What will be the work done for expansion of a gas from 1 lit to 10 lit volume agaist constant pressure of 1 bar?

Work done in expansion of an ideal gas from 4 litre to 6 litre against a constant external pressure of 2.1 atm was used to heat up 1 mole of water at 293 K . If specific heat of water is 4.2 J g^(-1)K^(-1) , what is the final temperature of water?

The work done during the expansion of a gas from a volume of 3 dm^(3) against a constant external pressure of 3 atm is (1 L atm = 101.3 J)

What is the work done when 1 mole of a gas expands isothermally from 25 L to 250 L at a constant pressure of 1 atm and a temperature of 300 K ?

Calculate the work done by 0.1 mole of a gas at 27^(@)C to double its volume at constant pressure (R = 2 cal mol^(-1)K^(-1))

The work done during the expanision of a gas from a volume of 4 dm^(3) to 6 dm^(3) against a constant external pressure of 3 atm is (1 L atm = 101.32 J)

The work done during the expanision of a gas from a volume of 4 dm^(3) to 6 dm^(3) against a constant external pressure of 3 atm is (1 L atm = 101.32 J)

Work done in expansion of an idela gas from 4L to 6L against a constant external pressure of 2.5 atm was used to heat up 1mol of water at 293K . If specific heat of water is 4.184J g^(-1)K^(-1) , what is the final temperature of water.

The pressure-volume of varies thermodynamic process is shown in graphs: Work is the mole of transference of energy. It has been observed that reversible work done by the system is the maximum obtainable work. w_(rev) gt w_(irr) The works of isothermal and adiabatic processes are different from each other. w_("isothermal reversible") = 2.303 nRT log_(10) ((V_(2))/(V_(1))) = 2.303 nRT log_(10)((P_(2))/(P_(1))) w_("adiabatic reversible") = C_(V) (T_(1)-T_(2)) The q value and work done in isothermal reversible expansion of one mole of an ideal gas from initial pressure of 1 bar to final pressure of 0.1 bar at constant temperature 273K are:

Show that the volume thermal expansion coefficient for an ideal gas at constant pressure is (1)/(T) .

Show that the volume thermal expansion coefficient for an ideal gas at constant pressure is (1)/(T) .