TransWikia.com

Sign of change in enthalpy and change in entropy

Chemistry Asked on December 6, 2021

Why is it wrong to assert that the change in entropy and the change in enthalpy must always have the same sign?

What makes me think that they must have the same sign is the fact that every reaction invariably comes to equilibrium under suitable conditions; and so we have the corresponding temperature equal to $ΔH/ΔS$ (setting $∆G = 0$ in the equation $ΔG = ΔH – TΔS).$

One Answer

TL;DR

In general the entropy of reaction can be written as

$$ TDelta _r S= Delta_r H + RTlog left(frac{Q_e}{Q}right) $$

At equilibrium $Q_e=Q$ and

$$ TDelta _r S_e= Delta_r H $$


Consider a simple reaction that behaves ideally (occurs under ideal solution conditions).

If it is carried out at constant T and p we can write

$$Delta_r G = Delta_r G^circ + RT log Q tag{1}$$

where Q is the reaction quotient.

But we can also write that

$$Delta_r G = Delta_r H - TDelta_r Stag{2a}$$

and

$$Delta_r G^circ = Delta_r H^circ - TDelta_r S^circtag{2b}$$

Equation (1) can then be written as

$$Delta_r G = Delta_r H^circ - T(Delta_r S^circ-R log Q) tag{3}$$

Matching terms in equations (2a) and (3) we have that

$$Delta_r H = Delta_r H^circ tag{4a}$$

and

$$Delta_r S = Delta_r S^circ - Rlog Q tag{4b}$$

When the reaction is at equilibrium $Q=Q_e$ (the reaction quotient is then equal to the equilibrium constant, here written $Q_e$) and $Delta_r G = 0$ which means, combining equations (2a) and (4a) that

$$ TDelta _r S_e = Delta _r H^ circ tag{5} $$

and

$$ TDelta _r S^ circ = TDelta_r S_e + RTlog Q_e tag{6}$$

so that

$$ TDelta _r S= TDelta_r S_e + RTlog Q_e - RTlog Q tag{7a} $$

or

$$ TDelta _r S= Delta_r H ^circ + RTlogleft(frac{Q_e}{Q}right) tag{7b} $$

Now compare equations (5) and (7b). Equation (5) holds at equilibrium and says, sure enough, that the reaction entropy and enthalpy are equal in sign at this point in the reaction coordinate. However, equation (7b) - which is the more general expression - says that $Delta_r S$ can in fact differ in sign from $Delta_r H^circ$, depending on the magnitude of the reaction quotient Q. It turns out that while the enthalpy of a reaction in an ideal solution is a constant, the entropy of reaction can be tuned by modifying Q.

Answered by Buck Thorn on December 6, 2021

Add your own answers!

Ask a Question

Get help from others!

© 2024 TransWikia.com. All rights reserved. Sites we Love: PCI Database, UKBizDB, Menu Kuliner, Sharing RPP