At constant pressure the volumes of a given mass of gas at temperatures `27^(@)C and 54^(@)C` are `V_(1) and V_(2)` respectively. The ratio `(V_(1))/(V_(2))` is

For CO_(2) gas the P vs V isotherms at temperature above 31.1^(@)C are-

Draw a graph between pressure (P) vs volume (1/V) at constant temperature.

The initial pressure, temperature & volume of 1 mol of a gas are P_(1),T_(1) and V_(1) respectively. The state of the gas is changed by the following two ways. Will the internal energy change be the same in both cases? (1) P_(1)V_(1)T_(2) underset("Process")overset("Reversible")toP_(2)V_(2)T_(2) (2) P_(1)V_(1)T_(1) underset("process")overset("Irreversible")toP_(2)V_(2)T_(2) .

for a given mass of an ideal gas at constant temperature draw and explain the graphs (i) PV^(2) vs V (ii) P^(2)V vs V.

At constant pressure for a given amount of an ideal gas, will the graph obtained by plotting V vs t^(@)C and V vs TK be different ?

At a given pressure, the volume of a given amount of gas at 0^(@)C is V_(0) . (i) will the V vs t (celsius temperature) plot for this gas be linear (ii) will it be a straight line passing through the origin? (iii) if this straight line does ot pass through the origin, then what will be its slope and intercept?

At constant pressure for a given amount of an ideal gas, will the graphs obtained by plotting V vs t^(@)C and V vs TK be different?

If at 0^@C the volume of certain mass gas at constant pressure be V_0 . What will be its volume at 4^@C ?