An office room contains about 2000 moles of air. The change in the internal energy of this much air when it is cooled from 34 °C to 24 °C at a constant pressure of 1.0 atm is
( Use `gamma_("air")=1.4` and universal gas constant=8.314 J/mol K)

The molar specific heat of a gas at constant volume is 24 J/mol ^@K . Then change in its internal energy if one of such gas is heated at constant volume from 10^@C to 30^@C is

For one mole of an ideal gas the slope of V versus T curve at constant pressure of 2 atm is X lit mol^(-1) K^(-1) . The value of the ideal universal gas constant ‘R’ in terms of X is_________

One mole of an ideal gas is heated at constant pressure of 1 atmosphere form 0^@C to 100^@C the change in the internal energy is (R = 8 J/ mol K )

For one mole of an ideal gas the slope of V versus T curve at constant pressure of 2 atm is X lit mol^(-1) K^(-1) . The value of the ideal universal gas constant 'R' in terms of X is "___________" .

The specific heat of a gas at constant volume is 20J/mol ^@K . When two moles of such gas is heated through 10^@C at constant pressure, what is the increase in internal energy and work done ? (R= 8J/mol ^@ K)

One mole of an ideal gas expands isothermally at 300 K from 1 L to 101 L at constant pressure of 1 atmosphere. The work done during this change is ___________ . (1 L-atm =24.2 cal)

The energy of activation for a first order reaction is 104 kJ//mol . The rate constant at 25^@C is 3.7xx10^(-5)s^(-1) . What is the rate constant at 30^@C ? (R= 8.314 j//K mol) ]

One mole of an ideal gas requires 207 J heat to raise the temperature by 10 K, when heated at constant pressure. If the same gas is heated at constant volume to raise the temperature by 10 K, then heat required is [given gas constant. R = 8.31/(mol -K)]

When the temperature of 5 mol of a gas is changed from 100^@C to 120^@C keeping the volume constant, the change in internal energy of the gas is 80 J, then find the heat capacity of the gas at constant volume.

5 mol of oxygen is heated at constant volume from 10^@C to 20^@C . Find the change in internal energy of the gas