Electrochemistry - The relationship between chemical processes and electricity oxidation – something loses electrons reduction – something gains electrons.

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Presentation transcript:

electrochemistry - The relationship between chemical processes and electricity oxidation – something loses electrons reduction – something gains electrons

Electrolytic process – an electrochemical process that requires the continual, external input of electrical energy to drive a nonspontaneous redox reaction Two fundamental types of electrochemical processes 2. Voltaic (or galvanic) processes – (spontaneous) 1. Electrolytic processes – (nonspontaneous)

electrolytic cells – the containers in which the electrolysis occurs electrodes – the actual surfaces where oxidation and reduction physically occur cathode – electrode where the process of reduction occurs anode – electrode where the process of oxidation occurs

B-36 Peacemaker gross weight = 410,000 lbs each B-36 had 22,000 lbs Mg

positively charged negatively charged voltage source anode cathode cell contains molten MgCl 2 ( )…. (which is Mg 2+ and 2 Cl - ) Mg 2+ migrates toward the cathode Cl - migrates toward the anode

voltage source positively charged negatively charged anode cathode (reduction) Cl - cathode: Mg 2+ Mg + 2 e - anode: Cl e - (oxidation) Mg 2+ 2 e Cl - Mg + Cl e -

Michael Faraday 1791 – 1867 “The amount of chemical change that occurs during electrolysis is directly proportional to the amount of electricity that passes through the cell”

Coulomb, C – SI unit of charge C = (amps) (sec) 1 mole e - = C ampere, amp – SI unit of electrical current

How many grams of elemental magnesium, Mg (s) can be produced by the electrolysis of molten MgCl 2 ( ) with an electrical current of 6.00 amps for 2222 seconds ? 1. Write the ½ reaction of interest 2. If possible, get Coulombs, C

What current, in amps, is required to produce 45.5 g of elemental chlorine, Cl 2 (g) from a melt of NaCl ( ) if electrolyzed for 2 hours, 15 minutes and 25 seconds ?

Voltaic process – an electrochemical cell which generates an electrical current from a spontaneous chemical redox process Two fundamental types of electrochemical processes 2. Voltaic (or galvanic) processes – (spontaneous) 1. Electrolytic processes – (nonspontaneous)

John Daniell 1790 – 1845 Daniell and Faraday

Zn + Cu 2+ Zn 2+ + Cu(spontaneous)

salt bridge – any medium that allows the flow of ions but prevents the direct mixing of solutions Cu e - Cu Zn Zn e - Zn + Cu 2+ Zn 2+ + Cu

Voltage (or Potential) – the force pushing the electrons Alessandro Volta 1745 – 1827

Zn + Cu 2+ Zn 2+ + Cu standard half-cell potential – voltage required to undergo a ½ reaction redox process E° red – voltage of “reduction ½ reaction” process E° ox – voltage of “oxidation ½ reaction” process standard conditions – 25  C and 1 atm and all solutions are 1 M

Cu e - Cu Zn Zn e - Zn + Cu 2+ Zn 2+ + Cu 2 e - + Zn + Cu 2+ Zn 2+ + Cu + 2 e - E° red = E° ox = V V Overall Cell Potential, E° cell – sum of the ½ cell reaction potentials E° cell = (E° red + E° ox )

Zn + Cu 2+ Zn 2+ + Cu Cu e - Cu E° red = V Zn Zn e - E° ox = V E° cell = (E° red + E° ox ) E° cell = 0.34 V V E° cell = V E° cell is often called “standard overall cell potential” or “electromotive force” or “EMF”

E° cell is very significant as it is the thermodynamic driving force for electrochemical processes When E° cell is positive (E° cell = + # V), electrochemical process is spontaneous When E° cell is negative (E° cell = – # V), electrochemical process is nonspontaneous

1. Determine the E° cell for the reaction and 2. Can a Voltaic cell be constructed using the reaction ? Fe 2+ + Al Fe + Al 3+ Voltage is an Intensive property

Relationship between E° cell and ΔG° rxn ΔG° rxn = – (n) (F) (E° cell ) ΔG° rxn is the standard Gibbs free energy n = smallest integer number of electrons transferred in the overall, balanced redox rxn F = Faraday constant = 96,485 C E° cell = the standard overall cell potential or EMF

3 Fe Al 3 Fe + 2 Al 3+ Determine ΔG° rxn for the following reaction E° cell = V

ΔG° rxn = – RT (ln K) R = J/mole∙K T = Temperature in Kelvin K = the equilibrium constant at standard conditions Fe 3+ + Pt Fe 2+ + Pt 2+ Determine E° cell, ΔG° rxn and K for the following rxn

Fe 3+ + e - Fe 2+ 2 e Fe 3+ + Pt 2 Fe 2+ + Pt e - E° red = V Pt Pt e - E° ox = V Fe 3+ + Pt Fe 2+ + Pt 2+ [] 2 Fe e - 2 Fe 2+ E° red = V E° cell = V 2 This electrochemical process is nonspontaneous