The mass of a monoatomic gas can be computed from its specific heat at constant volume cV. (Note that this is not CV.) Take cV = 0.075 cal/g · C° for a gas and calculate (a) the mass of its atom and (b) the molar mass.

We have specific heat at constant volume [tex]c_{V} = 0.075 [/tex] cal/g
if the monoatomic gas behaves as ideal gas, we can know the molar specific heat at constant volume [tex]C_{V}[/tex] . For a monoatomical gas [tex]C_{V}=\frac{3}{2} R[/tex] with R the universal gas constant. So [tex]C_{V}= \frac{3}{2} (1.987 \frac{cal}{mol*K})=2.9805 \frac{cal}{mol*K}[[/tex].
We can calculate the heat with [tex]c_{V}[/tex] or [tex]C_{V}[/tex] as follows [tex]Q= m c_{V} \Delta T = n C_{V} \Delta T[/tex] with m: mass and n: number of moles. So we can solve that equation for the molar mass (M=m/n) obtaining [tex]M = \frac{m}{n} = \frac{C_{V} }{c_{V} }[/tex].
We can answer the question b) M=2.9805/0.075=39.74 g/mol
With the molar mass and the avogadro's number ([tex]N_{Av}=6.022*10^{23}[/tex] [tex]mol^{-1}[/tex] we can calculate the atom mass as follows [tex]m_{atom} = \frac{M}{N_{Av} }[/tex]
Answer for the question a) is [tex]m_{atom} =\frac{39.74}{6.022*10^{23} }=6.6*10^{-23}g[/tex]