`T_(c) " and P_(c)` of a gas are 400 K and 41 atms respectively . The `V_(c)` is

For a certain gas P_(c) and T_(c) are 80atm and -33^(@)C respectively then V_(C) of the gas will be approximately [Take R=(1)/(2)" Ltr atm mol"^(-1)K^(-1) ]

The change in the magnitude of the volume of an ideal gas when a small additional pressure DeltaP is applied at a constant temperature, is the same as the change when the temperature is reduced by a small quantity DeltaT at constant pressure. The initial temperature and pressure of the gas were 300 K and 2 atm. respectively. If |DeltaT|=C|DeltaP| then value of C in (K/atm) is __________.

The critical temperature (T_(c)) and critical pressure (p_(c)) of CO_(2) are 30.98^(@)C and 73 atm respectively. Can CO_(2) (g) be liquefied at 32^(@)C and 80 atm pressure ?

K_(p) for a reaction at 25^(@)C is 10 atm. The activation energy for forward and reverse reactions are 12 and 20 kJ mol^(-1) respectively. The K_(c) for the reaction at 40^(@)C will be:

A real gas has critical temperature and critical pressure as 40^(@)C and 10 atm respectively, then liquification of gas is possible at

The value of C_(p) - C_(v) is 1.09R for a gas sample in state A and is 1.00R in state B . Let A_(A),T_(B) denote the temperature and p_(A) and P_(B) denote the pressure of the states A and B respectively. Then

C_v and C_p denote the molar specific heat capacities of a gas at constant volume and constant pressure, respectively. Then

C_v and C_p denote the molar specific heat capacities of a gas at constant volume and constant pressure, respectively. Then

C_v and C_p denote the molar specific heat capacities of a gas at constant volume and constant pressure, respectively. Then

C_v and C_p denote the molar specific heat capacities of a gas at constant volume and constant pressure, respectively. Then