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

In the relation: P=(alpha)/(beta)e^(-(alphaZ)/(ktheta)),P is pressure Z is distance k is Boltzmann constant and theta is the temperature. The dimensional formula of beta will be

In the relation: P=(alpha)/(beta)e^(-(alphaZ)/(ktheta)),P is pressure Z is distance k is Boltzmann constant and theta ils the temperature. The dimensional formula of beta will bes

In the relation, P=alpha/beta e^((alphaZ)/(ktheta))P is pressure, Z is distance, k is Boltzmann constant and theta is the temperature. The dimensional formula of beta will be-

In the relaction p = (a)/(beta) e ^((aZ)/(k theta ) , p is pressure Z is distance .k is Boltamann constant and theta is the teperations . The dimensional formula of beta will be

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

The force of interaction between two atoms is given by F= alpha beta exp(-(x^2)/(alphakt)) , where x is the distance ,k is the Boltzmann constant and T is temperature and alpha " and " beta are two constans. The dimension of beta is :

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

The dimensions of a/b in the equation P=(a-t^(2))/(bx) where P is pressure, x is distance and t is time are

Write the dimensions of a//b in the relation P = ( a - t^(2))/( bx) , where P is the pressure , x is the distance , and t is the time .

F=alphabetae^((-(x)/(alphakt))) k = Boltzmann constant t = temperature x = distance The dimensions of beta is