One litre of ideal gas is conpressed isothermally at 0.72m of Hg-column so that its volume becomes 0.9 litre. Find its stress, if the mercury is `13.6 xx 10^(3) kg//m^(3)`.

One litre of ideal gas is compressed isothermal at 0.72 m of Hg-column so that its volume becomes 0.9 litre. Find its stress, if the density of mercury is 13.6xx10^(3)kg//m^(3) .

One mole of an ideal gas is expanded freely and isothermally at 300 K from 10 litres to 100 litres. If DeltaE=0 , the value of DeltaH is

One mole of an ideal gas expanded freely and isothermally at 300 K from 5 litres to 10 litres. If DeltaE is 0 , then DeltaH is

One litre of a gas, kept at a pressure of 75 cm. of mercury is compressed isothermally. If its volume becomes 750 cm^(3) , then the bulk stress is (g = 10m//s^(2), e_("mercury") = 13.6 g//c.c]

When 5 moles of an ideal gas is compressed isothermally, its volume decreases from 5 litre to 1 litre. If the gas is at 27^(@) C, find the work done on the gas.

Density of mercury is 13.6 g cm^(-3) . Its density in kg m^(-3) is

One litre of a gas is maintained at pressure 72 cm of mercury. It is compressed isothermally so that its volume becomes 900 cm^3 . The values of stress and strain will be respectively

When 5 moles of an ideal gas is compressecd isothermally, its volume decreases from 5 litre to 1 litre. If the gas is at 27^(@)C , find the work done on the gas ("log"_(10)((1)/(5))=-0.6990) .

0.5 litres of an ideal gas is present at a pressure of 700 mm of Hg and 30^@ C. Find its volume at standard temperature and pressure.