Effective Area of Electrode in Schering Bridge Calculator

✖Specimen Capacitance is defined as the capacitance of the given specimen or of the given electronic component.ⓘ Specimen Capacitance [C_s]			+10% -10%
✖Spacing between Electrodes is the distance between two electrodes forming a parallel plate capacitor.ⓘ Spacing between Electrodes [d]			+10% -10%
✖Relative Permittivity is a measure of how much electric energy a material can store compared to a vacuum. It quantifies the ability of a material to allow the formation of an electric field within it.ⓘ Relative Permittivity [ε_r]			+10% -10%

✖Electrode Effective Area is the area of the electrode material that is accessible to the electrolyte that is used for charge transfer and/or storage.ⓘ Effective Area of Electrode in Schering Bridge [A]

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Formula

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Effective Area of Electrode in Schering Bridge

Formula

A = \frac{C s \cdot d}{ε r \cdot [Permitivity-vacuum]}

Example

1.453596 m² = \frac{6.4 μF \cdot 0.4 mm}{199 \cdot [Permitivity-vacuum]}

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Effective Area of Electrode in Schering Bridge Solution

STEP 0: Pre-Calculation Summary

Formula Used

Electrode Effective Area = (Specimen Capacitance*Spacing between Electrodes)/(Relative Permittivity*[Permitivity-vacuum])
A = (C_s*d)/(ε_r*[Permitivity-vacuum])
This formula uses 1 Constants, 4 Variables

Constants Used

[Permitivity-vacuum] - Permittivity of vacuum Value Taken As 8.85E-12

Variables Used

Electrode Effective Area - (Measured in Square Meter) - Electrode Effective Area is the area of the electrode material that is accessible to the electrolyte that is used for charge transfer and/or storage.
Specimen Capacitance - (Measured in Farad) - Specimen Capacitance is defined as the capacitance of the given specimen or of the given electronic component.
Spacing between Electrodes - (Measured in Meter) - Spacing between Electrodes is the distance between two electrodes forming a parallel plate capacitor.
Relative Permittivity - Relative Permittivity is a measure of how much electric energy a material can store compared to a vacuum. It quantifies the ability of a material to allow the formation of an electric field within it.

STEP 1: Convert Input(s) to Base Unit

Specimen Capacitance: 6.4 Microfarad --> 6.4E-06 Farad (Check conversion here)
Spacing between Electrodes: 0.4 Millimeter --> 0.0004 Meter (Check conversion here)
Relative Permittivity: 199 --> No Conversion Required

STEP 2: Evaluate Formula

Substituting Input Values in Formula

A = (C_s*d)/(ε_r*[Permitivity-vacuum]) --> (6.4E-06*0.0004)/(199*[Permitivity-vacuum])

Evaluating ... ...

A = 1.45359566192545

STEP 3: Convert Result to Output's Unit

1.45359566192545 Square Meter --> No Conversion Required

FINAL ANSWER

1.45359566192545 ≈ 1.453596 Square Meter <-- Electrode Effective Area

(Calculation completed in 00.004 seconds)

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< Schering Bridge Calculators

Unknown Resistance in Schering Bridge

Go Series Resistance 1 in Schering Bridge = (Known Capacitance 4 in Schering Bridge/Known Capacitance 2 in Schering Bridge)*Known Resistance 3 in Schering Bridge

Unknown Capacitance in Schering Bridge

Go Unknown Capacitance in Schering Bridge = (Known Resistance 4 in Schering Bridge/Known Resistance 3 in Schering Bridge)*Known Capacitance 2 in Schering Bridge

Effective Area of Electrode in Schering Bridge

Go Electrode Effective Area = (Specimen Capacitance*Spacing between Electrodes)/(Relative Permittivity*[Permitivity-vacuum])

Dissipation Factor in Schering Bridge

Go Dissipation Factor in Schering Bridge = Angular Frequency*Known Capacitance 4 in Schering Bridge*Known Resistance 4 in Schering Bridge

Effective Area of Electrode in Schering Bridge Formula

Electrode Effective Area = (Specimen Capacitance*Spacing between Electrodes)/(Relative Permittivity*[Permitivity-vacuum])
A = (C_s*d)/(ε_r*[Permitivity-vacuum])

What is relative permittivity?

Relative permittivity, also known as the dielectric constant, is a measure of how much electric energy a material can store compared to a vacuum. It quantifies the ability of a material to allow the formation of an electric field within it. The relative permittivity of a material is defined as the ratio of the permittivity of the material to the permittivity of free space (vacuum).

How to Calculate Effective Area of Electrode in Schering Bridge?

Effective Area of Electrode in Schering Bridge calculator uses Electrode Effective Area = (Specimen Capacitance*Spacing between Electrodes)/(Relative Permittivity*[Permitivity-vacuum]) to calculate the Electrode Effective Area, The Effective Area of Electrode in Schering Bridge formula is defined as the portion of the electrode surface area that actively participates in the capacitance formation. This area directly affects the capacitance value in the relationship between the electrodes and the dielectric material placed between them. Electrode Effective Area is denoted by A symbol.

How to calculate Effective Area of Electrode in Schering Bridge using this online calculator? To use this online calculator for Effective Area of Electrode in Schering Bridge, enter Specimen Capacitance (C_s), Spacing between Electrodes (d) & Relative Permittivity (ε_r) and hit the calculate button. Here is how the Effective Area of Electrode in Schering Bridge calculation can be explained with given input values -> 1.453596 = (6.4E-06*0.0004)/(199*[Permitivity-vacuum]).

FAQ

What is Effective Area of Electrode in Schering Bridge?

The Effective Area of Electrode in Schering Bridge formula is defined as the portion of the electrode surface area that actively participates in the capacitance formation. This area directly affects the capacitance value in the relationship between the electrodes and the dielectric material placed between them and is represented as A = (C_s*d)/(ε_r*[Permitivity-vacuum]) or Electrode Effective Area = (Specimen Capacitance*Spacing between Electrodes)/(Relative Permittivity*[Permitivity-vacuum]). Specimen Capacitance is defined as the capacitance of the given specimen or of the given electronic component, Spacing between Electrodes is the distance between two electrodes forming a parallel plate capacitor & Relative Permittivity is a measure of how much electric energy a material can store compared to a vacuum. It quantifies the ability of a material to allow the formation of an electric field within it.

How to calculate Effective Area of Electrode in Schering Bridge?

The Effective Area of Electrode in Schering Bridge formula is defined as the portion of the electrode surface area that actively participates in the capacitance formation. This area directly affects the capacitance value in the relationship between the electrodes and the dielectric material placed between them is calculated using Electrode Effective Area = (Specimen Capacitance*Spacing between Electrodes)/(Relative Permittivity*[Permitivity-vacuum]). To calculate Effective Area of Electrode in Schering Bridge, you need Specimen Capacitance (C_s), Spacing between Electrodes (d) & Relative Permittivity (ε_r). With our tool, you need to enter the respective value for Specimen Capacitance, Spacing between Electrodes & Relative Permittivity and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.

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