Sure, here is the derivation of the expression of pressure variation with altitude in a gas under adiabatic condition:

1. The equation of motion for a small parcel of air in the atmosphere is given by Newton's second law, F = ma. In the vertical direction, the forces are gravity and the pressure gradient force, so we have:

m*g = -dP

where m is the mass of the air parcel, g is the acceleration due to gravity, P is the pressure, and d is the differential operator.

2. We can express the mass m in terms of the density ρ and the volume V of the air parcel, m = ρ*V. Substituting this into the equation gives:

ρ*V*g = -dP

3. We can rearrange this equation to give the pressure gradient in terms of the density and gravity:

dP = -ρ*V*g

4. Under adiabatic conditions, the pressure P and the density ρ of the gas are related by the adiabatic equation of state, P = K*ρ^(γ), where K is a constant and γ is the ratio of specific heats (γ = Cp/Cv).

5. Substituting the adiabatic equation of state into the pressure gradient equation gives:

dP = -K*γ*ρ^(γ-1)*V*g

6. We can rearrange this equation to give the pressure as a function of altitude z (assuming that the pressure decreases with increasing altitude):

P(z) = P0 * exp(-g/(K*γ) * ∫ρ^(γ-1) dz)

where P0 is the pressure at sea level (z = 0) and the integral is taken from 0 to z.

This is the expression for the pressure variation with altitude in a gas under adiabatic conditions.

Question

Sure, here is the derivation of the expression of pressure variation with altitude in a gas under adiabatic condition:

1. The equation of motion for a small parcel of air in the atmosphere is given by Newton's second law, F = ma. In the vertical direction, the forces are gravity and the pressure gradient force, so we have:

m*g = -dP

where m is the mass of the air parcel, g is the acceleration due to gravity, P is the pressure, and d is the differential operator.

2. We can express the mass m in terms of the density ρ and the volume V of the air parcel, m = ρ*V. Substituting this into the equation gives:

ρ*V*g = -dP

3. We can rearrange this equation to give the pressure gradient in terms of the density and gravity:

dP = -ρ*V*g

4. Under adiabatic conditions, the pressure P and the density ρ of the gas are related by the adiabatic equation of state, P = K*ρ^(γ), where K is a constant and γ is the ratio of specific heats (γ = Cp/Cv).

5. Substituting the adiabatic equation of state into the pressure gradient equation gives:

dP = -K*γ*ρ^(γ-1)*V*g

6. We can rearrange this equation to give the pressure as a function of altitude z (assuming that the pressure decreases with increasing altitude):

P(z) = P0 * exp(-g/(K*γ) * ∫ρ^(γ-1) dz)

where P0 is the pressure at sea level (z = 0) and the integral is taken from 0 to z.

This is the expression for the pressure variation with altitude in a gas under adiabatic conditions.

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