Electrophoretic Mobility of Particle Solution

STEP 0: Pre-Calculation Summary
Formula Used
Electrophoretic Mobility = Drift Velocity of Dispersed Particle/Electric Field Intensity
μe = νd/E
This formula uses 3 Variables
Variables Used
Electrophoretic Mobility - (Measured in Square Meter per Volt per Second) - Electrophoretic Mobility is defined as the ratio of electrophoretic (drift) velocity to the electric field strength at the location where the velocity is measured.
Drift Velocity of Dispersed Particle - (Measured in Meter per Second) - Drift Velocity of Dispersed Particle is defined as average velocity attained by charged particles, such as electrons, in a material due to an electric field.
Electric Field Intensity - (Measured in Volt per Meter) - The Electric Field Intensity is a vector quantity that has both magnitude and direction. It depends on the amount of charge present on the test charge particle.
STEP 1: Convert Input(s) to Base Unit
Drift Velocity of Dispersed Particle: 5 Meter per Second --> 5 Meter per Second No Conversion Required
Electric Field Intensity: 36 Volt per Meter --> 36 Volt per Meter No Conversion Required
STEP 2: Evaluate Formula
Substituting Input Values in Formula
μe = νd/E --> 5/36
Evaluating ... ...
μe = 0.138888888888889
STEP 3: Convert Result to Output's Unit
0.138888888888889 Square Meter per Volt per Second --> No Conversion Required
FINAL ANSWER
0.138888888888889 0.138889 Square Meter per Volt per Second <-- Electrophoretic Mobility
(Calculation completed in 00.004 seconds)

Credits

Created by Pratibha
Amity Institute Of Applied Sciences (AIAS, Amity University), Noida, India
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Verified by Soupayan banerjee
National University of Judicial Science (NUJS), Kolkata
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7 Electrophoresis and other Electrokinetics Phenomena Calculators

Viscosity of Solvent given Zeta Potential using Smoluchowski Equation
Go Dynamic Viscosity of Liquid = (Zeta Potential*Relative Permittivity of Solvent)/(4*pi*Ionic Mobility)
Ionic Mobility given Zeta Potential using Smoluchowski Equation
Go Ionic Mobility = (Zeta Potential*Relative Permittivity of Solvent)/(4*pi*Dynamic Viscosity of Liquid)
Relative Permittivity of Solvent given Zeta Potential
Go Relative Permittivity of Solvent = (4*pi*Dynamic Viscosity of Liquid*Ionic Mobility)/Zeta Potential
Zeta Potential using Smoluchowski Equation
Go Zeta Potential = (4*pi*Dynamic Viscosity of Liquid*Ionic Mobility)/Relative Permittivity of Solvent
Drift Velocity of Dispersed Particle given Electrophoretic Mobility
Go Drift Velocity of Dispersed Particle = Electrophoretic Mobility*Electric Field Intensity
Electric Field Intensity given Electrophoretic Mobility
Go Electric Field Intensity = Drift Velocity of Dispersed Particle/Electrophoretic Mobility
Electrophoretic Mobility of Particle
Go Electrophoretic Mobility = Drift Velocity of Dispersed Particle/Electric Field Intensity

16 Important Formulas of Colloids Calculators

Surface Enthalpy given Critical Temperature
Go Surface Enthalpy = (Constant for each Liquid)*(1-(Temperature/Critical Temperature))^(Empirical Factor-1)*(1+((Empirical Factor-1)*(Temperature/Critical Temperature)))
Surface Entropy given Critical Temperature
Go Surface Entropy = Empirical Factor*Constant for each Liquid*(1-(Temperature/Critical Temperature))^(Empirical Factor)-(1/Critical Temperature)
Ionic Mobility given Zeta Potential using Smoluchowski Equation
Go Ionic Mobility = (Zeta Potential*Relative Permittivity of Solvent)/(4*pi*Dynamic Viscosity of Liquid)
Number of Moles of Surfactant given Critical Micelle Concentration
Go Number of Moles of Surfactant = (Total Concentration of Surfactant-Critical Micelle Concentration)/Degree of Aggregation of Micelle
Zeta Potential using Smoluchowski Equation
Go Zeta Potential = (4*pi*Dynamic Viscosity of Liquid*Ionic Mobility)/Relative Permittivity of Solvent
Micellar Core Radius given Micellar Aggregation Number
Go Micelle Core Radius = ((Micellar Aggregation Number*3*Volume of Hydrophobic Tail)/(4*pi))^(1/3)
Volume of Hydrophobic Tail given Micellar Aggregation Number
Go Volume of Hydrophobic Tail = ((4/3)*pi*(Micelle Core Radius^3))/Micellar Aggregation Number
Micellar Aggregation Number
Go Micellar Aggregation Number = ((4/3)*pi*(Micelle Core Radius^3))/Volume of Hydrophobic Tail
Critical Packing Parameter
Go Critical Packing Parameter = Surfactant Tail Volume/(Optimal Area*Tail Length)
Specific Surface Area for array of n Cylindrical Particles
Go Specific Surface Area = (2/Density)*((1/Cylinder Radius)+(1/Length))
Electrophoretic Mobility of Particle
Go Electrophoretic Mobility = Drift Velocity of Dispersed Particle/Electric Field Intensity
Surface Viscosity
Go Surface Viscosity = Dynamic Viscosity/Thickness of Surface Phase
Critical Chain Length of Hydrocarbon Tail using Tanford Equation
Go Critical Chain Length of Hydrocarbon Tail = (0.154+( 0.1265*Number of Carbon Atoms))
Specific Surface Area
Go Specific Surface Area = 3/(Density*Radius of Sphere)
Number of Carbon Atoms given Critical Chain Length of Hydrocarbon
Go Number of Carbon Atoms = (Critical Chain Length of Hydrocarbon Tail-0.154)/0.1265
Volume of Hydrocarbon Chain using Tanford Equation
Go Micelle Core Volume = (27.4+(26.9*Number of Carbon Atoms))*(10^(-3))

Electrophoretic Mobility of Particle Formula

Electrophoretic Mobility = Drift Velocity of Dispersed Particle/Electric Field Intensity
μe = νd/E

What is Electrophoresis?

Electrophoresis is the motion of dispersed particles relative to a fluid under the influence of a spatially uniform electric field. Electrophoresis of positively charged particles (cations) is sometimes called cataphoresis, while electrophoresis of negatively charged particles (anions) is sometimes called anaphoresis.
Electrophoresis is used in laboratories to separate macromolecules based on size. The technique applies a negative charge so proteins move towards a positive charge. Electrophoresis is used extensively in DNA, RNA and protein analysis.

How to Calculate Electrophoretic Mobility of Particle?

Electrophoretic Mobility of Particle calculator uses Electrophoretic Mobility = Drift Velocity of Dispersed Particle/Electric Field Intensity to calculate the Electrophoretic Mobility, The Electrophoretic Mobility of Particle formula is defined as the ratio of electrophoretic velocity to the electric field intensity at the location where the velocity is measured. Electrophoretic Mobility is denoted by μe symbol.

How to calculate Electrophoretic Mobility of Particle using this online calculator? To use this online calculator for Electrophoretic Mobility of Particle, enter Drift Velocity of Dispersed Particle d) & Electric Field Intensity (E) and hit the calculate button. Here is how the Electrophoretic Mobility of Particle calculation can be explained with given input values -> 0.138889 = 5/36.

FAQ

What is Electrophoretic Mobility of Particle?
The Electrophoretic Mobility of Particle formula is defined as the ratio of electrophoretic velocity to the electric field intensity at the location where the velocity is measured and is represented as μe = νd/E or Electrophoretic Mobility = Drift Velocity of Dispersed Particle/Electric Field Intensity. Drift Velocity of Dispersed Particle is defined as average velocity attained by charged particles, such as electrons, in a material due to an electric field & The Electric Field Intensity is a vector quantity that has both magnitude and direction. It depends on the amount of charge present on the test charge particle.
How to calculate Electrophoretic Mobility of Particle?
The Electrophoretic Mobility of Particle formula is defined as the ratio of electrophoretic velocity to the electric field intensity at the location where the velocity is measured is calculated using Electrophoretic Mobility = Drift Velocity of Dispersed Particle/Electric Field Intensity. To calculate Electrophoretic Mobility of Particle, you need Drift Velocity of Dispersed Particle d) & Electric Field Intensity (E). With our tool, you need to enter the respective value for Drift Velocity of Dispersed Particle & Electric Field Intensity 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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