Moles of Electron Transferred given Standard Change in Gibbs Free Energy Solution

STEP 0: Pre-Calculation Summary
Formula Used
Moles of Electron Transferred = -(Standard Gibbs Free Energy)/([Faraday]*Standard Cell Potential)
n = -(ΔG°)/([Faraday]*Eocell)
This formula uses 1 Constants, 3 Variables
Constants Used
[Faraday] - Faraday constant Value Taken As 96485.33212
Variables Used
Moles of Electron Transferred - The Moles of Electron Transferred is the amount of electrons taking part in the cell reaction.
Standard Gibbs Free Energy - (Measured in Joule) - The Standard Gibbs Free Energy is a standard thermodynamic potential that can be used to calculate the maximum of reversible work performed by a standard system at constant temperature and pressure.
Standard Cell Potential - (Measured in Volt) - The Standard cell potential is defined as The value of the standard emf of a cell in which molecular hydrogen under standard pressure is oxidized to solvated protons at the left-hand electrode.
STEP 1: Convert Input(s) to Base Unit
Standard Gibbs Free Energy: -771 Kilojoule --> -771000 Joule (Check conversion here)
Standard Cell Potential: 2 Volt --> 2 Volt No Conversion Required
STEP 2: Evaluate Formula
Substituting Input Values in Formula
n = -(ΔG°)/([Faraday]*Eocell) --> -((-771000))/([Faraday]*2)
Evaluating ... ...
n = 3.99542595262613
STEP 3: Convert Result to Output's Unit
3.99542595262613 --> No Conversion Required
FINAL ANSWER
3.99542595262613 3.995426 <-- Moles of Electron Transferred
(Calculation completed in 00.004 seconds)

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15 Gibbs Free Energy and Gibbs Free Entropy Calculators

Internal Energy given Gibbs Free Entropy
Go Internal Energy = ((Entropy-Gibbs Free Entropy)*Temperature)-(Pressure*Volume)
Pressure given Gibbs Free Entropy
Go Pressure = (((Entropy-Gibbs Free Entropy)*Temperature)-Internal Energy)/Volume
Entropy given Gibbs Free Entropy
Go Entropy = Gibbs Free Entropy+((Internal Energy+(Pressure*Volume))/Temperature)
Volume given Gibbs Free Entropy
Go Volume = (((Entropy-Gibbs Free Entropy)*Temperature)-Internal Energy)/Pressure
Gibbs Free Entropy
Go Gibbs Free Entropy = Entropy-((Internal Energy+(Pressure*Volume))/Temperature)
Helmholtz Free Entropy given Gibbs Free Entropy
Go Helmholtz Free Entropy = (Gibbs Free Entropy+((Pressure*Volume)/Temperature))
Moles of Electron Transferred given Standard Change in Gibbs Free Energy
Go Moles of Electron Transferred = -(Standard Gibbs Free Energy)/([Faraday]*Standard Cell Potential)
Standard Cell Potential given Standard Change in Gibbs Free Energy
Go Standard Cell Potential = -(Standard Gibbs Free Energy)/(Moles of Electron Transferred*[Faraday])
Standard Change in Gibbs Free Energy given Standard Cell Potential
Go Standard Gibbs Free Energy = -(Moles of Electron Transferred)*[Faraday]*Standard Cell Potential
Moles of Electron Transferred given Change in Gibbs Free Energy
Go Moles of Electron Transferred = (-Gibbs Free Energy)/([Faraday]*Cell Potential)
Change in Gibbs Free Energy given Cell Potential
Go Gibbs Free Energy = (-Moles of Electron Transferred*[Faraday]*Cell Potential)
Electric Part of Gibbs Free Entropy given Classical Part
Go Electric part gibbs free entropy = (Gibbs Free Entropy-Classical part gibbs free entropy)
Gibbs Free Entropy given Classical and Electric Part
Go Gibbs Free Entropy = (Classical part gibbs free entropy+Electric part gibbs free entropy)
Gibbs Free Entropy given Gibbs Free Energy
Go Gibbs Free Entropy = -(Gibbs Free Energy/Temperature)
Change in Gibbs Free Energy given Electrochemical Work
Go Gibbs Free Energy = -(Work Done)

Moles of Electron Transferred given Standard Change in Gibbs Free Energy Formula

Moles of Electron Transferred = -(Standard Gibbs Free Energy)/([Faraday]*Standard Cell Potential)
n = -(ΔG°)/([Faraday]*Eocell)

What is the Relationship between Cell Potential & Free Energy?

Electrochemical cells convert chemical energy to electrical energy and vice versa. The total amount of energy produced by an electrochemical cell, and thus the amount of energy available to do electrical work, depends on both the cell potential and the total number of electrons that are transferred from the reductant to the oxidant during the course of a reaction. The resulting electric current is measured in coulombs (C), an SI unit that measures the number of electrons passing a given point in 1 s. A coulomb relates energy (in joules) to electrical potential (in volts). Electric current is measured in amperes (A); 1 A is defined as the flow of 1 C/s past a given point (1 C = 1 A·s).

How to Calculate Moles of Electron Transferred given Standard Change in Gibbs Free Energy?

Moles of Electron Transferred given Standard Change in Gibbs Free Energy calculator uses Moles of Electron Transferred = -(Standard Gibbs Free Energy)/([Faraday]*Standard Cell Potential) to calculate the Moles of Electron Transferred, The Moles of electron transferred given Standard change in Gibbs free energy formula is defined as the negative ratio standard Gibbs free energy to the standard cell potential and faraday constant. Moles of Electron Transferred is denoted by n symbol.

How to calculate Moles of Electron Transferred given Standard Change in Gibbs Free Energy using this online calculator? To use this online calculator for Moles of Electron Transferred given Standard Change in Gibbs Free Energy, enter Standard Gibbs Free Energy (ΔG°) & Standard Cell Potential (Eocell) and hit the calculate button. Here is how the Moles of Electron Transferred given Standard Change in Gibbs Free Energy calculation can be explained with given input values -> 3.995426 = -((-771000))/([Faraday]*2).

FAQ

What is Moles of Electron Transferred given Standard Change in Gibbs Free Energy?
The Moles of electron transferred given Standard change in Gibbs free energy formula is defined as the negative ratio standard Gibbs free energy to the standard cell potential and faraday constant and is represented as n = -(ΔG°)/([Faraday]*Eocell) or Moles of Electron Transferred = -(Standard Gibbs Free Energy)/([Faraday]*Standard Cell Potential). The Standard Gibbs Free Energy is a standard thermodynamic potential that can be used to calculate the maximum of reversible work performed by a standard system at constant temperature and pressure & The Standard cell potential is defined as The value of the standard emf of a cell in which molecular hydrogen under standard pressure is oxidized to solvated protons at the left-hand electrode.
How to calculate Moles of Electron Transferred given Standard Change in Gibbs Free Energy?
The Moles of electron transferred given Standard change in Gibbs free energy formula is defined as the negative ratio standard Gibbs free energy to the standard cell potential and faraday constant is calculated using Moles of Electron Transferred = -(Standard Gibbs Free Energy)/([Faraday]*Standard Cell Potential). To calculate Moles of Electron Transferred given Standard Change in Gibbs Free Energy, you need Standard Gibbs Free Energy (ΔG°) & Standard Cell Potential (Eocell). With our tool, you need to enter the respective value for Standard Gibbs Free Energy & Standard Cell Potential and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.
How many ways are there to calculate Moles of Electron Transferred?
In this formula, Moles of Electron Transferred uses Standard Gibbs Free Energy & Standard Cell Potential. We can use 1 other way(s) to calculate the same, which is/are as follows -
  • Moles of Electron Transferred = (-Gibbs Free Energy)/([Faraday]*Cell Potential)
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