1) Calculate the standard cell potential (E∘) for the reaction X(s)+Y+(aq)→X+(aq)+Y(s) if K = 1.12×10−3. 2)Calculate...

Calculate the standard cell potential at 25 ∘C for the reaction X(s)+2Y+(aq)→X2+(aq)+2Y(s) where ΔH∘ = -793...

Calculate the standard cell potential at 25 ∘C for the reaction X(s)+2Y+(aq)→X2+(aq)+2Y(s) where ΔH∘ = -793 kJ and ΔS∘ = -143 J/K .

Calculate the standard cell potential at 25 ∘C for the reaction X(s)+2Y+(aq)→X2+(aq)+2Y(s) where ΔH∘ = -597...

Calculate the standard cell potential at 25 ∘C for the reaction X(s)+2Y+(aq)→X2+(aq)+2Y(s) where ΔH∘ = -597 kJ and ΔS∘ = -337 J/K

Calculate the standard cell potential (E∘) for the reaction X(s)+Y+(aq)→X+(aq)+Y(s) if K = 2.71×10−3.

Calculate the standard cell potential (E∘) for the reaction X(s)+Y+(aq)→X+(aq)+Y(s) if K = 2.71×10−3.

Calculate the standard cell potential (E∘) for the reaction X(s)+Y+(aq)→X+(aq)+Y(s) if K = 6.43×10^−3. Express your...

Calculate the standard cell potential (E∘) for the reaction X(s)+Y+(aq)→X+(aq)+Y(s) if K = 6.43×10^−3. Express your answer numerically in volts.

± Cell Potential and Free Energy Free-energy change, ΔG∘, is related to cell potential, E∘, by...

± Cell Potential and Free Energy Free-energy change, ΔG∘, is related to cell potential, E∘, by the equation ΔG∘=−nFE∘ where n is the number of moles of electrons transferred and F=96,500C/(mol e−) is the Faraday constant. When E∘ is measured in volts, ΔG∘ must be in joules since 1 J=1 C⋅V. Part A Calculate the standard free-energy change at 25 ∘C for the following reaction: Mg(s)+Fe2+(aq)→Mg2+(aq)+Fe(s) Express your answer to three significant figures and include the appropriate units. Part B...

For a certain reaction,   ΔH°=−14.6   kJ  and   ΔS°=−233  J/K.  If  n=2,  calculate  E°cell  for the reaction...

For a certain reaction,   ΔH°=−14.6   kJ  and   ΔS°=−233  J/K.  If  n=2,  calculate  E°cell  for the reaction at  25°C. a. −0.284 V b. 0.0961 V c. −0.130 V d. 0.736 V e. 0.0654 V

Calculate the standard potential, E°, for this reaction from its equilibrium constant at 298 K. X(s)...

Calculate the standard potential, E°, for this reaction from its equilibrium constant at 298 K. X(s) + Y^2+(aq)----->X^2+(aq) + Y(s) K=6.11x10^-5 <--------

1.      Calculate the standard free energy change at 500 K for the following reaction. Cu(s) +...

1.      Calculate the standard free energy change at 500 K for the following reaction. Cu(s) + H2O(g) à CuO(s) + H2(g) ΔH˚f (kJ/mol) S˚ (J/mol·K) Cu(s)    0    33.3    H2O(g)    -241.8    188.7    CuO(s)    -155.2    43.5    H2(g)     0    130.6 2.      When solid ammonium nitrate dissolves in water, the resulting solution becomes cold. Which is true and why? a.      ΔH˚ is positive and ΔS˚ is positive b.      ΔH˚ is positive and ΔS˚...

Consider the cell: Hg(l) ׀ Hg2SO4(s) ׀ FeSO4(aq) ׀ Fe(s) The standard cell potential (E θ...

Consider the cell: Hg(l) ׀ Hg2SO4(s) ׀ FeSO4(aq) ׀ Fe(s) The standard cell potential (E θ ) for the reduction of Fe2+ is -0.447 V and the standard cell potential for the reduction of Hg2SO4(s) is +0.6125 V. (a) Write the cell reaction. (b) If the activity of FeSO4(aq) is 0.0100, calculate the cell potential and the standard Gibbs energy at 25°C.

1) Given the following thermochemical reaction and thermodynamic data, find Gibbs Free Energy, ΔG, and determine...

1) Given the following thermochemical reaction and thermodynamic data, find Gibbs Free Energy, ΔG, and determine if the reaction is spontaneous or non-spontaneous at 25 °C? N2(g) + 3H2(g) → 2NH3(g) ΔH = -91.8 kJ ΔS[N2] = 191 J / mol · K, ΔS[H2] = 131 J / mol · K, and ΔS[NH3] = 193 J / mol · K a.98.3 kJ; Non-Spontaneous b.-98.3 kJ; Spontaneous c.32.7 kJ; Non-Spontaneous d.ΔG = -32.7 kJ; Spontaneous 2) What is the oxidation number...