is as follows: Zn (s) + Cl2 (g, 1 atm.) →ZNCI2 (aq) a) Write the reaction that takes place in each half-cell. E and Zn"/Zn = -0.763 V %3! EvzCı,/cr =1.36 V calculate the standard potential, E°cell, b) Being and AGº. c) It the molality of the electrolyte ZnCl2 is of 0.1 m, employ the Debye-Hückel law for calculating the average ionic activity coefficient (y+), the average ionic activity (a±) and the electrolyte's activity (a2) d) Calculate the cell potential (Ecell), at 25 °C, using the values obtained in the previous section.

The Zn-Cl battery has been suggested as an energy generator in transportation. The reaction
is as follows:
Zn (s) + Cl₂ (g, 1 atm.) ZnCl₂ (aq)
a) Write the reaction that takes place in each half-cell.
b) Being and , calculate the standard potential, Eºcell,
and ∆G⁰.
c) It the molality of the electrolyte ZnCl₂ is of 0.1 m, employ the Debye-Hückel law for calculating the average ionic activity coefficient (γ±), the average ionic activity (a±) and the
electrolyte’s activity (a₂)
d) Calculate the cell potential (Ecell), at 25 °C, using the values obtained in the previous section. 

Transcribed Image Text:

is as follows: Zn (s) + Cl2 (g, 1 atm.) →ZnCl2 (aq) a) Write the reaction that takes place in each half-cell. E'. b) Being V2C1,/cr and AGº. =1.36 V E = -0.763 V Zn²"/Zn calculate the standard potential, E°cell, and c) It the molality of the electrolyte ZnCl2 is of 0.1 m, employ the Debye-Hückel law for calculating the average ionic activity coefficient (y=), the average ionic activity (a±) and the electrolyte's activity (a2) d) Calculate the cell potential (Ecell), at 25 °C, using the values obtained in the previous section.