using the following graph for an ideal gas follow `PV^(1/2)` = constant . find `P_1//P_2` ratio. If `V_2 = 2V_1`

A gas follows PV^(1/2)= constant as shown. If V_2 =2V_1 , find T_2/T_1

P-V graph for an ideal gas undergoing polytropic process PV^(m) = constant is shown here. Find the value of m.

In the following P–V diagram of an ideal gas, two adiabates cut two isotherms at T_1 and T_2 The value of V_B // V_C is :

An ideal gas follows following process P^(2)V= constant. Then on expansion, the tempereture of gas

For an ideal gas V - T curves at constant pressure P_(1) & P_(2) are shown in figure, from the figure

During an experiment, an ideal gas is found to obey an additional law p//V^(2) = constant. The gas is initially at a temperature T and volume V . Find the temperature when it expands to a volume 2V .

An ideal gas follows a process PV^(gamma) = constant where gamma = adiabatic exponent.The slope of P-V graph will be represented by

Which one of the following is the correct PV vs P plot at constant temperature for an ideal gas ? (P and V stand for pressure and volume of the gas respectively)