The quantity `(PV)/(k_(B)T)` represents the (` k_(B):`Boltzmann constant)

The quantity(pV)/(kt) represents

K_(m) value represents

In the equation ((1)/(pbeta))=(y)/(k_(B)T) , where p is the pressure, y is the distance, k_(B) is Boltzmann constant and T is the tempreture. Dimensions of beta are

An HCl molecule has rolational, translational and vibrational motions. If the rms velocity is bar(v) , m is its mass and k_(B) is Boltzmann constant, then its temperature will be :

In certain region of space there are n number of molecules per unit volume. The temperature of the gas is T. The pressure of the gas will be (k = Boltzmann's constant and R = universal gas constant)

A quantity X is given by X = ((R )/( N_(A)K))^(2) where R is the universal gas constant, N_(A) is Avagadro number & K is the Boltzmann's constant Dimension of X is that of

A quantity X is given by X = ((R )/( N_(A)K))^(2) where R is the universal gas constant, N_(A) is Avagadro number & K is the Boltzmann's constant Dimension of X is that of

The wavelength of de-Broglie wave associated with a thermal neutron of mass m at absolute temperature T is given by (here, k is the Boltzmann constant)

The dimensions of Stefan-Boltzman constant sigma can be written in terms of Plank's constant h. Boltzmann constant k_(B) and the speed of light c as sigma = h^(alpha) K_(B)^(b) c^(Y) . Here

The average thermal energy for a mono-atomic gas is: ( k_B is Boltzmann constant and T, absolute temperature)