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Energy of i-th State is defined as the total quantity of energy present in a particular energy state. Check FAQs
εi=1β(ln(gni-1)-α)
εi - Energy of i-th State?β - Lagrange's Undetermined Multiplier 'β'?g - Number of Degenerate States?ni - Number of particles in i-th State?α - Lagrange's Undetermined Multiplier 'α'?

Determination of Energy of I-th State for Fermi-Dirac Statistics Example

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Here is how the Determination of Energy of I-th State for Fermi-Dirac Statistics equation looks like with Values.

Here is how the Determination of Energy of I-th State for Fermi-Dirac Statistics equation looks like with Units.

Here is how the Determination of Energy of I-th State for Fermi-Dirac Statistics equation looks like.

40054.1308Edit=10.0001Edit(ln(3Edit0.0002Edit-1)-5.0324Edit)
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Determination of Energy of I-th State for Fermi-Dirac Statistics Solution

Follow our step by step solution on how to calculate Determination of Energy of I-th State for Fermi-Dirac Statistics?

FIRST Step Consider the formula
εi=1β(ln(gni-1)-α)
Next Step Substitute values of Variables
εi=10.0001J(ln(30.0002-1)-5.0324)
Next Step Prepare to Evaluate
εi=10.0001(ln(30.0002-1)-5.0324)
Next Step Evaluate
εi=40054.1308053579J
LAST Step Rounding Answer
εi=40054.1308J

Determination of Energy of I-th State for Fermi-Dirac Statistics Formula Elements

Variables
Functions
Energy of i-th State
Energy of i-th State is defined as the total quantity of energy present in a particular energy state.
Symbol: εi
Measurement: EnergyUnit: J
Note: Value can be positive or negative.
Lagrange's Undetermined Multiplier 'β'
Lagrange's Undetermined Multiplier 'β' is denoted by 1/kT. Where, k= Boltzmann constant, T= temperature.
Symbol: β
Measurement: EnergyUnit: J
Note: Value can be positive or negative.
Number of Degenerate States
Number of Degenerate States can be defined as the number of energy states that have the same energy.
Symbol: g
Measurement: NAUnit: Unitless
Note: Value can be positive or negative.
Number of particles in i-th State
Number of particles in i-th State can be defined as the total number of particles present in a particular energy state.
Symbol: ni
Measurement: NAUnit: Unitless
Note: Value can be positive or negative.
Lagrange's Undetermined Multiplier 'α'
Lagrange's Undetermined Multiplier 'α' is denoted by μ/kT, Where μ= chemical potential; k= Boltzmann constant; T= temperature.
Symbol: α
Measurement: NAUnit: Unitless
Note: Value can be positive or negative.
ln
The natural logarithm, also known as the logarithm to the base e, is the inverse function of the natural exponential function.
Syntax: ln(Number)

Other Formulas to find Energy of i-th State

​Go Determination of Energy of I-th State for Bose-Einstein Statistics
εi=1β(ln(gni-1)-α)

Other formulas in Indistinguishable Particles category

​Go Mathematical Probability of Occurrence of Distribution
ρ=WWtot
​Go Boltzmann-Planck Equation
S=[BoltZ]ln(W)
​Go Determination of Helmholtz Free Energy using Molecular PF for Indistinguishable Particles
A=-NA[BoltZ]T(ln(qNA)+1)
​Go Determination of Gibbs Free energy using Molecular PF for Indistinguishable Particles
G=-NA[BoltZ]Tln(qNA)

How to Evaluate Determination of Energy of I-th State for Fermi-Dirac Statistics?

Determination of Energy of I-th State for Fermi-Dirac Statistics evaluator uses Energy of i-th State = 1/Lagrange's Undetermined Multiplier 'β'*(ln(Number of Degenerate States/Number of particles in i-th State-1)-Lagrange's Undetermined Multiplier 'α') to evaluate the Energy of i-th State, The Determination of Energy of I-th State for Fermi-Dirac Statistics formula is defined as the amount of energy present in a particular state. Energy of i-th State is denoted by εi symbol.

How to evaluate Determination of Energy of I-th State for Fermi-Dirac Statistics using this online evaluator? To use this online evaluator for Determination of Energy of I-th State for Fermi-Dirac Statistics, enter Lagrange's Undetermined Multiplier 'β' (β), Number of Degenerate States (g), Number of particles in i-th State (ni) & Lagrange's Undetermined Multiplier 'α' (α) and hit the calculate button.

FAQs on Determination of Energy of I-th State for Fermi-Dirac Statistics

What is the formula to find Determination of Energy of I-th State for Fermi-Dirac Statistics?
The formula of Determination of Energy of I-th State for Fermi-Dirac Statistics is expressed as Energy of i-th State = 1/Lagrange's Undetermined Multiplier 'β'*(ln(Number of Degenerate States/Number of particles in i-th State-1)-Lagrange's Undetermined Multiplier 'α'). Here is an example- 40054.13 = 1/0.00012*(ln(3/0.00016-1)-5.0324).
How to calculate Determination of Energy of I-th State for Fermi-Dirac Statistics?
With Lagrange's Undetermined Multiplier 'β' (β), Number of Degenerate States (g), Number of particles in i-th State (ni) & Lagrange's Undetermined Multiplier 'α' (α) we can find Determination of Energy of I-th State for Fermi-Dirac Statistics using the formula - Energy of i-th State = 1/Lagrange's Undetermined Multiplier 'β'*(ln(Number of Degenerate States/Number of particles in i-th State-1)-Lagrange's Undetermined Multiplier 'α'). This formula also uses Natural Logarithm (ln) function(s).
What are the other ways to Calculate Energy of i-th State?
Here are the different ways to Calculate Energy of i-th State-
  • Energy of i-th State=1/Lagrange's Undetermined Multiplier 'β'*(ln(Number of Degenerate States/Number of particles in i-th State-1)-Lagrange's Undetermined Multiplier 'α')OpenImg
Can the Determination of Energy of I-th State for Fermi-Dirac Statistics be negative?
Yes, the Determination of Energy of I-th State for Fermi-Dirac Statistics, measured in Energy can be negative.
Which unit is used to measure Determination of Energy of I-th State for Fermi-Dirac Statistics?
Determination of Energy of I-th State for Fermi-Dirac Statistics is usually measured using the Joule[J] for Energy. Kilojoule[J], Gigajoule[J], Megajoule[J] are the few other units in which Determination of Energy of I-th State for Fermi-Dirac Statistics can be measured.
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