Deck 20: Electrochemistry

A) When a half reaction is reversed, the sign of the potential is changed.
B) Reversing a half reaction makes it a reduction potential.
C) Each electrochemical cell consists of a reduction half cell and an oxidation half cell.
D) A voltaic cell is also called a battery.
E) The potential difference of a cell is the voltage of the cell.

A) A double vertical line separates half cells in a cell diagram.
B) A single vertical line separates phases in a cell diagram.
C) A voltaic cell is a galvanic cell.
D) Voltaic cells produce an electron flow.
E) Electrolytic cells are cells where electron flow is caused by spontaneous reactions.

A) An electrode is often a strip of metal.
B) An electrode in a solution of its ions is a half cell.
C) An electrochemical cell is a half cell.
D) The electromotive force (emf) is the cell potential.
E) The cell potential is the potential difference between the half cells.

A) SHE stands for Standard Helium Electrodes.
B) E° is the standard electrode potential.
C) The standard electrode potential is the reduction potential of a half cell.
D) The standard cell potential is the potential difference between two half cells.
E) E°cell is the standard cell potential.

A) anode
B) cathode
C) salt bridge
D) electrolyte
E) in cathodic space

A) Electrons are transferred in oxidation-reduction reactions.
B) A strip of metal in a solution of ions of that metal is an electrode potential.
C) Reduction is the gain of electrons.
D) Oxidation is the loss if electrons.
E) A salt bridge maintains electrical contact between two half cells.

A) The zinc electrode is the cathode.
B) The reaction will go in the direction indicated.
C) The shorthand notation is Zn ∣ Zn2+  Pb2+ ∣ Pb
D) The actual cell voltage is less than +0.637 volts because of concentration polarization and possible other factors.
E) The lead electrode is positively charged.

A) Mg will not displace Zn2+ from solution
B) Cu will displace Sn2+ from solution
C) Fe will displace Zn2+ from solution
D) Fe will displace H+ from solution
E) Sn will displace Fe2+ from solution

A) A cell diagram is a symbolic way to show cell components.
B) An anode is where oxidation occurs.
C) A cathode is where reduction occurs.
D) Half cells in a cell diagram are separated by a single vertical line.
E) The anode is on the left in a cell diagram.

A) A concentration cell consists of half cells with identical electrodes but different ion concentrations.
B) Primary batteries' cell reactions cannot be reversed.
C) Secondary batteries' cell reaction can be reversed.
D) A primary battery is recharged by passing electricity through the battery.
E) Cells can be joined in series to increase the total voltage.

A) 0.638 V
B) -0.638 V
C) 0.888 V
D) -1.276 V
E) -0.888 V

A) 8 × 10-9
B) 9 × 10-5
C) 2 × 10-17
D) 5 × 10-13
E) 6 × 10-5

A) nonspontaneous
B) slow
C) exothermic
D) spontaneous
E) fast

A) One mole of hydrogen ions will have a positive charge of one Faraday.
B) One Faraday of charge will release 35.5 g of Cl2 in the electrolysis of a chloride solution.
C) One Faraday of charge will plate out two moles of Cu from a solution of CuSO4(aq).
D) One mole of electrons has a charge of l Faraday.
E) One mole of hydrogen gas requires 2 Faradays.

A) No, Mg(s) does not react with Ag+.
B) No, E° is a positive value.
C) No, E° is a negative value.
D) Yes, E° is a positive value.
E) Yes, E° is a negative value.

A) 2.8 × 10-3 M
B) 1.6 × 10-5 M
C) 4.5 × 10-5 M
D) 2.4 × 10-2 M
E) 7.8 × 10-6 M

A) pH
B) pKa
C) Ksp
D) Q
E) pKw

A) 2 × 10-2 M
B) 1 M
C) 4 × 10-42 M
D) 0.05 M
E) 0.4 M

A) Li+/Li couple
B) Co3+/Co2+ couple
C) Co(III)/Co(IV) couple
D) both Li+/Li and Co3+/Co2+
E) both Li+/Li and Co(III)/Co(IV)

A) Corrosion of metals is an oxidation reduction process.
B) Rust is a form of corrosion.
C) Metals can be protected by cathodic protection.
D) Cathodic protection is attaching a more active metal to the protected metal.
E) The active metal is called a sacrificial cathode.

A) Fe2+(aq) ∣ Fe3+(aq)  Zn2+(aq) ∣ Zn(s)
B) Pt(s) ∣ Fe2+(aq), Fe3+(aq)  Zn2+(aq) ∣ Zn(s)
C) Zn(s) ∣ Zn2+(aq)  Fe3+(aq) ∣ Fe2+(aq) ∣ Pt(s)
D) Zn(s) ∣ Zn2+(aq)  Fe3+(aq) ∣ Fe2+(aq)
E) Zn(s) ∣ Zn2+(aq)  Fe3+(aq) ∣ Fe2+(aq) ∣ Zn(s)

A) Halve [Cu2+].
B) Halve [Fe2+].
C) Double [Cu2+].
D) Double [Fe2+].
E) Cut Cu electrode in half.

A) I) and V)
B) II) and IV)
C) I) and IV)
D) II) and III)
E) I) and III)

A) 0.913 V
B) -2.439 V
C) 2.439 V
D) -1.063 V
E) -0.913 V

A) 0.6 M
B) 1 × 10-2 M
C) 1 × 10-6 M
D) 9 × 10-4 M
E) 4 × 10-4 M

A) 0.756 V
B) -0.756 V
C) 3.156 V
D) -1.556 V
E) 1.556 V

A) The work available in a cell = -zFEcell.
B) ΔG° = -zFE°cell
C) When Ecell < 0, the reaction is spontaneous.
D) When Ecell = 0, the reaction is at equilibrium.
E) Reversing a cell reaction changes the sign of Ecell.

A) 1 × 10-2
B) 0.771
C) 4 × 1011
D) 5 × 10-10
E) 4 × 10-11

A) 5.7 × 10106
B) 2.0 × 1053
C) 3.7 × 1052
D) 1.1 × 1027
E) 10-107

A) 0.730 V
B) -0.875 V
C) 0.875 V
D) 0.195 V
E) -0.195 V

A) 5.90 × 103 C
B) 2.95 × 103 C
C) 1.47 × 103 C
D) 3.39 × 10-4 C
E) 1.69 × 10-4 C

A) Cu to plate out on the negative electrode
B) Cu to plate out on the anode
C) oxygen to form on the negative electrode
D) H2 to form at the negative electrode
E) sulfur to form on the positive electrode

A) 2.941 V
B) -1.813 V
C) 1.813 V
D) -1.539 V
E) 1.539 V

A) 0.215 V
B) 0.465 V
C) 0.930 V
D) -0.215 V
E) -0.465 V

A) 96,485 A
B) 1.60 × 10-19
C) 6.02 × 1023 A
D) 96,485 C
E) 96,485 F

A) Ti(s) + Se2-(aq) + 1 e- → Ti3+(aq) + Se(s)
B) 2 Ti(s) + 3 Se(s) → 2 Ti3+(aq) + 3 Se2-(aq)
C) Ti(s) + Se(s) → Ti3+(aq) + Se2-(aq) + 1 e-
D) 2 Ti3+(aq) + 3 Se(s) → 2 Ti(s) + 3 Se2-(aq)
E) 2 Ti3+(aq) + 3 Se(s) + 1 e- → 2 Ti(s) + 3 Se2-(aq)

A) Ag(s) | Ag(aq)  Mg2+(aq) | Mg(s)
B) Mg(s) ∣ Mg2+  Ag+ (aq) ∣ Ag (s)
C) Mg(s) ∣ Mg2+  Ag(s) ∣ Ag+ (aq)
D) Ag(aq) ∣ Ag(s)  Mg(s) ∣ Mg2+ (aq)
E) Ag(s) ∣ Mg2+ (aq)  Ag+ (aq) ∣ Mg(s)

A) 1.45 × 107 C
B) 1.56 × 106 C
C) 1.45 × 104 C
D) 2.41 × 104 C
E) 1.56 × 104 C

A) 2.50 volts
B) 0.417 volts
C) -1.08 volts
D) 1.08 volts
E) -0.40 volts

A) Pb(s) + Zn(s) → Pb+2(aq) + Zn+2(aq) + 4 e-
B) Pb(s) + Zn+2(aq) → Pb+2(aq) + Zn(s)
C) Pb+2(s) + Zn+2(s) → Pb(s) + Zn(s) + 4 e-
D) Pb+2(aq) + Zn(s) → Zn+2(aq) + Pb(s)
E) Pb(s) + Zn(s) + 4 e- → Pb+2(aq) + Zn+2(aq)

A) No, since E°cell is negative.
B) Yes, since E°cell is negative.
C) No, the reverse reaction is spontaneous.
D) Yes, since E°cell is positive.
E) No, the system is at equilibrium.

A) 3.016 V
B) -4.224 V
C) 1.508 V
D) 4.224 V
E) -1.508 V

A) 0.756 V
B) -0.756 V
C) 3.156 V
D) -3.156 V
E) 1.556 V

A) 1.556 V
B) -3.156 V
C) 3.156 V
D) 0.800 V
E) 2.356 V

A) 0.212 V
B) -0.462 V
C) 0.462 V
D) -0.212 V
E) 0.424 V

A) ...a direct current must be used."
B) ...oxygen is evolved at the cathode."
C) ...electrical energy must be supplied continuously because it is an endothermic reaction."
D) ...the volume of hydrogen produced is twice the volume of oxygen produced."
E) ....one mole of H₂ is produced for each two moles of electrons."

A) -2.34 V
B) -2.28 V
C) 2.28 V
D) -0.74 V
E) 0.74 V

A) 0.913 V
B) -2.439 V
C) 2.439 V
D) -1.063 V
E) -0.913 V

A) 0.638 V
B) -0.638 V
C) 0.888 V
D) -1.276 V
E) -0.888 V

A) +0.463 V
B) -0.926 V
C) -0.463 V
D) +0.926 V
E) +0.231 V

A) -210 kJ
B) -140 kJ
C) -700 kJ
D) -463 kJ
E) -420 kJ

A) 10-6
B) 105
C) 1010
D) 10-11
E) 1061

A) 1.372 V
B) 1.707 V
C) 1.646 V
D) 1.433 V
E) -1.646 V

A) Zn2+(aq) ∣ Zn(s), H+(aq)  Cr2O72-(aq), Cr(s) ∣ Cr3+(aq)
B) Zn(s) ∣ Zn2+(aq)  H+(aq), Cr3+(aq) ∣ Cr(s)
C) Cr(s) ∣ Cr3+(aq), H+(aq), Cr2O72-(aq)  Zn(S) ∣ Zn2+(aq)
D) Zn(s) ∣ Zn2+(aq)  Cr2O72-(aq), H+(aq), Cr3+(aq) ∣ Pt(s)
E) Pt(s) ∣ Cr3+(aq), Cr2O72-(aq), H+(aq)  Zn2+(aq) ∣ Zn(s)

A) -10.92 V
B) 10.92 V
C) 21.85 V
D) -1.092 V
E) 1.092 V

A) +0.257 V
B) -0.257 V
C) 0.000 V
D) +0.0844 V
E) +0.0422 V

A) 2 Br- + Zn2+ → Zn + Br2
B) Br2 + Zn → Zn2+ + 2 Br-
C) 2 Br- + Zn → Br2 + Zn2+
D) Br2 + Zn → Zn2+ + Br-
E) Br2 + Zn2+ → Zn + 2Br-

A) -105 kJ
B) -211 kJ
C) 105 kJ
D) -2107 kJ
E) 211 kJ

A) 2.16 V
B) -2.16 V
C) -0.56 V
D) 0.56 V
E) 1.36 V

A) -1.83 V
B) 0.31 V
C) 1.83 V
D) -0.31 V
E) -0.76 V

A) 1.227 V
B) 1.611 V
C) 1.562 V
D) 1.487 V
E) 1.467 V

A) +0.154 V
B) -0.154 V
C) +1.45 V
D) -1.45 V
E) +0.308 V

A) Pt ∣ Cl2(g) ∣ Cl-(aq)  Sn2+(aq) ∣ Sn(s)
B) Sn(S) ∣ Sn2+(aq)  Cl-(aq) ∣ Cl2(g) ∣ Pt
C) Cl2(g) ∣ Cl-(aq)  Sn2+(aq) ∣ Sn(s)
D) Sn(S)  Sn2+(aq)  Cl-(aq) ∣ Cl2(g)
E) Sn(S) ∣ Cl-(aq)  Sn2+(aq) ∣ Sn(s)

A) 2 × 1069
B) 2 × 10-16
C) 2 × 1016
D) 2 × 10-8
E) 6 × 107

A) 1073
B) 10-10
C) 109
D) 1019
E) 10-19

A) 1 and 4
B) 2 and 4
C) 3 and 4
D) 1 and 3
E) 2 and 3

A) 0.65 V
B) 0.38 V
C) 0.74 V
D) 0.92 V
E) 0.20 V

A) 3 × 10-19
B) 2 × 1037
C) 2 × 10-37
D) 3 × 1018
E) 3 × 10-18

A) -300.3 kJ/mol
B) 304.5 kJ/mol
C) 609.0 kJ/mol
D) -304.5 kJ/mol
E) -609.0 kJ/mol