The entropy changes; ΔS s u r r and ΔS t o t a l for a gas that undergoes reversible adiabatic expansion from an initial temperature of 298 K and 450 bar until the final pressure is 1/3 its initial value needs to be deduced. Concept Introduction: The entropy change associated with a reversible process is given as a ratio of the heat transferred (q r e v ) at a given temperature T ΔS = q rev T -----(1) The total entropy change is given as a sum of the entropy change of the system and surroundings ΔS = ΔS system +ΔS surr ------(2) A given process is spontaneous if the entropy change is positive i.e. ΔS < 0, spontaneous process

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Chapter 5, Problem 5.32NP

(a)

Interpretation Introduction

Interpretation:

The entropy changes; ΔS_s_u_r_r and ΔS_t_o_t_a_lfor a gas that undergoes reversible adiabatic expansion from an initial temperature of 298 K and 450 bar until the final pressure is 1/3 its initial value needs to be deduced.

Concept Introduction:

The entropy change associated with a reversible process is given as a ratio of the heat transferred (q_r_e_v) at a given temperature T

ΔS = qrevT -----(1)

The total entropy change is given as a sum of the entropy change of the system and surroundings

ΔS = ΔSsystem+ΔSsurr ------(2)

A given process is spontaneous if the entropy change is positive

i.e. ΔS < 0, spontaneous process

(b)

Interpretation Introduction

Interpretation:

The entropy changes; ΔS_s_u_r_r and ΔS_t_o_t_a_l for a gas that undergoes adiabatic expansion from an initial temperature of 298 K and 450 bar against a constant external pressure of 1.50 bar unit the final pressure is 1/3 the initial value needs to be deduced

Concept Introduction:

For an ideal gas, the entropy change associated with anirreversible process from initial pressure and temperature P₁,T₁ to a final state with P₂, T₂ is given as

ΔS = −nRlnP2P1 + nCplnT2T1 -----(4)

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