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CHAPTER 19 SECTION 6 FREE ENERGY AND TEMPERATURE.

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Presentation on theme: "CHAPTER 19 SECTION 6 FREE ENERGY AND TEMPERATURE."— Presentation transcript:

1 CHAPTER 19 SECTION 6 FREE ENERGY AND TEMPERATURE

2 ΔG = ΔH - TΔS = ΔH + (-TΔS) Enthalpy Entropy Notice that the expression for ΔG is a sum of two contributions, an enthalpy term (ΔH) and an entropy term (-TΔS). Because the value of -TΔS depends directly on the absolute temperature T, ΔG will vary with temperature. T is a positive value at all temperatures (Kelvin!). Enthalpy (ΔH) can be positive or negative. Entropy (-TΔS) can also be positive or negative.

3 When ΔS is positive, which means the final state has greater disorder (a greater number of microstates) than the initial state, the term -TΔS is negative. When ΔS is negative, the term -TΔS is positive. The sign of ΔG, which tells us whether a process is spontaneous, will depend on the signs and magnitudes of ΔH and -TΔS. When both ΔH and -TΔS are negative, ΔG will always be negative and the process will be spontaneous at all temperatures (exothermic).

4 Likewise, when both ΔH and -TΔS are positive, ΔG will always be positive and the process will be nonspontaneous at all temperatures. When ΔH and -TΔS have opposite signs, the sign of ΔG will depend on the magnitudes of the two terms. Generally, ΔH and ΔS change very little with temperature. However, the value of T directly affects the magnitude of -TΔS which increases with an increase in temperature and becomes more important in determining the sign and magnitude of ΔG.

5 Let’s consider once more the melting of ice to liquid water at 1 atm pressure: H 2 O (s)  H 2 O (l) ΔH > 0, ΔS > 0 This process is endothermic, which means ΔH is positive. We also know that entropy increases during this process, so ΔS is positive and -TΔS is negative. At temperatures below 0 o C the magnitude of ΔH is greater than that of -TΔS. Hence, the positive enthalpy term dominates, leading to a positive value for ΔG.

6 The positive value of ΔG means that the melting of ice is not spontaneous at T < 0 o C, rather, the reverse process, the freezing of liquid water into ice, is spontaneous at these temperatures. As the temperature increases, the magnitude of the entropy term -TΔS increases. When T > 0 o C, the magnitude of -TΔS is greater than ΔH. At these temperatures the negative entropy term dominates, which leads to a negative value for ΔG.

7 The negative value of ΔG tells us that the melting of ice is spontaneous at T > 0 o C. At the normal melting point of water, T = 0 o C, the two phases are at equilibrium. Recall that ΔG = 0 at equilibrium; at T = 0 o C, ΔH and -TΔS, are equal in magnitude and opposite in sign, so they cancel one another and give ΔG = 0. See Table 19.4 for a summary

8 ΔH ΔS -T ΔS ΔG = ΔH - TΔS Reaction Characteristics _ + _ _ Spontaneous at all temp’s. + _ + + Non-spont. at all temp’s. _ _ + + or - Spont. at low T Non-spont. at high T + + _ + or - Spont. at high T Non-spont. at low T

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