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(C) The given reactions are:$(i) 2 Cu_{(s)} + 1/2 O_{2(g)} \longrightarrow Cu_2O_{(s)}; \Delta G_1^	heta = -78,000 \ J \ mol^{-1}$$(ii) H_{2(g)} + 1/

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(C) The given reactions are:$(i) 2 Cu_{(s)} + 1/2 O_{2(g)} \longrightarrow Cu_2O_{(s)}; \Delta G_1^	heta = -78,000 \ J \ mol^{-1}$$(ii) H_{2(g)} + 1/2 O_{2(g)} \longrightarrow H_2O_{(g)}; \Delta G_2^	heta = -1,78,000 \ J \ mol^{-1}$Subtracting $(ii)$ from $(i)$ gives the target reaction:$2 Cu_{(s)} + H_2O_{(g)} \longrightarrow Cu_2O_{(s)} + H_{2(g)}$$\Delta G^	heta = \Delta G_1^	heta - \Delta G_2^	heta = -78,000 - (-1,78,000) = 1,00,000 \ J \ mol^{-1}$To prevent oxidation,$\Delta G \ge 0$. At the threshold (minimum $p_{H_2}$):$\Delta G = \Delta G^	heta + RT \ln Q = 0$$1,00,000 + (8 	imes 1250) \ln \left( \frac{p_{H_2}}{p_{H_2O}} ight) = 0$$1,00,000 + 10,000 \ln \left( \frac{p_{H_2}}{p_{H_2O}} ight) = 0$$10 + \ln(p_{H_2}) - \ln(p_{H_2O}) = 0$$\ln(p_{H_2}) = \ln(p_{H_2O}) - 10$Given $p_{H_2O} = 1\% 	ext{ of } 1 \ 	ext{bar} = 0.01 \ 	ext{bar} = 10^{-2} \ 	ext{bar}$.$\ln(p_{H_2O}) = \ln(10^{-2}) = -2 \ln(10) = -2 	imes 2.3 = -4.6$.$\ln(p_{H_2}) = -4.6 - 10 = -14.6$.

List-$X$	List-$Y$
$(A)$ Active mass	$(i)$ $\Delta n = 0$
$(B)$ Equilibrium constant	$(ii)$ Molar concentration
$(C)$ $A + \text{Heat} \rightleftharpoons B$	$(iii)$ Van't Hoff equation
$(D)$ $2A_{(g)} + B_{(g)} \rightleftharpoons 3C_{(g)}$	$(iv)$ Favoured by increase in temperature
	$(v)$ Chemical equilibrium

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