**Transcription for Educational Website:**A galvanic (voltaic) cell consists of an electrode composed of manganese in a 1.0 M manganese(II) ion solution and a second electrode composed of cobalt in a 1.0 M cobalt(II) ion solution, connected by a salt bridge. Calculate the standard potential for this cell at 25 °C. Use this list of [standard reduction potentials](#).\[ E_{\text{cell}} = \boxed{\phantom{V}} \text{ V} \]**Explanation:**This text serves as a problem statement for calculating the standard potential of a galvanic cell. The galvanic cell in this question consists of two different electrodes, manganese and cobalt, each immersed in their respective ion solutions of 1.0 M concentration. These solutions are connected by a salt bridge, which allows the movement of ions to maintain charge neutrality.To solve this problem, you would typically refer to a list of standard reduction potentials to find the reduction potentials for both the manganese and cobalt half-reactions. Once identified, you would use the following formula to calculate the standard cell potential:\[ E_{\text{cell}} = E_{\text{cathode}} - E_{\text{anode}} \]The specific reduction potentials would be plugged into the formula to solve for \( E_{\text{cell}} \).

Given:Higher the value of standard reduction potential for a species, higher will be its tendency to get reduced.Since, the value of Hence, Co2+ gets reduced to Co and Mn gets oxidized to Mn2+.The standard electrode potential of the cell is calculated as:Hence, the standard potential for this cell at 25oC is 0.90 V.standard potential for this cell at 25oC is 0.90 V

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A galvanic (voltaic) cell consists of an electrode composed of manganese in a 1.0 M manganese(II) ion solution and a second electrode composed of cobalt in a 1.0 M cobalt(II) ion solution, connected by a salt bridge. Calculate the standard potential for this cell at 25 °C. Use this list of standard reduction potentials. E: cell V

A galvanic (voltaic) cell consists of an electrode composed of manganese in a 1.0 M manganese(II) ion solution and a second electrode composed of cobalt in a 1.0 M cobalt(II) ion solution, connected by a salt bridge. Calculate the standard potential for this cell at 25 °C. Use this list of standard reduction potentials. E: cell V

Chemistry

10th Edition

ISBN:9781305957404

Author:Steven S. Zumdahl, Susan A. Zumdahl, Donald J. DeCoste

Publisher:Steven S. Zumdahl, Susan A. Zumdahl, Donald J. DeCoste

Chapter1: Chemical Foundations

Section: Chapter Questions

Problem 1RQ: Define and explain the differences between the following terms. a. law and theory b. theory and...

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