Calculate the volume occupied by `2.0 mol` of `N_(2)` at `200 K` and `10.1325MPa` pressure if `(P_(c)V_(c))/(RT_(c))=(3)/(8)` and `(P_(r)V_(r))/(T_(r))=2.21`.

Calculate the volume occupied by 2.0 mole of N_(2) at 200K and 8.21 atm pressure, if (P_(C)V_(C))/(RT_(C)) = (3)/(8) and (P_(r)V_(r))/(T_(r)) = 2.4 .

Calculate the volume occupied by 16gram O_(2) at 300K and 8.31 Mpa if (P_(C)V_(C))/(RT_(C))=3//8 and (P_(r)V_(r))/(T_(r))=2.21 ( Given :R=8.314 MPa//K-mol )

Calculate the volume occupied by 8.8 g of CO_(2) at 31.1^(@)C and 1 bar pressure. R= 0.083 bar L K^(-1)mol^(-1).

The volume of 2.8g of CO at 27^(@)C and 0.821 atm pressure is (R=0.0821 lit. atm mol^(-1)K^(-1))

At low pressure, if RT=2sqrt(a.p), then the volume occupied by a real gas is : (a) (2RT)/(P) (b) (2P)/(RT) (c) (RT)/(2P) (d) (2RT)/(P)

Using the van der Waals equation, calculate the pressure of 10.0mol NH_(3) gas in a 10.0 L vessel at 27^(@)C . {:((P+n^(2)(a)/(V^(2)))(V-nb)=nRT,,a=4.2L^(2).atm//mol^(2),,b=0.037L//mol):}

T_(c) " and P_(c) of a gas are 400 K and 41 atms respectively . The V_(c) is

At low pressure, the van der Waal's equation become : (a) PV_(m)=RT (b) P(V_(m)-b)=RT (c) (P+(a)/(V_(M)^(2)))V_(m)=RT (d) P=(RT)/(V_(m))+(a)/(V_(m)^(2))

If .^(n)P_(r) = 720 and .^(n)C_(r) = 120 , then find r. .

For an ideal gas, an illustratio of three different paths A(B+C) and (D+E) from an initial state P_(1), V_(1), T_(1) to a final state P_(2), V_(2),T_(1) is shown in the given figure. Path A represents a reversible isothermal expansion form P_(1),V_(1) to P_(2),V_(2) , Path (B+C) represents a reversible adiabatic expansion (B) from P_(1),V_(1),T_(1)to P_(3),V_(2),T_(2) followed by reversible heating the gas at constant volume (C) from P_(3),V_(2),T_(2) to P_(2),V_(2),T_(1) . Path (D+E) represents a reversible expansion at constant pressure P_(1)(D) from P_(1),V_(1),T_(1) to P_(1),V_(2),T_(3) followed by a reversible cooling at constant volume V_(2)(E) from P_(1),V_(2),T_(3) to P_(2),V_(2),T_(1) . What is q_(rev) , for path (A) ?