Two vessels are connected by a valve of negligible volume. One container, A has 2.8 g `N_(2)` at `T_(1)K`. The other container, B is completely evacuated. The container A is heated to `T_(2)K`, while container B is maintained at `T_(2)/3 K` . Volume of A is half that of B. If the valve is opened, then

Two vessels connected by a valve of negligible volume. One container (I) has 2.8 g of N_(2) at temperature T_(1) (K) . The other container (II) is completely evacuated. The container (I) is heated to T_(2)(K) while container (II) is maintained at T_(2)//3(K) . volume of vessel (I) is half that of vessel (II). If the valve is opened then what is the mass ratio of N_(2) is both vessel (W_(I)//W_(II)) ?

The figure given below shows three glass chambers that are connected by valves of negligible volume. At the outset of an experiment, the valves are closed and the chambers contain the gases as detailed in the diagram. All the chambers are at the temperature of 300 K and external pressure of 1.0 atm . What is the total pressure in chamber B after valve 1 is opened?

Two idential container joined by a small pipe initially contain the same gas at pressure p_(0) and absolute temperature T_(0) . One container is now maintained at the same temperature while the other is heated to 2T_(0) . The common pressure of the gas

The figure given below shows three glass chambers that are connected by valves of negligible volume. At the outset of an experiment, the valves are closed and the chambers contain the gases as detailed in the diagram. All the chambers are at the temperature of 300 K and external pressure of 1.0 atm . Which of the following represents the total kinetic energy of all the gas molecules after both valves are opened? ( R=0.082 atm L K^(-1) mol^(-1)=8.314 JK^(_1)mol^(-1) )

Two closed vessel A and B of equal volume of 8.21 L are connected by a narrow tube of negligible volume with open valve. The left hand side container is found to contain 3 mole CO_(2) and 2 mole of He at 400 K. What is the partial pressure of He in vessel B at 400 K? (a)2.4 atm (b)8atm (c)12atm (d)None of these

Three closed rigid vessels, A, B and C, which initially contain three different gases at different temperatures are connected by tube of negligible volume, without any energy transfer with surroundings. The vessel A contain 2 mole Ne gas, at 300 K, vessel 'B' contain 2 mole SO_(2) gas at 400 K and vessel 'C' contain 3 mole CO_(2) gas at temperature 500 K. What is the final pressure (in atm) attained by gases when all valves of connecting three vessels are opened and additional 15.6 kcal hear supplied to vessels through valve. The volume of A, B and C vessel is 2, 2 and 3 litre respectively Given :R =2 calorie/mol-K, C_(v)(Ne)=3//2R,C_(v)(CO)=5//2R and C_(v)(SO_(2))=3R

Two vessels A and B having equal volume contain equal masses of hydrogen in A and helium in B at 300 K. Then, mark the correct statement?

Two identical containers joned by a small pipe initially contain the same gas at pressue p_(o) and abosolute temperature T_(o^.) One container is now mantained at the same temperature while the other is heated to 2T_(0^.) The commmon pressure of the gases will be

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?