5. (a) Use the standard reduction potentials at 259 C in Table 18.1 in Tro, Fridgen and Shaw, and...
(a) Use the standard reduction potentials at 25° C in Table 18.1 in Tro, Fridgen and Shaw, and calculate the standard emf E° of an electrochemical cell described by the following reaction: Ca + Sr2+ → Ca2+ + Sr (b) What is the value of E if the concentration of Sr2+ is 8.17 x 10-5 and the concentration of Ca2+ is 8.48 x 10-6? (c) If E = 0.28 V and Sr2+ = 0.10 M, what is the concentration of...
(a) Use the standard reduction potentials at 25° C in Table 18.1 in Tro, Fridgen and Shaw, and calculate the standard emf E° of an electrochemical cell described by the following reaction: Cd + Co2+ --> Cd2+ + Co (b) What is the value of E if the concentration of Co2+ is 2.99 x 10-6 and the concentration of Cd2+ is 3.87 x 10-5? (c) If E = 0.32 V and Co2+ = 0.10 M, what is the concentration of...
5. (a) Use the standard reduction potentials at 25° C in Table 18.1 in Tro, Fridgen and Shaw, and calculate the standard emf E° of an electrochemical cell described by the following reaction: Pb + Mn2+ --> Pb2+ + Mn (b) What is the value of E if the concentration of Mn2+ is 6.20 x 10-3 and the concentration of Pb2+ is 7.73 x 10-2? (c) If E = -0.89 V and Mn2+ = 0.10 M, what is the concentration...
5. (a) Use the standard reduction potentials at 25° C in Table 18.1 in Tro, Fridgen and Shaw, and calculate the standard emf Eº of an electrochemical cell described by the following reaction: Pb + Sn2+ --> Pb2+ + Sn (b) What is the value of E if the concentration of Sn is 1.26 x 10-2 and the concentration of Pb2+ is 7.11 x 10-5? (c) If E = 0.16 V and Sn2+ = 0.10 M, what is the concentration...
(a) Use the standard reduction potentials at 25° C in Table 18.1 in Tro, Fridgen and Shaw, and calculate the standard emf E° of an electrochemical cell described by the following reaction: Cu + Zn2+ --> Cu2+ + Zn (b) What is the value of E if the concentration of Zn2+ is 8.03 x 10-6 and the concentration of Cu2+ is 6.09 x 10-5? (c) If E = -0.90 V and Zn2+ = 0.10 M, what is the concentration of...
4. (a) Use the standard reduction potentials at 25° C in Table 18.1 in Tro, Fridgen and Shaw, and calculate the standard emf E° of an electrochemical cell described by the following reaction: Be + 2 Nat → 2 Na + Be2+ (b) What is n? (c) What is AGº for this reaction at 25°? (d) What is the equilibrium constant for this reaction at 25°? lectrochemical cell described by the followinden and Shaw, and
4. (a) Use the standard reduction potentials at 25° C in Table 18.1 in Tro, Fridgen and Shaw, and calculate the standard emf E° of an electrochemical cell described by the following reaction: 2 Nat + Zn → Zn2+ + 2 Na (b) What is n? (c) What is AGº for this reaction at 25°? (d) What is the equilibrium constant for this reaction at 25°?
4. (a) Use the standard reduction potentials at 25° C in Table 18.1 in Tro, Fridgen and Shaw, and calculate the standard emf E° of an electrochemical cell described by the following reaction: 3 Mn + 2 Al3+ → 2 Al + 3 Mn2+ (b) What is n? (c) What is ∆G° for this reaction at 25°? (d) What is the equilibrium constant for this reaction at 25°?
4. (a) Use the standard reduction potentials at 25° C in Table 18.1 in Tro, Fridgen and Shaw, and calculate the standard emf E° of an electrochemical cell described by the following reaction: 3 Zn + 2 Cr3+ + 2 Cr + 3 Zn? (b) What is n? (c) What is AGº for this reaction at 25°? (d) What is the equilibrium constant for this reaction at 25°? TABLE 18.1 Standard Reduction Potentials at 25°C EV) 2.87 1.61 1.51 1.36...
table is 18.1 is given. please show work so i understand 4. (a) Use the standard reduction potentials at 25° C in Table 18.1 in Tro, Fridgen and Shaw, and calculate the standard emf E' of an electrochemical cell described by the following reaction: 2 K+ + Mn → Mn + 2 K (b) What is n? (c) What is AGº for this reaction at 25°? (d) What is the equilibrium constant for this reaction at 25°? E (V) Weaker...