The Fermi level is the total chemical potential for electrons (or electrochemical potential for electrons) and is usually denoted by µ or E_{F}.^{[1]} The Fermi level of a body is a thermodynamic quantity, and its significance is the thermodynamic work required to add one electron to the body (not counting the work required to remove the electron from wherever it came from). A precise understanding of the Fermi level—how it relates to electronic band structure in determining electronic properties, how it relates to the voltage and flow of charge in an electronic circuit—is essential to an understanding of solidstate physics.
In a band structure picture, the Fermi level can be considered to be a hypothetical energy level of an electron, such that at thermodynamic equilibrium this energy level would have a 50% probability of being occupied at any given time. The Fermi level does not necessarily correspond to an actual energy level (in an insulator the Fermi level lies in the band gap), nor does it even require the existence of a band structure. Nonetheless, the Fermi level is a precisely defined thermodynamic quantity, and differences in Fermi level can be measured simply with a voltmeter.
Contents

The Fermi level and voltage 1

The Fermi level and band structure 2

Local conduction band referencing, internal chemical potential, and the parameter ζ 2.1

The Fermi level and temperature out of equilibrium 3

Technicalities 4

Terminology problems 4.1

Fermi level referencing and the location of zero Fermi level 4.2

Why it is not advisable to use "the energy in vacuum" as a reference zero 4.2.1

Discrete charging effects in small systems 4.3

Footnotes and references 5
The Fermi level and voltage
Sometimes it is said that electric currents are driven by differences in electrostatic potential (Galvani potential), but this is not exactly true.^{[2]} As a counterexample, multimaterial devices such as p–n junctions contain internal electrostatic potential differences at equilibrium, yet without any accompanying current; if a voltmeter is attached to the junction, one simply measures zero volts.^{[3]} Clearly, the electrostatic potential is not the only factor influencing the flow of charge in a material—Pauli repulsion and thermal effects also play an important role.
In fact, the quantity called "voltage" as measured in an electronic circuit has a simple relationship to the chemical potential for electrons (Fermi level). When the leads of a voltmeter are attached to two points in a circuit, the displayed voltage is a measure of the total work that can be obtained, per unit charge, by allowing a tiny amount of charge to flow from one point to the other. If a simple wire is connected between two points of differing voltage (forming a short circuit), current will flow from positive to negative voltage, converting the available work into heat.
The Fermi level of a body expresses the work required to add an electron to it, or equally the work obtained by removing an electron. Therefore, the observed difference (V_{A}V_{B}) in voltage between two points "A" and "B" in an electronic circuit is exactly related to the corresponding chemical potential difference (µ_{A}µ_{B}) in Fermi level by the formula^{[4]}

(V_{\mathrm{A}}V_{\mathrm{B}}) = (\mu_{\mathrm{A}}\mu_{\mathrm{B}})/e
where e is the electron charge.
From the above discussion it can be seen that electrons will move from a body of high µ (low voltage) to low µ (high voltage) if a simple path is provided. This flow of electrons will cause the lower µ to increase (due to charging or other repulsion effects) and likewise cause the higher µ to decrease. Eventually, µ will settle down to the same value in both bodies. This leads to an important fact regarding the equilibrium (off) state of an electronic circuit:

An electronic circuit in thermodynamic equilibrium will have a constant Fermi level throughout its connected parts.
This also means that the voltage (measured with a voltmeter) between any two points will be zero, at equilibrium. Note that thermodynamic equilibrium here requires that the circuit be internally connected and not contain any batteries or other power sources, nor any variations in temperature.
The Fermi level and band structure
In the band theory of solids, electrons are considered to occupy a series of bands composed of singleparticle energy eigenstates each labelled by ϵ. Although this single particle picture is an approximation, it greatly simplifies the understanding of electronic behaviour and it generally provides correct results when applied correctly.
The Fermi–Dirac distribution f(\epsilon) gives the probability that (at thermodynamic equilibrium) an electron will occupy a state having energy ϵ. Alternatively, it gives the average number of electrons that will occupy that state given the restriction imposed by the Pauli exclusion principle:^{[5]}

f(\epsilon) = \frac{1}{e^{(\epsilon\mu) / (k T)} + 1}
Here, T is the absolute temperature and k is Boltzmann's constant. If there is a state at the Fermi level (ϵ = µ), then this state will have a 50% chance of being occupied at any given time.
The location of µ within a material's band structure is important in determining the electrical behaviour of the material.

In an insulator, µ lies within a large band gap, far away from any states that are able to carry current.

In a metal, semimetal or degenerate semiconductor, µ lies within a delocalized band. A large number of states nearby µ are thermally active and readily carry current.

In an intrinsic or lightly doped semiconductor, µ is close enough to a band edge that there are a dilute number of thermally excited carriers residing near that band edge.
In semiconductors and semimetals the position of µ relative to the band structure can usually be controlled to a significant degree by doping or gating. These controls do not change µ which is fixed by the electrodes, but rather they cause the entire band structure to shift up and down (sometimes also changing the band structure's shape). For further information about the Fermi levels of semiconductors, see (for example) Sze. ^{[6]}
Local conduction band referencing, internal chemical potential, and the parameter ζ
If the symbol ℰ is used to denote an electron energy level measured relative to the energy of the edge of its enclosing band, ϵ_{C}, then in general we have ℰ = ϵ – ϵ_{C}, and in particular we can define the parameter ζ ^{[7]} by referencing the Fermi level to the band edge:

\zeta = \mu  \epsilon_{\rm C}.
It follows that the Fermi–Dirac distribution function can also be written

f(\mathcal{E}) = \frac{1}{e^{(\mathcal{E}\zeta)/(kT)}+1}.
The band theory of metals was initially developed by Sommerfeld, from 1927 onwards, who paid great attention to the underlying thermodynamics and statistical mechanics. Confusingly, in some contexts the bandreferenced quantity ζ may be called the "Fermi level", "chemical potential" or "electrochemical potential", leading to ambiguity with the globallyreferenced Fermi level. In this article the terms "conductionband referenced Fermi level" or "internal chemical potential" are used to refer to ζ.
ζ is directly related to the number of active charge carriers as well as their typical kinetic energy, and hence it is directly involved in determining the local properties of the material (such as electrical conductivity). For this reason it is common to focus on the value of ζ when concentrating on the properties of electrons in a single, homogeneous conductive material. By analogy to the energy states of a free electron, the ℰ of a state is the kinetic energy of that state and ϵ_{C} is its potential energy. With this in mind, the parameter ζ could also be labelled the "Fermi kinetic energy".
Unlike µ, the parameter ζ is not a constant at equilibrium, but rather varies from location to location in a material due to variations in ϵ_{C}, which is determined by factors such as material quality and impurities/dopants. Near the surface of a semiconductor or semimetal, ζ can be strongly controlled by externally applied electric fields, as is done in a field effect transistor. In a multiband material, ζ may even take on multiple values in a single location. For example, in a piece of aluminum metal there are two conduction bands crossing the Fermi level (even more bands in other materials);^{[8]} each band has a different edge energy ϵ_{C} and a different value of ζ.
The value of ζ at zero temperature is widely known as the Fermi energy, sometimes written ζ_{0}. Confusingly (again), the name "Fermi energy" sometimes is used to refer to ζ at nonzero temperature.
The Fermi level and temperature out of equilibrium
The Fermi level μ and temperature T are well defined constants for a solidstate device in thermodynamic equilibrium situation, such as when it is sitting on the shelf doing nothing. When the device is brought out of equilibrium and put into use, then strictly speaking the Fermi level and temperature are no longer well defined. Fortunately, it is often possible to define a quasiFermi level and quasitemperature for a given location, that accurately describe the occupation of states in terms of a thermal distribution. The device is said to be in 'quasiequilibrium' when and where such a description is possible.
The quasiequilibrium approach allows one to build a simple picture of some nonequilibrium effects as the electrical conductivity of a piece of metal (as resulting from a gradient in μ) or its thermal conductivity (as resulting from a gradient in T). The quasiμ and quasiT can vary (or not exist at all) in any nonequilibrium situation, such as:

If the system contains a chemical imbalance (as in a battery).

If the system is exposed to changing electromagnetic fields. (as in capacitors, inductors, and transformers).

Under illumination from a lightsource with a different temperature, such as the sun (as in solar cells),

When the temperature is not constant within the device (as in thermocouples),

When the device has been altered, but has not had enough time to reequilibrate (as in piezoelectric or pyroelectric substances).
In some situations, such as immediately after a material experiences a highenergy laser pulse, the electron distribution cannot be described by any thermal distribution. One cannot define the quasiFermi level or quasitemperature in this case; the electrons are simply said to be "nonthermalized". In less dramatic situations, such as in a solar cell under constant illumination, a quasiequilibrium description may be possible but requiring the assignment of distinct values of μ and T to different bands (conduction band vs. valence band). Even then, the values of μ and T may jump discontinuously across a material interface (e.g., p–n junction) when a current is being driven, and be illdefined at the interface itself.
Technicalities
Terminology problems
The term "Fermi level" is mainly used in discussing the solid state physics of electrons in semiconductors, and a precise usage of this term is necessary to describe band diagrams in devices comprising different materials with different levels of doping. In these contexts, however, one may also see Fermi level used imprecisely to refer to the bandreferenced Fermi level µϵ_{C}, called ζ above. It is common to see scientists and engineers refer to "controlling", "pinning", or "tuning" the Fermi level inside a conductor, when they are in fact describing changes in ϵ_{C} due to doping or the field effect. In fact, thermodynamic equilibrium guarantees that the Fermi level in a conductor is always fixed to be exactly equal to the Fermi level of the electrodes; only the band structure (not the Fermi level) can be changed by doping or the field effect (see also band diagram). A similar ambiguity exists between the terms "chemical potential" and "electrochemical potential".
It is also important to note that Fermi level is not necessarily the same thing as Fermi energy. In the wider context of quantum mechanics, the term Fermi energy usually refers to the maximum kinetic energy of a fermion in an idealized noninteracting, disorder free, zero temperature Fermi gas. This concept is very theoretical (there is no such thing as a noninteracting Fermi gas, and zero temperature is impossible to achieve). However, it finds some use in approximately describing white dwarfs, neutron stars, atomic nuclei, and electrons in a metal. On the other hand, in the fields of semiconductor physics and engineering, "Fermi energy" often is used to refer to the Fermi level described in this article.^{[9]}
Fermi level referencing and the location of zero Fermi level
Much like the choice of origin in a coordinate system, the zero point of energy can be defined arbitrarily. Observable phenomena only depend on energy differences. When comparing distinct bodies, however, it is important that they all be consistent in their choice of the location of zero energy, or else nonsensical results will be obtained. It can therefore be helpful to explicitly name a common point to ensure that different components are in agreement. On the other hand, if a reference point is inherently ambiguous (such as "the vacuum", see below) it will instead cause more problems.
A practical and welljustified choice of common point is a bulky, physical conductor, such as the electrical ground or earth. Such a conductor can be considered to be in a good thermodynamic equilibrium and so its µ is well defined. It provides a reservoir of charge, so that large numbers of electrons may be added or removed without incurring charging effects. It also has the advantage of being accessible, so that the Fermi level of any other object can be measured simply with a voltmeter.
Why it is not advisable to use "the energy in vacuum" as a reference zero
When the two metals depicted here are in thermodynamic equilibrium as shown (equal Fermi levels E
_{F}), the vacuum
electrostatic potential ϕ is not flat due to a difference in
work function.
In principle, one might consider using the state of a stationary electron in the vacuum as a reference point for energies. This approach is not advisable unless one is careful to define exactly where "the vacuum" is.^{[10]} The problem is that not all points in the vacuum are equivalent.
At thermodynamic equilibrium, it is typical for electrical potential differences of order 1 V to exist in the vacuum (Volta potentials). The source of this vacuum potential variation is the variation in work function between the different conducting materials exposed to vacuum. Just outside a conductor, the electrostatic potential depends sensitively on the material, as well as which surface is selected (its crystal orientation, contamination, and other details).
The parameter that gives the best approximation to universality is the Earthreferenced Fermi level suggested above. This also has the advantage that it can be measured with a voltmeter.
Discrete charging effects in small systems
In cases where the "charging effects" due to a single electron are nonnegligible, the above definitions should be clarified. For example, consider a capacitor made of two identical parallelplates. If the capacitor is uncharged, the Fermi level is the same on both sides, so one might think that it should take no energy to move an electron from one plate to the other. But when the electron has been moved, the capacitor has become (slightly) charged, so this does take a slight amount of energy. In a normal capacitor, this is negligible, but in a nanoscale capacitor it can be more important.
In this case one must be precise about the thermodynamic definition of the chemical potential as well as the state of the device: is it electrically isolated, or is it connected to an electrode?

When the body is able to exchange electrons and energy with an electrode (reservoir), it is described by the grand canonical ensemble. The value of chemical potential µ can be said to be fixed by the electrode, and the number of electrons N on the body may fluctuate. In this case, the chemical potential of a body is the infinitesimal amount of work needed to increase the average number of electrons by an infinitesimal amount (even though the number of electrons at any time is an integer, the average number varies continuously.):

\mu(\langle N\rangle,T) = \left(\frac{\partial F}{\partial \langle N\rangle}\right)_{T},
where F(N, T) is the free energy function of the grand canonical ensemble.

If the number of electrons in the body is fixed (but the body is still thermally connected to a heat bath), then it is in the canonical ensemble. We can define a "chemical potential" in this case literally as the work required to add one electron to a body that already has exactly N electrons,^{[11]}

\mu'(N,T) = F(N+1,T)  F(N,T),
where F(N, T) is the free energy function of the canonical ensemble, or alternatively as the work obtained by removing an electron from that body,

\mu''(N,T) = F(N,T)  F(N1,T) = \mu'(N1,T).
These chemical potentials are not equivalent, µ ≠ µ' ≠ µ'', except in the thermodynamic limit. The distinction is important in small systems such as those showing Coulomb blockade.^{[12]} The parameter µ (i.e., in the case where the number of electrons is allowed to fluctuate) remains exactly related to the voltmeter voltage, even in small systems. To be precise, then, the Fermi level is defined not by a deterministic charging event by one electron charge, but rather a statistical charging event by an infinitesimal fraction of an electron.
Footnotes and references

^

^ I. Riess, What does a voltmeter measure? Solid State Ionics 95, 327 (1197) [2]

^ Sah, ChihTang (1991). Fundamentals of SolidState Electronics. World Scientific. p. 404.

^

^

^ Sze, S. M. (1964). Physics of Semiconductor Devices. Wiley.

^ Sommerfeld, Arnold (1964). Thermodynamics and Statistical Mechanics. Academic Press.

^ "3D Fermi Surface Site". Phys.ufl.edu. 19980527. Retrieved 20130422.

^ For example: D. Chattopadhyay (2006). Electronics (fundamentals And Applications).

^ Technically, it is possible to consider the vacuum to be an insulator and in fact its Fermi level is defined if its surroundings are in equilibrium. Typically however the Fermi level is two to five electron volts below the vacuum electrostatic potential energy, depending on the work function of the nearby vacuum wall material. Only at high temperatures will the equilibrium vacuum be populated with a significant number of electrons (this is the basis of thermionic emission).

^ Shegelski, Mark R. A. (May 2004). "The chemical potential of an ideal intrinsic semiconductor". American Journal of Physics 72 (5): 676–678.

^ Beenakker, C. W. J. (1991). "Theory of Coulombblockade oscillations in the conductance of a quantum dot". Physical Review B 44 (4): 1646.
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