Given the following hypothetical reactions and ΔG°rxn's, calculate the ΔG°rxn in kilojoules per mole for the final reaction.
A(g) + 12X2(g) → AX(g) ΔG°rxn = -119.2 kJ/mol
ZX4(g) → Z(g) + 2X2(g) ΔG°rxn = 427.6 kJ/mol
JX3(g) + 3AX(g) → JA3(g) + 3X2(g) ΔG°rxn = -472.2 kJ/mol
Z(g) + 4AX(g) → ZX4(g) + 4A(g) ΔG°rxn = ??? kJ/mol
Given the following hypothetical reactions and ΔG°rxn's, calculate the ΔG°rxn in kilojoules per mole for the...
Given the following equation, N2O(g) + NO2(g) → 3 NO(g) ΔG°rxn = -23.0 kJ Calculate ΔG°rxn for the following reaction. 18 NO(g) → 6 N2O(g) + 6 NO2(g) -3.83 kJ -23.0 kJ 138 kJ -138 kJ 23.0 kJ
Given the following equation, N2O(g) + NO2(g) → 3 NO(g) ΔG°rxn = -23.0 kJ Calculate ΔG°rxn for the following reaction. 18 NO(g) → 6 N2O(g) + 6 NO2(g) -3.83 kJ -138 kJ 23.0 kJ -23.0 kJ 138 kJ
Using values of ΔG°f, calculate ΔG°rxn for the following reaction. Is the reaction product-favored or reactant-favored? SiCl4(g) + 2 Mg(s) → 2 MgCl2(s) + Si(s) ΔG°f (kJ/mol) HgS(s) -50.6 SO2(g) -300.13 H2S(g) -33.56 H2O(ℓ) -228.59 SiCl4(g) -622.76 MgCl2(s) -591.59 ____ kJ/mol? product-favored or reactant-favored?
CHEM-1220:
hemical Thermodynamics Coupled Reactions Resources « previous| 10 of 13 next >» Coupled Reactions Part A Consider these hypothetical chemical reactions In nature, one common strategy to make thermodynamically unfavorable reactions proceed is to couple them chemically to reactions that are thermodynamically favorable. As long as the overall reaction is thermodynamically favorable even the unfavorable reaction will proceed 1. A-B, 2.B-C, 3, C D, ΔG= 13.0 kJ/mol ΔG=-26.2 kJ/mol ΔG= 7.70 kJ/mol What is the free energy, ΔG, for...
Calculate the energy change (in kilojoules per mole) for the formation of the following substances from their elements. CaF2 (The sublimation energy for Ca is +178.2 kJ/mol, Ei1 = +589.8 kJ/mol, Ei2 = +1145kJ/mol, and the lattice energy of CaF2 is 2630 kJ/mol.) Express the energy change in kilojoules per mole to four significant digits.
1. Use the data given to calculate the value of ΔG°rxn for the reaction at 25 °C. 2 C(graphite) + H2(g) <---> C2H2(g) C(graphite) H2(g) C2H2(g) S° (J/mol ⋅ K) 5.74 130.68 201.0 (kJ/mol) 0 0 −226.8 Report answer to four significant figures.
Calculate the net energy change in kilojoules per mole for the formation of KF(s) from the elements: K(s) + 1/2 F2(g) \rightarrow→KF(s). The following information is given: Heat of sublimation for K(s) = 89.2 kJ/mol, Eea for F(g) = –328 kJ/mol Bond dissociation energy for F2(g) = 158 kJ/mol, Ei for K(g) = 418.8 kJ/mol Electrostatic interactions in KF(s) = –821 kJ/mol
Use the following data to calculate the value of ΔG°rxn at 298 K for the reaction described by the given chemical equation. Include the units. Compound S°f (J/molK) DH°f (kJ/mol) CO (g) 197.7 –110.5 H2 (g) 130.7 0 CH4 (g) 186.3 –74.6 H2O (g) 188.8 –241.8 CO (g) + 3H2 (g) → CH4 (g) + H2O (g) I got -141.9 KJ/mol, but i think the units are wrong and I don't know why.
Constants | Periodic Table Calculate ΔG∘rxn and K for each of the following reactions. Part A The reaction of Cr3+(aq) and Cr(s) to form Cr2+(aq). [The reduction potential of Cr2+(aq) to Cr(s) is -0.91 V.] Calculate ΔG∘rxn.
Calculate the ΔG°rxn using the following information. 2 HNO3(aq) + NO(g) → 3 NO2(g) + H2O(l) ΔG°rxn = ? ΔG°f (kJ/mol) -110.9 87.6 51.3 -237.1