An ideal gas undergoes the following reversible cycle: (i) an isobaric expansion from state (P1, V₁) to the state (P1, V2); (ii) an isochoric reduction in pressure to the state (P2, V2); (iii) an isobaric reduction in volume to to the state (P2, V₁); (iv) an isochoric increase in pressure back to the original state (P1, V₁). A) What work is done on the gas in this cycle? B) If P1 = 3.0 atm, P₂ = 1.0 atm, V₁ = 1.0 L and V₂ = 2.0 L, how much work is done on the gas in traversing the cycle 100 times?
An ideal gas undergoes the following reversible cycle: (i) an isobaric expansion from state (P1, V₁) to the state (P1, V2); (ii) an isochoric reduction in pressure to the state (P2, V2); (iii) an isobaric reduction in volume to to the state (P2, V₁); (iv) an isochoric increase in pressure back to the original state (P1, V₁). A) What work is done on the gas in this cycle? B) If P1 = 3.0 atm, P₂ = 1.0 atm, V₁ = 1.0 L and V₂ = 2.0 L, how much work is done on the gas in traversing the cycle 100 times?
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Transcribed Image Text:An ideal gas undergoes the following reversible cycle: (i) an isobaric expansion from state (P1, V₁) to the state (P1, V2);
(ii) an isochoric reduction in pressure to the state (P2, V2); (iii) an isobaric reduction in volume to to the state (P2, V₁);
(iv) an isochoric increase in pressure back to the original state (P1, V₁).
A)
What work is done on the gas in this cycle?
B)
If P1 = 3.0 atm, P₂ = 1.0 atm, V₁ = 1.0 L and V₂ = 2.0 L, how much work is done on the gas in traversing the
cycle 100 times?
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