Answer:
New pressure of the gas increases by 26.5% with respect to initial pressure, new volume decreases 27% with respect to initial volume and new temperature decreases 8% with respect to initial volume.
Explanation:
If we assume the gas is a perfect gas we can use the perfect gas equation:
[tex]PV=nRT [/tex]
[tex] \frac{P_{1}V_{1}}{T_{1}}=\frac{P_{2}V_{2}}{T_{2}} [/tex](1)
Where subscripts 1 shows before the isothermal process and 2 after it, because isothermal means constant temperature T1=T2, and pressure increases by 10% means P2=1,1*P1, using these facts on (1) we have:
[tex] V_{2}=\frac{V_{1}}{1.1} [/tex] (2)
[tex] \frac{P_{2}V_{2}}{T_{2}}=\frac{P_{3}V_{3}}{T_{3}} [/tex] (3)
Where subscripts 2 shows before the isobaric process and 3 after it, because isobaric means constant pressure P2=P3, and volume decreases by 20% means V3=0.8*V2, using these facts on (3) we have:
[tex] T_{3}=0.8T_{2} [/tex] (4)
[tex] \frac{P_{3}V_{3}}{T_{3}}=\frac{P_{4}V_{4}}{T_{4}} [/tex] (5)
Where subscripts 3 shows before the isochoric process and 4 after it, because isochoric means constant volume V3=V4, and temperature increases by 15% means T4=1.15*T3, using these facts on (5) we have:
[tex]P_{4}=1.15P_{3}[/tex] (6)
So now because P4=1.15*P3, P2=P3 and P2=1.1*P1:
[tex]P_{4}=1.15*1.1P_{1}=1.265P1[/tex]
This is, the new pressure of the gas increases by 26.5% with respect to initial pressure.
Similarly, we have V3=V4, V3=0.8*V2 and V1=1,1*V2:
[tex]V_{4}=\frac{0.8}{1.1}V_{1}=0.72V1[/tex]
so the final volume decreases 27% with respect to initial volume.
T4=1,15*T3, T3=0.8*T2 and T1=T2:
[tex]T_{4}=1.15*0.8T_{1}=0.92T1[/tex]
The new temperature decreases 8% with respect to initial volume.
