Statement-1: In equation `P=(1)/(3)alphaV_(rms)^(2)`, the term `alpha ` represents density of gas. ltBrgt Statement-2: `V_(rms)=sqrt((3RT)/(M))`
Statement-3: Rotational kinetic energy of a monoatomic gas is zero.

In equation p = 1/3 alpha v_(r m s)^(2) , the term (prop) represents dencity of gas. v_(r m s) = sqrt (3 R T)/(M) .

In the formula p = 2/3 E , the term (E) represents translational kinetic energy per unit volume of gas. In case of monoatomic gas, translational kinetic energy and total kinetic energy are equal.

Statement -1: If kinetic energy of a system is zero then linear momentum of each of particle of the system must be zero. Statement-2: If linear momentum of a system is zero then kinetic energy of system must be zero. Statement-3: If linear momentum of a particle is zero then kinetic energy is zero. Select the correct sequence.

Statement- 1 : Absolute zero temperature is not the temperature of zero energy. Statement- 2 : Only the intenal kinetic energy of the molecules is represented by temperature.

Statement -1 : In the formation of a neutron star, spin angular velocity increases tremendously. Statement-2 : Conservation of rotational kinetic energy

The pressure exerted by an ideal gas is P = (1)/(3) (M)/(V)C^(2) , where the symbols have their usual meaning. Using standard gas equation, PV = RT, we find that C^(2) = (3 RT)/(M) or C^(2) oo T . Average kinetic energy of translation of one mole of gas =(1)/(2) MC^(2) = (3 RT)/(2) with the help of the passage given above, choose the most appropriate alternative for each of the following quetions : At waht temperature, pressure remaining unchanged, will the rms velocity of a gas be half its value at 0^(@)C ?