What is the change in internal energy when a gas contracts form 377 mL to 177 mL under a constant pressure of 1520 torr, while at the same time being cooled by removing 124 J heat?

What is the change internal energy when a gas contracts from 377 mL to 177 mL under a constant pressure of 1520 torr, while at the same time being cooled by removing 124 J heat ? [Take :( 1 L atm ) =100 J)]

What is the change in internal energy if 10 J of heat is given to system at constant pressure and 20 J of work is done by the system?

A sample of gas contracts by 1 litre against a constant pressure of 0.1 atm while 5.13 J heat it lost to surroundings. The change in internal energy, U of the system is

When gas is given heat DeltaQ , a part of heat energy is utilized into work done W by gas and the remaining part is utilized to change in internal energy. An ideal diatomic gas is heated at constant pressure, the ratio of the internal energy change to heat energy supplied, is

calculate the change in internal energy of a gas kept in a rigid container when 100 J of heat is supplied to it.

What is the increase in volume, when the temperature of 600 mL of air increases from 27^(@)C to 47^(@)C under constant pressure?

What is the increase in volume, when the temperature of 600 mL of air increases from 27^(@)C to 47^(@)C under constant pressure?

A gas expends from 2 L to 6L against a constant pressure of 0.5 atm on absobing 200 J of heat. Calculate the change in internal energy.

The change in internal energy when 5 mole of hydrogen is heated to 20^(@)C from 10^(@)C , specific heat of hydrogen at constant pressure is 8 cal/mol .^(@)C is

C_p is always greater than C_v for a gas, which of the following statements provide, partly or wholly, the reason for this? (i) No work is done by a gas at constant volume (ii) When a gas absorbs heat at constant pressure, its volume must change (iii) For the same change in temperature, the internal energy of a gas changes by a smaller amount at constant volume that at constant pressure (iv) The internal energy of an ideal gas is a function only of its temperature