During an adiabatic process, the volume of a gas is found to be proportional to the cube of its absolute temperature. The ratio Cp / CV for the gas is
5/3
4/3
3/2
5/4
The work done by a gas is maximum when it expands
isothermally
adiabatically
isentropically
isobarically
An ideal monoatomic gas at 27°C is compressed adiabatically to 8/27 times of its present volume. The increase in temperature of the gas is
375°C
402°C
175°C
475°C
Blowing air with open mouth is an example of
isobaric process
isochoric process
isothermal process
adiabatic process
An ideal gas heat engine operates in a Carnot's cycle between 227°C and 127°C. It absorbs 6 x 104 J at high temperature. The amount of heat converted into work is
1.6 × 104 J
1.2 × 104 J
4.8 × 104 J
3.5 × 104 J
B.
1.2 × 104 J
Using the relation
A monoatomic gas is suddenly compressed to (1/8) of its initial volume adiabatically. The ratio of its final pressure to the initial pressure is : (Given the ratio of the specific heats of the given gas to be 5/3)
32
40/3
24/5
8
A Carnot engine takes heat from a reservoir at 627° C and rejects heat to a sink at 27°C. Its efficiency will be
3/5
1/3
2/3
200/209
During an adiabatic process, the cube of the pressure is found to be inversely proportional to the fourth power of the volume. Then the ratio of specific heats is
1
1.33
1.67
1.4
A Carnot's engine operates with source at 127°C and sink at 27°C. If the source supplies 40 kJ of heat energy, the work done by the engine is
30 kJ
10 kJ
4 kJ
1 kJ
If γ is the ratio of specific heats and R is the universal gas constant, then the molar specific heat at constant volume CV is given by
γR