Here `T_(1) and T_(2)` are

The velocities of sound in an ideal gas at temperature T_(1) and T_(2) K are found to be V_(1) and V_(2) respectively. If ther.m.s velocities of the molecules of the same gas at the same temperatures T_(1) and T_(2) are v_(1) and v_(2) respectively then

Two particles are projected from the same point with the same speed at different angles theta_(1) and theta_(2) to the horizontal. If their respectively times of flights are T_(1) and T_(2) and horizontal ranges are same then (a) theta_(1) + theta_(2) = 90^(@) (b) T_(1) = T_(2) tan theta_(1) (c) T_(1) = T_(2) tan theta_(2) (d) T_(1) sin theta_(2) = T_(2) sin theta_(1)

A cannot engine with efficiency eta operates between two heat reservoirs with temperatures T_(1) and T_(2) , where T_(1) gt T_(2) . If only T_(1) is changed by 0.4% , the change in efficiency is Delta eta_(1) , whereas if only T_(2) is changed by 0.2% , the efficiency is changed by Delta eta_(2) . The ratio (Delta eta_(1))/(Delta eta_(2)) is approximately.

Given is the graph between PV/T and P for 1 gm of oxygen gas at two different temperature T_(1) and T_(2) (Given:Density of oxygen= 1.429 kg//m^(3) ).The value of PV/T at the point A and the relation between T_(1) and T_(2) and respectively

Freundlich adsorption isotherms for the physical adsorption of a gas at temperature T_(1), T_(2) and T_(3) are shown in the graph given below. The correct relationship between T_(1), T_(2) and T_(3) is