas absorbs 100 calories of heat energy and is compressed from 10L to 5L by applying an external pressure of 2 atm. Change in internal energy in calories will be nearly.

Four moles of a gas when heated through 20^(@)C expand by 6.3 xx 10^(-3) m^(3) under a const-ant pressure of 10^(5) N//m^(2) .. If 30 J "mole"^(-1)k^(-1) is C_(v) then the C_(p) in J "mole"^(-1)k^(-1) is,

An ideal gas expands from 500 cm^3 to 700 cm^3 against 1 atm pressure, by absorbing 2J of energy. Calculate change in internal energy of the ideal gas.