Gaseous hydrogen initially contained under standard conditions in a sealed vessel of volume `5xx10^(-3)m^(-3)` was cooled by `55K`. Find the change in internal energy and amount of heat lost by the gas.

Gaseous hydrogen initially at STP in a container of volume 5xx10^(-5)m^3 is cooled by 55 K.Find the change in internal energy and amount of heat lost by the gas.

Gaseous hydrogen contained initially under standard conditions in a sealed vessel of volume V = 5.01 L was cooled by DeltaT=50 K . Find how much the internal energy of the gas will change and what amount of heat will be lost by the gas.

Gaseous hydrogen contained initially under standard conditions in sealed vessel of volume V = 5 L was cooled by Delta T = 55 K . Find how much the internal energy of the gas will change and what amount of heat will be lost by the gas.

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

A gas is allowed to expand in an insulated container against a constant external pressure of 3 atm from an initial volume of 5.0L to final volume of 9.0L .The change in internal energy Delta U of the gas is

One mole of an ideal gas whose pressure changes with volume as P=alphaV , where alpha is a constant, is expanded so that its volume increase eta times. Find the change in internal energy and heat capacity of the gas.

When heat energy of 1500 J is supplied to a gas it is compressed from 10 m^(3) to 5 m^(3) at a pressure of 100 Pa. the change in internal energy is

A gas adsorbs 100 J heat and undergoes simultaneous expansion against a constant external pressure of 10^(4) Pa .If volume changed from 3L to 5L the change in internal energy is

When 100J of heat is given to an ideal gas it expands from 200cm^(3) to 400cm^(3) at a constant pressure of 3 xx 10^(5) Pa . Calculate (a) the change in internal energy of the gas (b) the number of moles in the gas if the initial temperature is 400K , (c ) the molar heat capacity C_(p) at constant pressure and (d) the molar heat capacity C_(v) at constant volume. [R = (25)/(3)J//mol-K]