$6-17.$ A gas stream with a flow rate of $1000mo\frac{l}{m}in$ leaves a reactor at $T=450K$ and $P=10$ bar. For the next step, the temperature of the gas must be reduced to $300K,$ but the pressure of the stream isn't very important. Consequently, a turbine is being placed after the reactor, to obtain some work, but the turbine must be designed to have an actual outlet temperature of $300K.$ Find the turbine outlet pressure and the work produced for each of the following cases. In all cases, the gas has $C_P^{**}=40\frac{J}{m}ol*K.$

A$.$ The gas is an ideal gas, and the turbine is reversible.

B$.$ The gas is an ideal gas, but the turbine efficiency is $80\%.$ Find the turbine outlet pressure and the work produced.

C$.$ The turbine is reversible, and the gas follows the equation of state.

D$.$ The turbine efficiency is $80\%,$ and the gas follows the equation of state.