The degrees of freedom of a monatomic gas is f = 3. Its molar specific heats are $${C_v} = {f \over 2}RT$$ and $${C_p} = {C_v} + R = {{(f + 2)} \over 2}RT$$. The ratio of specific heats is given by

$$\gamma = {C_p}/{C_v} = (f + 2)/f = 5/3$$.

In an adiabatic process, $$TV_{}^{\gamma - 1}$$ = constant. Hence, $${T_1}V_1^{\gamma - 1} = {T_2}V_2^{\gamma - 1}$$, which gives

$${T_2} = {T_1}{({V_1}/{V_2})^{\gamma - 1}} = 100{(1/8)^{5/3 - 1}} = 25\,K$$,

where we used T₁ = 100 K and V₂ = 8V₁. The change in internal energy of one mole of the ideal gas is

$$\Delta U = {U_2} - {U_1} = {f \over 2}R{T_2} - {f \over 2}R{T_1} = {f \over 2}R({T_2} - {T_1})$$

$$ = (3/2)(8)(25 - 100) = - 900\,J$$.

Thus, the decrease in internal energy of the gas is 900 J.