While performing Lab 11, Electrochemistry, students connected 1 M solutions of the following metals and used...
While performing Lab 11, Electrochemistry, students connected 1 M solutions of the following metals and used electrodes to monitor the cell potential. Using the table of theoretical values and what you know of the metals to fill in the blanks below. When writing equations: Use spaces only before and after a plus sign. For example, the reaction: Fe2+ + 2e - → Fe would be entered as: Fe^2+ + 2e. → Fe Galvanic Cell Consisting of: Zn²+ + 2e -...
While performing Lab 11, Electrochemistry, students connected 1 M solutions of the following metals and used electrodes to monitor the cell potential. Using the table of theoretical values and what you know of the metals to fill in the blanks below. When writing equations: Use spaces only before and after a plus sign. For example, the reaction: Fe2+ + 2e + Fe would be entered as: Fe^2+ + 2e^. ► Fe Galvanic Cell Consisting of: Cu2+ + 2e - Cu...
While performing Lab 11, Electrochemistry, students connected 1 M solutions of the following metals and used electrodes to monitor the cell potential. Using the table of theoretical values and what you know of the metals to fill in the blanks below. When writing equations: Use spaces only before and after a plus sign. For example, the reaction: Fe2++2e−→FeFe2++2e-→Fe would be entered as: Fe^2+ + 2e^- →→ Fe Galvanic Cell Consisting of: Al3++3e−Al3++3e- →→ AlAl -1.66 Mg2++2e−Mg2++2e- →→ MgMg -2.37 E0cell Measured...
While performing Lab 11, Electrochemistry, students connected 1 M solutions of the following metals and used electrodes to monitor the cell potential. Using the table of theoretical values and what you know of the metals to fill in the blanks below. When writing equations: Use spaces only before and after a plus sign. For example, the reaction: Fe2+ + 2e → Fe would be entered as: Fe^2+ + 2e. Fe Galvanic Cell Consisting of: Zn²+ + 2e Zn -0.76 +...
PART A: REDOX REACTIONS 1. For each of the metals, write the redox equations for reactions you observed in a table as shown below. Write NR for “no reaction” where none was observed. 2+ (**e.g., Cu + Zn → Cu + Zn , Ecell = 1.10 V) Cu(NO3)2 Pb(NO3)2 Zn(NO3)2 16 Cu(s) NR NR Pb(s) NR Zn(s) NR 2. Calculate the Eº for every cell, whether or not a reaction was observed, using equation (5) and values for the standard...
Candidate l: Zn(s) | Zn2+(aq,0.500 M) I Cu2+(aq, 1.00 M) Cu(s) Candidate 2: Pb(s) | Pb2+(aq, 0.500 M) || Cu2+(aq, 1.00 M) Cu(s) Candidate 3: Mg(s) | Mg2+(aq, 0.500 M) | Pb2+(aq, 1.00 M)| Pb(s) (a) 6 pts) Choose one of the candidate voltaic cells #1, #2, or #3. Draw a schematic cell diagram for the candidate voltaic cell of choice. Clearly label anode, cathode, electrodes, ions and their concentrations, salt bridge, and the flow of electrons. (b) (5 pts)...
Given the E° table values on page 2, list and explain the following: 2. Which metals are capable of reducing Fe2 to Fe? Which metal ions are capable of oxidizing Zn to Zn2? E(volts) Half-Reaction +0.80 2 Ag ()+2 e2 Ag () Cura)+2 e Cu ( +0.34 +2e H2 0.0 2H (aq) Ni +2 e Ni ( -0.25 Fe()+2 e -0.44 Fe ( -0.76 Zn (a)+ 2 e Zn () Mg +2 e Mg ( -2.37 (aq) 2 K (a)+2...
Using the information in the table: Which combination of metals, if used to create an electrochemical cell, would produce the largest voltage? Liu lur the reaction between Zn and Cu2+ ions is 1.1030 V, we can use the known value for the half-cell potential for zinc to determine the half-cell potential for copper: Zn(s) → Zn2+(aq) + 2e + Cu2+(aq) + 2e → Cu(s) Zn(s) + Cu2+ (aq) → Zn2+ (aq) + Cu(s) E half-cell = 0.7628 V Eºhalf-cell =...
Help me Solve these questions please... Electrochemistry Practice Questions Name 1. What's the oxidation number of nitrogen and oxygen in the nitrate ion? (1 point) 18 points Extra Credit) 5. Given the following balanced equation answer questions and NO: N= -5 Cu + M9. - Mg + Cu MO? + 2e- - Mg = -2.38 V Cu + 2 - Cu E = +0.34 V 0 -6 a) Write the cell line notation for the reaction above. (1 point) 2....
Calculate the theoretical cell potential (E°) of a galvanic cell under standard conditions made up of copper and magnesium (see Part II and Table 1 for more information). PARTIL Creating and Testing Voltaic Cells Introduction and Background for the Voltaic Cells A galvanic cell (sometimes more appropriately called a voltaic cell) consists of two half-cells joined by a salt bridge that allow ions to pass between the two sides in order to maintain electroneutrality. Each half-cell contains the Components of...