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Mobility of a charge carriers Solution

STEP 0: Pre-Calculation Summary
Formula Used
mobility_of_charge_carriers = Drift Velocity/Electric field intensity
μ = Vd/E
This formula uses 2 Variables
Variables Used
Drift Velocity - Drift Velocity is the average velocity of electrons along the wire . (Measured in Meter per Second)
Electric field intensity - The Electric field intensity is a vector quantity which has both magnitude and direction. It depends on the amount of charge present on the test charge particle. (Measured in Volt per Meter)
STEP 1: Convert Input(s) to Base Unit
Drift Velocity: 0.001 Meter per Second --> 0.001 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
μ = Vd/E --> 0.001/36
Evaluating ... ...
μ = 2.77777777777778E-05
STEP 3: Convert Result to Output's Unit
2.77777777777778E-05 Meter² per Second --> No Conversion Required
FINAL ANSWER
2.77777777777778E-05 Meter² per Second <-- Mobility of charge carriers
(Calculation completed in 00.016 seconds)

10+ Basic Electronics Calculators

Conductivity in semiconductors in terms of mobility of electrons and holes
conductivity = Concentration of electrons in the conduction band*[Charge-e]*Mobility of holes+Majority carrier electron concentration*[Charge-e]*Mobility of electron Go
Intrinsic concentration
intrinsic_carrier_concentration = sqrt(Coefficient related to specific semiconductor*(Temperature)^3*e^-(Semiconductor bandgap energy/(2*[BoltZ]*Temperature))) Go
Conductivity of extrinsic semiconductor for p-type
conductivity_of_extrinsic_semiconductors_n_type = Acceptor concentration*[Charge-e]*Mobility of electron Go
Conductivity of extrinsic semiconductors for n-type
conductivity_of_extrinsic_semiconductors_p_type = Donor concentration*[Charge-e]*Mobility of holes Go
Majority carrier concentration in a Semiconductor
majority_carrier_electron_concentration = (Intrinsic carrier concentration)^2/Minority carrier concentration Go
Electron diffusion length in terms of relaxation time
electron_diffusion_length = sqrt(Electron Diffusion Constant*Relaxation time) Go
Conductivity in metals in terms of number of electrons
conductivity = Number of Electrons*Mobility of electron*[Charge-e] Go
Einstein's Equation
voltage_equivalent_of_temperature = Electron Diffusion Constant/Mobility of electron Go
Mobility of a charge carriers
mobility_of_charge_carriers = Drift Velocity/Electric field intensity Go
Thermal Voltage or voltage equivalent of temperature
thermal_voltage = Temperature/11600 Go

Mobility of a charge carriers Formula

mobility_of_charge_carriers = Drift Velocity/Electric field intensity
μ = Vd/E

What is mobility of charge carriers ?

The mobility of charge carriers in a current-carrying conductor can be defined as the net average velocity with which the free-electrons move towards the positive end of a conductor under the influence of an external electric field that is being applied.

How to Calculate Mobility of a charge carriers?

Mobility of a charge carriers calculator uses mobility_of_charge_carriers = Drift Velocity/Electric field intensity to calculate the Mobility of charge carriers, Mobility of a charge carriers is defined as the drift velocity of the charge carrier per unit electric field. Mobility of charge carriers and is denoted by μ symbol.

How to calculate Mobility of a charge carriers using this online calculator? To use this online calculator for Mobility of a charge carriers, enter Drift Velocity (Vd) and Electric field intensity (E) and hit the calculate button. Here is how the Mobility of a charge carriers calculation can be explained with given input values -> 2.778E-5 = 0.001/36.

FAQ

What is Mobility of a charge carriers?
Mobility of a charge carriers is defined as the drift velocity of the charge carrier per unit electric field and is represented as μ = Vd/E or mobility_of_charge_carriers = Drift Velocity/Electric field intensity. Drift Velocity is the average velocity of electrons along the wire and The Electric field intensity is a vector quantity which has both magnitude and direction. It depends on the amount of charge present on the test charge particle.
How to calculate Mobility of a charge carriers?
Mobility of a charge carriers is defined as the drift velocity of the charge carrier per unit electric field is calculated using mobility_of_charge_carriers = Drift Velocity/Electric field intensity. To calculate Mobility of a charge carriers, you need Drift Velocity (Vd) and Electric field intensity (E). With our tool, you need to enter the respective value for Drift Velocity and Electric field intensity 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 Mobility of charge carriers?
In this formula, Mobility of charge carriers uses Drift Velocity and Electric field intensity. We can use 10 other way(s) to calculate the same, which is/are as follows -
  • thermal_voltage = Temperature/11600
  • mobility_of_charge_carriers = Drift Velocity/Electric field intensity
  • majority_carrier_electron_concentration = (Intrinsic carrier concentration)^2/Minority carrier concentration
  • intrinsic_carrier_concentration = sqrt(Coefficient related to specific semiconductor*(Temperature)^3*e^-(Semiconductor bandgap energy/(2*[BoltZ]*Temperature)))
  • voltage_equivalent_of_temperature = Electron Diffusion Constant/Mobility of electron
  • electron_diffusion_length = sqrt(Electron Diffusion Constant*Relaxation time)
  • conductivity = Number of Electrons*Mobility of electron*[Charge-e]
  • conductivity = Concentration of electrons in the conduction band*[Charge-e]*Mobility of holes+Majority carrier electron concentration*[Charge-e]*Mobility of electron
  • conductivity_of_extrinsic_semiconductors_p_type = Donor concentration*[Charge-e]*Mobility of holes
  • conductivity_of_extrinsic_semiconductors_n_type = Acceptor concentration*[Charge-e]*Mobility of electron
Where is the Mobility of a charge carriers calculator used?
Among many, Mobility of a charge carriers calculator is widely used in real life applications like {FormulaUses}. Here are few more real life examples -
{FormulaExamplesList}
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