Answer:
The temperature T= 648.07k
Explanation:
T1=input temperature of the first heat engine =1400k
T=output temperature of the first heat engine and input temperature of the second heat engine= unknown
T3=output temperature of the second heat engine=300k
but carnot efficiency of heat engine =[tex]1 - \frac{Tl}{Th} \\[/tex]
where Th =temperature at which the heat enters the engine
Tl is the temperature of the environment
since both engines have the same thermal capacities [tex]n_{th}[/tex] therefore [tex]n_{th} =n_{th1} =n_{th2}\\n_{th }=1-\frac{T1}{T}=1-\frac{T}{T3}\\ \\= 1-\frac{1400}{T}=1-\frac{T}{300}\\[/tex]
We have now that
[tex]\frac{-1400}{T}+\frac{T}{300}=0\\[/tex]
multiplying through by T
[tex]-1400 + \frac{T^{2} }{300}=0\\[/tex]
multiplying through by 300
-[tex]420000+ T^{2} =0\\T^2 =420000\\\sqrt{T2}=\sqrt{420000} \\T=648.07k[/tex]
The temperature T= 648.07k
