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Question 5 (1 point) Transpose the following galvanic cell into cell notation. Anode: Iron metal in...
Question 6 (1 point) Transpose the following redox reaction into cell notation. Mg (s) + Pb2+ (aq) -- Mg2+ (aq) + Pb (s) O1 Mg (s)| Mg2+ (1 M) || Pb2+ (1 M) | Pb (s) || O I Mg (s) | NaNO3 (1 M) || NaNO3 (1 M) | Pb (s) O1 Pt (s)| Mg2+ (1 M) || Pb2+ (1 M) | Pt(s) O Pb (s) | Pb2+ (1 M) || Mg2+ (1 M) | Mg (s) || Question...
Questions Galvanic Cell Metal and Solution in Cathode Half-cell Cell Potential(v) Metal and Solution in Anode Half-cell Black Wire (-) Red Wire (+) -2.370 Pt/H2 and Nitric Acid Mg and Magnesium Nitrate #1 -0.143 Pt/ H2 and Nitric Acid Pb and Lead (II) Nitrate #2 -0.249 Pt/ H2 and Nitric Acid #3 Ni and Nickel (II) Nitrate 다 5. Based on your information above write the half reactions occurring in each half-cell. Ensure you are writing the correct oxidation or...
In a galvanic cell, one half-cell consists of a cobalt strip dipped into a 1.00 M solution of Co(NO3)2. In the second half-cell, solid niobium is in contact with a 1.00 M solution of Nb(NO3)3. Co is observed to plate out as the galvanic cell operates, and the initial cell voltage is measured to be 0.819 V at 25°C. (a) Write balanced equations for the half-reactions at the anode and the cathode. Show electrons as e-. Use the smallest integer...
Separate galvanic cells are made from the following half-cells: cell 1: H+(aq)/H2(g) and Pb2+(aq)/Pb(s) cell 2: Fe2+(aq)/Fe(s) and Zn2+(aq)/Zn(s) Which of the following is correct for the working cells? Standard reduction potentials, 298 K, Aqueous Solution (pH = 0): Cl2(g) + 2e --> 2C1-(aq); E° = +1.36 V Fe3+(aq) + e --> Fe2+(aq); E° = +0.77 V Cu2+(aq) + 2e --> Cu(s); E° = +0.34 V 2H+(aq) + 2e --> H2(g); E° = 0.00 V Pb2+(aq) + 2e --> Pb(s);...
Galvanic Cell Homework - Unanswered Dunhus Galvanic cell Using the electrochemical series, predict which species will be oxidized on Anode in a galvanic cell constructed of tin metal and a solution containing Fe3+ and Fe2+ ions. E° (Fe3+/Fe2+) = + 0.771 V E° (Sn2+/Sn(s)) = -0.141 V Click or tap on the species being oxidized on Anode. Fe3+ Fe2+ Sn2+ Sn(s) Targets placed: 0/2 You can place up to 2 targets LIICA U pon the stronger oxidant Which is the...
1. Consider a voltaic (galvanic) cell with the following metal electrodes. Identify which metal is the cathode and which is the anode, and calculate the cell potential. (Use the table of Standard Electrode Potentials.) a. Ag(I) and Zr(IV) Cathode: Anode: Ecell b. Cr(III) and Co(II) Cathode: Anode: Ecell c. In(III) and Au(III) Cathode: Anode: Ecell
Show all steps please :) A galvanic cell is prepared using the following two half-cells: (i) MnO4 (0.273 M), Mn2+ (0.167 M), and H+ (1.0 M), and (ii) Fe2+ (0.247 M) and Fe3+ (0.389 M). The standard reduction potentials for the two half cells are: Mnoa + 8H+ + 5e – Mn2+ + 4H20 E° = 1.507 V Fe3+ + e- Fe2+ E° = 0.770 V a) Calculate the voltage for this galvanic cell. b) Write the balanced equation for...
Consider a voltaic (galvanic) cell with the following metal electrodes. Identify which metal is the cathode and which is the anode, and calculate the cell potential. (Use the table of Standard Electrode Potentials.) (a) Ca(II) and Sc(III) Cathode: . Ca(II) Sc(III) Anode: Ca(II) Sc(III) Ecell = 0.0591 x V (b) Pb(II) and In(III) Cathode: . Pb(II) In(III) Anode: Pb(II) In(III) Ecell - (c) Ni(II) and Zr(IV) Cathode: NI(II) Zr(IV) Anode: Ni(II) Zr(IV) Ecell - V Supporting Materials Periodic Table Supplemental...
2. A standard state galvanic cell is constructed using the following half-reactions. Fe3+ (aq) + Fe2(aq) Fe2(aq) + 2e → Fe(s) a. Fill in the cell diagram. Label the anode, cathode, the reactants and products in each solu direction of electron flow through the wire, and ion flow through the salt bridge. (5 pts) KNO, Salt Bridge (+) electrode (-) electrode b. Calculate the concentration of each ion in the cell at equilibrium. (10 pts)
Sketch the galvanic cell based on a half-cell containing 0.1 M Cu(NO3)2 with a Cu(s) electrode and a half-cell containing 0.001 M Fe(NO3)2 with an Fe(s) electrode. Show the direction of electron flow and identify the cathode and the anode. Calculate Ecell and ∆G at 25 ◦C.