Conductivity given Conductance Calculator

✖Conductance (also known as electrical conductance) is defined as the potential for a substance to conduct electricity.ⓘ Conductance [G]			+10% -10%
✖The Distance between Electrodes is the separation between two parallel electrodes.ⓘ Distance between Electrodes [l]			+10% -10%
✖The Electrode Cross-sectional Area is the size of the electrodes used in an electrolytic cell.ⓘ Electrode Cross-sectional Area [a]			+10% -10%

✖The Specific Conductance is the ability of a substance to conduct electricity. It is the reciprocal of specific resistance.ⓘ Conductivity given Conductance [K]

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Formula

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Conductivity given Conductance

Formula

`"K" = ("G")*("l"/"a")`

Example

`"4714.405S/m"=("9900.25℧")*("5m"/"10.5m²")`

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Conductivity given Conductance Solution

STEP 0: Pre-Calculation Summary

Formula Used

Specific Conductance = (Conductance)*(Distance between Electrodes/Electrode Cross-sectional Area)
K = (G)*(l/a)
This formula uses 4 Variables

Variables Used

Specific Conductance - (Measured in Siemens per Meter) - The Specific Conductance is the ability of a substance to conduct electricity. It is the reciprocal of specific resistance.
Conductance - (Measured in Siemens) - Conductance (also known as electrical conductance) is defined as the potential for a substance to conduct electricity.
Distance between Electrodes - (Measured in Meter) - The Distance between Electrodes is the separation between two parallel electrodes.
Electrode Cross-sectional Area - (Measured in Square Meter) - The Electrode Cross-sectional Area is the size of the electrodes used in an electrolytic cell.

STEP 1: Convert Input(s) to Base Unit

Conductance: 9900.25 Mho --> 9900.25 Siemens (Check conversion here)
Distance between Electrodes: 5 Meter --> 5 Meter No Conversion Required
Electrode Cross-sectional Area: 10.5 Square Meter --> 10.5 Square Meter No Conversion Required

STEP 2: Evaluate Formula

Substituting Input Values in Formula

K = (G)*(l/a) --> (9900.25)*(5/10.5)

Evaluating ... ...

K = 4714.40476190476

STEP 3: Convert Result to Output's Unit

4714.40476190476 Siemens per Meter --> No Conversion Required

FINAL ANSWER

4714.40476190476 ≈ 4714.405 Siemens per Meter <-- Specific Conductance

(Calculation completed in 00.020 seconds)

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< 20 Conductance and Conductivity Calculators

Area of Cross-Section of Electrode given Conductance and Conductivity

Go Electrode Cross-sectional Area = (Conductance*Distance between Electrodes)/(Specific Conductance)

Distance between Electrode given Conductance and Conductivity

Go Distance between Electrodes = (Specific Conductance*Electrode Cross-sectional Area)/(Conductance)

Conductivity given Conductance

Go Specific Conductance = (Conductance)*(Distance between Electrodes/Electrode Cross-sectional Area)

Conductance given Conductivity

Go Conductance = (Specific Conductance*Electrode Cross-sectional Area)/(Distance between Electrodes)

Molar Conductivity at Infinite Dilution

Go Molar Conductivity at Infinite Dilution = (Mobility of Cation+Mobility of Anion)*[Faraday]

Limiting Molar Conductivity of Cations

Go Limiting Molar Conductivity = Ionic Mobility of Cation at Infinite Dilution*[Faraday]

Limiting Molar Conductivity of Anions

Go Limiting Molar Conductivity = Ionic Mobility of Anion at Infinite Dilution*[Faraday]

Limiting Molar Conductivity given Degree of Dissociation

Go Limiting Molar Conductivity = (Solution Molar Conductivity/Degree of Dissociation)

Specific Conductance given Molarity

Go Specific Conductance = (Solution Molar Conductivity*Molarity)/1000

Molar Volume of solution given Molar Conductivity

Go Molar Volume = (Solution Molar Conductivity/Specific Conductance)

Molar Conductivity given Conductivity and Volume

Go Solution Molar Conductivity = (Specific Conductance*Molar Volume)

Conductivity given Molar Volume of Solution

Go Specific Conductance = (Solution Molar Conductivity/Molar Volume)

Equivalent Conductance

Go Equivalent Conductance = Specific Conductance*Volume of Solution

Molar Conductivity given Molarity

Go Molar Conductivity = Specific Conductance*1000/Molarity

Cell Constant given Conductance and Conductivity

Go Cell Constant = (Specific Conductance/Conductance)

Conductivity given Cell Constant

Go Specific Conductance = (Conductance*Cell Constant)

Conductance given Cell Constant

Go Conductance = (Specific Conductance/Cell Constant)

Molar Conductance

Go Molar Conductance = Specific Conductance/Molarity

Specific Conductance

Go Specific Conductance = 1/Resistivity

Conductance

Go Conductance = 1/Resistance

< 17 Important Formulas of Conductance Calculators

Charge Number of Ion Species using Debey-Huckel Limiting Law

Go Charge Number of Ion Species = (-ln(Mean Activity Coefficient)/(Debye Huckel limiting Law Constant*sqrt(Ionic Strength)))^(1/2)

Debey-Huckel Limiting Law Constant

Go Debye Huckel limiting Law Constant = -(ln(Mean Activity Coefficient))/(Charge Number of Ion Species^2)*sqrt(Ionic Strength)

Dissociation Constant of Acid 1 given Degree of Dissociation of Both Acids

Go Dissociation Constant of Acid 1 = (Dissociation Constant of Acid 2)*((Degree of Dissociation 1/Degree of Dissociation 2)^2)

Dissociation Constant of Base 1 given Degree of Dissociation of Both Bases

Go Dissociation Constant of Base 1 = (Dissociation Constant of Base 2)*((Degree of Dissociation 1/Degree of Dissociation 2)^2)

Distance between Electrode given Conductance and Conductivity

Go Distance between Electrodes = (Specific Conductance*Electrode Cross-sectional Area)/(Conductance)

Conductivity given Conductance

Go Specific Conductance = (Conductance)*(Distance between Electrodes/Electrode Cross-sectional Area)

Equilibrium Constant given Degree of Dissociation

Go Equilibrium Constant = Initial Concentration*Degree of Dissociation^2/(1-Degree of Dissociation)

Molar Conductivity at Infinite Dilution

Go Molar Conductivity at Infinite Dilution = (Mobility of Cation+Mobility of Anion)*[Faraday]

Degree of Dissociation given Concentration and Dissociation Constant of Weak Electrolyte

Go Degree of Dissociation = sqrt(Dissociation Constant of Weak Acid/Ionic Concentration)

Dissociation Constant given Degree of Dissociation of Weak Electrolyte

Go Dissociation Constant of Weak Acid = Ionic Concentration*((Degree of Dissociation)^2)

Degree of Dissociation

Go Degree of Dissociation = Molar Conductivity/Limiting Molar Conductivity

Conductivity given Molar Volume of Solution

Go Specific Conductance = (Solution Molar Conductivity/Molar Volume)

Equivalent Conductance

Go Equivalent Conductance = Specific Conductance*Volume of Solution

Conductivity given Cell Constant

Go Specific Conductance = (Conductance*Cell Constant)

Molar Conductance

Go Molar Conductance = Specific Conductance/Molarity

Specific Conductance

Go Specific Conductance = 1/Resistivity

Conductance

Go Conductance = 1/Resistance

Conductivity given Conductance Formula

Specific Conductance = (Conductance)*(Distance between Electrodes/Electrode Cross-sectional Area)
K = (G)*(l/a)

What is specific conductance?

Specific Conductance is the ability of a substance to conduct electricity. It is the reciprocal of specific resistance. Specific conductance is defined as the conducting capacity of a solution of the dissolved electrolyte and the whole solution is being placed between two electrodes are 1 sq. cm and length 1 cm.

How to Calculate Conductivity given Conductance?

Conductivity given Conductance calculator uses Specific Conductance = (Conductance)*(Distance between Electrodes/Electrode Cross-sectional Area) to calculate the Specific Conductance, The Conductivity given conductance formula is defined as the product of conductance of electrolytic conductor with the ratio of the distance between electrode to the area of electrodes. Specific Conductance is denoted by K symbol.

How to calculate Conductivity given Conductance using this online calculator? To use this online calculator for Conductivity given Conductance, enter Conductance (G), Distance between Electrodes (l) & Electrode Cross-sectional Area (a) and hit the calculate button. Here is how the Conductivity given Conductance calculation can be explained with given input values -> 4714.405 = (9900.25)*(5/10.5).

FAQ

What is Conductivity given Conductance?

The Conductivity given conductance formula is defined as the product of conductance of electrolytic conductor with the ratio of the distance between electrode to the area of electrodes and is represented as K = (G)*(l/a) or Specific Conductance = (Conductance)*(Distance between Electrodes/Electrode Cross-sectional Area). Conductance (also known as electrical conductance) is defined as the potential for a substance to conduct electricity, The Distance between Electrodes is the separation between two parallel electrodes & The Electrode Cross-sectional Area is the size of the electrodes used in an electrolytic cell.

How to calculate Conductivity given Conductance?

The Conductivity given conductance formula is defined as the product of conductance of electrolytic conductor with the ratio of the distance between electrode to the area of electrodes is calculated using Specific Conductance = (Conductance)*(Distance between Electrodes/Electrode Cross-sectional Area). To calculate Conductivity given Conductance, you need Conductance (G), Distance between Electrodes (l) & Electrode Cross-sectional Area (a). With our tool, you need to enter the respective value for Conductance, Distance between Electrodes & Electrode Cross-sectional Area 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 Specific Conductance?

In this formula, Specific Conductance uses Conductance, Distance between Electrodes & Electrode Cross-sectional Area. We can use 6 other way(s) to calculate the same, which is/are as follows -

Specific Conductance = 1/Resistivity
Specific Conductance = (Conductance*Cell Constant)
Specific Conductance = (Solution Molar Conductivity/Molar Volume)
Specific Conductance = (Conductance*Cell Constant)
Specific Conductance = (Solution Molar Conductivity/Molar Volume)
Specific Conductance = 1/Resistivity

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