Photoelectron Energy Solution

STEP 0: Pre-Calculation Summary
Formula Used
Photoelectron Energy = [hP]*Frequency of Incident Light
Ephoto = [hP]*f
This formula uses 1 Constants, 2 Variables
Constants Used
[hP] - Planck constant Value Taken As 6.626070040E-34
Variables Used
Photoelectron Energy - (Measured in Joule) - Photoelectron Energy refers to the kinetic energy of an electron that is emitted or liberated from a material or atom when it absorbs a photon of sufficient energy.
Frequency of Incident Light - (Measured in Hertz) - Frequency of Incident Light refers to the number of complete cycles of electromagnetic waves passing through a given point in space per unit time.
STEP 1: Convert Input(s) to Base Unit
Frequency of Incident Light: 183.15 Petahertz --> 1.8315E+17 Hertz (Check conversion here)
STEP 2: Evaluate Formula
Substituting Input Values in Formula
Ephoto = [hP]*f --> [hP]*1.8315E+17
Evaluating ... ...
Ephoto = 1.213564727826E-16
STEP 3: Convert Result to Output's Unit
1.213564727826E-16 Joule -->757.447197075242 Electron-Volt (Check conversion here)
FINAL ANSWER
757.447197075242 757.4472 Electron-Volt <-- Photoelectron Energy
(Calculation completed in 00.004 seconds)

Credits

Created by Shobhit Dimri
Bipin Tripathi Kumaon Institute of Technology (BTKIT), Dwarahat
Shobhit Dimri has created this Calculator and 900+ more calculators!
Verified by Urvi Rathod
Vishwakarma Government Engineering College (VGEC), Ahmedabad
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20 Energy Band & Charge Carrier Calculators

Intrinsic Carrier Concentration
Go Intrinsic Carrier Concentration = sqrt(Effective Density of State in Valence Band*Effective Density of State in Conduction Band) *exp(-Energy Gap/(2*[BoltZ]*Temperature))
Carrier Lifetime
Go Carrier Lifetime = 1/(Proportionality for Recombination*(Holes Concentration in Valance Band+Electron Concentration in Conduction Band))
Energy of Electron given Coulomb's Constant
Go Energy of Electron = (Quantum Number^2*pi^2*[hP]^2)/(2*[Mass-e]*Potential Well Length^2)
Steady State Electron Concentration
Go Steady State Carrier Concentration = Electron Concentration in Conduction Band+Excess Carrier Concentration
Effective Density of State
Go Effective Density of State in Conduction Band = Electron Concentration in Conduction Band/Fermi Function
Fermi Function
Go Fermi Function = Electron Concentration in Conduction Band/Effective Density of State in Conduction Band
Concentration in Conduction Band
Go Electron Concentration in Conduction Band = Effective Density of State in Conduction Band*Fermi Function
Effective Density State in Valence Band
Go Effective Density of State in Valence Band = Holes Concentration in Valance Band/(1-Fermi Function)
Recombination Lifetime
Go Recombination Lifetime = (Proportionality for Recombination*Holes Concentration in Valance Band)^-1
Concentration of Holes in Valence Band
Go Holes Concentration in Valance Band = Effective Density of State in Valence Band*(1-Fermi Function)
Thermal Generation Rate
Go Thermal Generation = Proportionality for Recombination*(Intrinsic Carrier Concentration ^2)
Distribution Coefficient
Go Distribution Coefficient = Impurity Concentration in Solid/Impurity Concentration in Liquid
Liquid Concentration
Go Impurity Concentration in Liquid = Impurity Concentration in Solid/Distribution Coefficient
Net Rate of Change in Conduction Band
Go Proportionality for Recombination = Thermal Generation/(Intrinsic Carrier Concentration^2)
Excess Carrier Concentration
Go Excess Carrier Concentration = Optical Generation Rate*Recombination Lifetime
Optical Generation Rate
Go Optical Generation Rate = Excess Carrier Concentration/Recombination Lifetime
Photoelectron Energy
Go Photoelectron Energy = [hP]*Frequency of Incident Light
Conduction Band Energy
Go Conduction Band Energy = Energy Gap+Valence Band Energy
Valence Band Energy
Go Valence Band Energy = Conduction Band Energy-Energy Gap
Energy Gap
Go Energy Gap = Conduction Band Energy-Valence Band Energy

15 Semiconductor Carriers Calculators

Intrinsic Carrier Concentration
Go Intrinsic Carrier Concentration = sqrt(Effective Density of State in Valence Band*Effective Density of State in Conduction Band) *exp(-Energy Gap/(2*[BoltZ]*Temperature))
Carrier Lifetime
Go Carrier Lifetime = 1/(Proportionality for Recombination*(Holes Concentration in Valance Band+Electron Concentration in Conduction Band))
Radius of Nth Orbit of Electron
Go Radius of nth Orbit of Electron = ([Coulomb]*Quantum Number^2*[hP]^2)/(Mass of Particle*[Charge-e]^2)
Quantum State
Go Energy in Quantum State = (Quantum Number^2*pi^2*[hP]^2)/(2*Mass of Particle*Potential Well Length^2)
Electron Flux Density
Go Electron Flux Density = (Mean Free Path Electron/(2*Time))*Difference in Electron Concentration
Fermi Function
Go Fermi Function = Electron Concentration in Conduction Band/Effective Density of State in Conduction Band
Effective Density State in Valence Band
Go Effective Density of State in Valence Band = Holes Concentration in Valance Band/(1-Fermi Function)
Distribution Coefficient
Go Distribution Coefficient = Impurity Concentration in Solid/Impurity Concentration in Liquid
Electron Multiplication
Go Electron Multiplication = Number of Electron Out of Region/Number of Electron in Region
Excess Carrier Concentration
Go Excess Carrier Concentration = Optical Generation Rate*Recombination Lifetime
Electron Current Density
Go Electron Current Density = Total Carrier Current Density-Hole Current Density
Hole Current Density
Go Hole Current Density = Total Carrier Current Density-Electron Current Density
Mean Time Spend by Hole
Go Mean Time Spend by Hole = Optical Generation Rate*Majority Carrier Decay
Photoelectron Energy
Go Photoelectron Energy = [hP]*Frequency of Incident Light
Conduction Band Energy
Go Conduction Band Energy = Energy Gap+Valence Band Energy

Photoelectron Energy Formula

Photoelectron Energy = [hP]*Frequency of Incident Light
Ephoto = [hP]*f

How do I find Coulomb's constant?

The force is modeled based on the charge and distance, and Coulomb's constant (k) is known as a proportionality constant in the equation F=k qq/r2.

How to Calculate Photoelectron Energy?

Photoelectron Energy calculator uses Photoelectron Energy = [hP]*Frequency of Incident Light to calculate the Photoelectron Energy, The photoelectron energy is contained in discrete units rather than in a continuous distribution of energies. The quantized units of light energy can be considered as localized packets of energy, called photons is integral multiple of planks constant anf angular frequency. Photoelectron Energy is denoted by Ephoto symbol.

How to calculate Photoelectron Energy using this online calculator? To use this online calculator for Photoelectron Energy, enter Frequency of Incident Light (f) and hit the calculate button. Here is how the Photoelectron Energy calculation can be explained with given input values -> 4.7E+21 = [hP]*1.8315E+17 .

FAQ

What is Photoelectron Energy?
The photoelectron energy is contained in discrete units rather than in a continuous distribution of energies. The quantized units of light energy can be considered as localized packets of energy, called photons is integral multiple of planks constant anf angular frequency and is represented as Ephoto = [hP]*f or Photoelectron Energy = [hP]*Frequency of Incident Light. Frequency of Incident Light refers to the number of complete cycles of electromagnetic waves passing through a given point in space per unit time.
How to calculate Photoelectron Energy?
The photoelectron energy is contained in discrete units rather than in a continuous distribution of energies. The quantized units of light energy can be considered as localized packets of energy, called photons is integral multiple of planks constant anf angular frequency is calculated using Photoelectron Energy = [hP]*Frequency of Incident Light. To calculate Photoelectron Energy, you need Frequency of Incident Light (f). With our tool, you need to enter the respective value for Frequency of Incident Light 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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