Two colsed vessel A and B of equal volume containing air at pressure `P_(1)` and temperature `T_(1)` are connected to each other through a narrow open tube . If the temperature of one is now maintained at `T_(1)` and other at `T_(2)` (where `T_(1)gtT_(2)`) then that what will be the final pressure ?

Two closed vessel A and B of equal volume containing air at pressure P_(1) and temperature T_(1) are connected to each other through a naroow open tube. If th temperature of one is now maintained at T_(1) and other at T_(2) (wehre T_(1) gt T_(2) ) then that what will be the final pressure ?

Two closed vessels of equal volume containing air at pressure P_(1) and temperature T_(1) are connected to each other through a narrow tube. If the temperature in one of the vessels is now maintained at T_(1) and that in the other at T_(2) , what will be the pressure in the vessels?

Two closed vessels of equal volume containing air at pressure P_(1) and temperature T_(1) are connected to each other through a narrow tube. If the temperature in one of the vessels is now maintained at T_(1) and that in the other at T_(2) , what will be the pressure in the vessels?

Two closed bulbs of equal volume (V) containing an ideal gas initially at pressure P_(i) and temperature T_(1) are connected through a narrow tube of negligible volume as shown in the figure below . The temperature of one of the bulbs is then raised to T_(2) . the final pressure Pf is

A closed vessel A having volume V contains N_(2) at pressure P and temperature T. another closed vessel B having the same volume V contains. He at the same pressure P. but temperature 2T. The ratio of masses of N_(2) and He in the vesses A and B is

Gaseous system is placed with pressure P_(1) , volume V_(1) and temperature T_(1) , it has undergone thermodynamic changes where temperature is remaining constant, it is

Three rods of same cross-section but different length and conductivity are joined in series . If the temperature of the two extreme ends are T_(1) and T_(2) (T_(1)gtT_(2)) find the rate of heat transfer H.

Two containers of equal volume contain the same gas at pressure P_(1) and P_(2) and absolute temperature T_(1) and T_(2) , respectively. On joining the vessels, the gas reaches a common pressure P and common temperature T . The ratio P//T is equal to

Two containers of equal volume contain the same gas at pressure P_(1) and P_(2) and absolute temperature T_(1) and T_(2) , respectively. On joining the vessels, the gas reaches a common pressure P and common temperature T . The ratio P//T is equal to

Two bars of same length and same cross-sectional area but of different thermal conductivites K_(1) and K_(2) are joined end to end as shown in the figure. One end of the compound bar it is at temperature T_(1) and the opposite end at temperature T_(2) (where T_(1) gt T_(2) ). The temperature of the junction is