Debye length

In plasmas and electrolytes the Debye length (also called Debye radius), named after the Dutch physicist and physical chemist Peter Debye, is the measure of a charge carrier's net electrostatic effect in solution, and how far those electrostatic effects persist. A Debye sphere is a volume whose radius is the Debye length, with each Debye length, charges are increasingly electrically screened. Every Debye‐length, the electric potential will decrease in magnitude by 1/e. The notion of Debye length plays an important role in plasma physics, electrolytes and colloids (DLVO theory).

Physical origin

The Debye length arises naturally in the thermodynamic description of large systems of mobile charges. In a system of $N$ different species of charges, the $j$ -th species carries charge $q_{j}$ and has concentration $n_{j}(\mathbf {r} )$ at position $\mathbf {r}$ . According to the so-called "primitive model", these charges are distributed in a continuous medium that is characterized only by its relative static permittivity, $\varepsilon _{r}$ . This distribution of charges within this medium gives rise to an electric potential $\Phi (\mathbf {r} )$ that satisfies Poisson's equation:

\varepsilon \nabla ^{2}\Phi (\mathbf {r} )=-\,\sum _{j=1}^{N}q_{j}\,n_{j}(\mathbf {r} )-\rho _{E}(\mathbf {r} )

where $\varepsilon \equiv \varepsilon _{r}\varepsilon _{0}$ , $\varepsilon _{0}$ is the electric constant, and $\rho _{E}$ is a charge density external (logically, not spatially) to the medium.

The mobile charges not only establish $\Phi (\mathbf {r} )$ but also move in response to the associated Coulomb force, $-q_{j}\,\nabla \Phi (\mathbf {r} )$ . If we further assume the system to be in thermodynamic equilibrium with a heat bath at absolute temperature $T$ , then the concentrations of discrete charges, $n_{j}(\mathbf {r} )$ , may be considered to be thermodynamic (ensemble) averages and the associated electric potential to be a thermodynamic mean field. With these assumptions, the concentration of the $j$ -th charge species is described by the Boltzmann distribution,

n_{j}(\mathbf {r} )=n_{j}^{0}\,\exp \left(-{\frac {q_{j}\,\Phi (\mathbf {r} )}{k_{B}T}}\right)

where $k_{B}$ is Boltzmann's constant and where $n_{j}^{0}$ is the mean concentration of charges of species $j$ .

Identifying the instantaneous concentrations and potential in the Poisson equation with their mean-field counterparts in Boltzmann's distribution yields the Poisson–Boltzmann equation:

\varepsilon \nabla ^{2}\Phi (\mathbf {r} )=-\,\sum _{j=1}^{N}q_{j}n_{j}^{0}\,\exp \left(-{\frac {q_{j}\,\Phi (\mathbf {r} )}{k_{B}T}}\right)-\rho _{E}(\mathbf {r} )

Solutions to this nonlinear equation are known for some simple systems. Solutions for more general systems may be obtained in the high-temperature (weak coupling) limit, $q_{j}\,\Phi (\mathbf {r} )\ll k_{B}T$ , by Taylor expanding the exponential:

\exp \left(-{\frac {q_{j}\,\Phi (\mathbf {r} )}{k_{B}T}}\right)\approx 1-{\frac {q_{j}\,\Phi (\mathbf {r} )}{k_{B}T}}

This approximation yields the linearized Poisson-Boltzmann equation

\varepsilon \nabla ^{2}\Phi (\mathbf {r} )=\left(\sum _{j=1}^{N}{\frac {n_{j}^{0}\,q_{j}^{2}}{k_{B}T}}\right)\,\Phi (\mathbf {r} )-\,\sum _{j=1}^{N}n_{j}^{0}q_{j}-\rho _{E}(\mathbf {r} )

which also is known as the Debye–Hückel equation:^[1]^[2]^[3]^[4]^[5] The second term on the right-hand side vanishes for systems that are electrically neutral. The term in parentheses divided by $\varepsilon$ , has the units of an inverse length squared and by dimensional analysis leads to the definition of the characteristic length scale

\lambda _{D}=\left({\frac {\varepsilon \,k_{B}T}{\sum _{j=1}^{N}n_{j}^{0}\,q_{j}^{2}}}\right)^{1/2}

that commonly is referred to as the Debye–Hückel length. As the only characteristic length scale in the Debye–Hückel equation, $\lambda _{D}$ sets the scale for variations in the potential and in the concentrations of charged species. All charged species contribute to the Debye–Hückel length in the same way, regardless of the sign of their charges. For an electrically neutral system, the Poisson equation becomes

\nabla ^{2}\Phi (\mathbf {r} )=\lambda _{D}^{-2}\Phi (\mathbf {r} )-{\frac {\rho _{E}(\mathbf {r} )}{\varepsilon }}

To illustrate Debye screening, the potential produced by an external point charge $\rho _{E}=Q\delta (\mathbf {r} )$ is

\Phi (\mathbf {r} )={\frac {Q}{4\pi \varepsilon r}}e^{-r/\lambda _{D}}

The bare Coulomb potential is exponentially screened by the medium, over a distance of the Debye length.

The Debye–Hückel length may be expressed in terms of the Bjerrum length $\lambda _{B}$ as

\lambda _{D}=\left(4\pi \,\lambda _{B}\,\sum _{j=1}^{N}n_{j}^{0}\,z_{j}^{2}\right)^{-1/2}

where $z_{j}=q_{j}/e$ is the integer charge number that relates the charge on the $j$ -th ionic species to the elementary charge $e$ .

Typical values

In space plasmas where the electron density is relatively low, the Debye length may reach macroscopic values, such as in the magnetosphere, solar wind, interstellar medium and intergalactic medium (see table):

Plasma	Density n_e(m⁻³)	Electron temperature T(K)	Magnetic field B(T)	Debye length λ_D(m)
Solar core	10³²	10⁷	--	10⁻¹¹
Tokamak	10²⁰	10⁸	10	10⁻⁴
Gas discharge	10¹⁶	10⁴	--	10⁻⁴
Ionosphere	10¹²	10³	10⁻⁵	10⁻³
Magnetosphere	10⁷	10⁷	10⁻⁸	10²
Solar wind	10⁶	10⁵	10⁻⁹	10
Interstellar medium	10⁵	10⁴	10⁻¹⁰	10
Intergalactic medium	1	10⁶	--	10⁵
Source: Chapter 19: The Particle Kinetics of Plasma http://www.pma.caltech.edu/Courses/ph136/yr2004/

Hannes Alfvén pointed out that: "In a low density plasma, localized space charge regions may build up large potential drops over distances of the order of some tens of the Debye lengths. Such regions have been called electric double layers. An electric double layer is the simplest space charge distribution that gives a potential drop in the layer and a vanishing electric field on each side of the layer. In the laboratory, double layers have been studied for half a century, but their importance in cosmic plasmas has not been generally recognized."

In a plasma

In a plasma, the background medium may be treated as the vacuum ( $\varepsilon _{r}=1$ ), and the Debye length is

\lambda _{D}={\sqrt {\frac {\varepsilon _{0}k_{B}/q_{e}^{2}}{n_{e}/T_{e}+\sum _{j}z_{j}^{2}n_{j}/T_{j}}}}

where

λ_D is the Debye length,

ε₀ is the permittivity of free space,

k_B is the Boltzmann constant,

q_e is the charge of an electron,

T_e and T_i are the temperatures of the electrons and ions, respectively,

n_e is the density of electrons,

n_j is the density of atomic species j, with positive ionic charge z_jq_e

The ion term is often dropped, giving

\lambda _{D}={\sqrt {\frac {\varepsilon _{0}k_{B}T_{e}}{n_{e}q_{e}^{2}}}}

although this is only valid when the mobility of ions is negligible compared to the process's timescale.^[6]

In an electrolyte solution

In an electrolyte or a colloidal suspension, the Debye length^[7] for a monovalent electrolyte is usually denoted with symbol κ⁻¹

\kappa ^{-1}={\sqrt {\frac {\varepsilon _{r}\varepsilon _{0}k_{B}T}{2N_{A}e^{2}I}}}

where

I is the ionic strength of the electrolyte, and here the unit should be mole/m³,

ε₀ is the permittivity of free space,

ε_r is the dielectric constant,

k_B is the Boltzmann constant,

T is the absolute temperature in kelvins,

N_A is the Avogadro number.

e is the elementary charge,

or, for a symmetric monovalent electrolyte,

\kappa ^{-1}={\sqrt {\frac {\varepsilon _{r}\varepsilon _{0}RT}{2F^{2}C_{0}}}}

where

R is the gas constant,

F is the Faraday constant,

C₀ is the molar concentration of the electrolyte.

Alternatively,

\kappa ^{-1}={\frac {1}{\sqrt {8\pi \lambda _{B}N_{A}I}}}

where

\lambda _{B}

is the Bjerrum length of the medium.

For water at room temperature, λ_B ≈ 0.7 nm.

At room temperature (25 °C), one can consider in water for 1:1 electrolytes the relation:^[8]

\kappa ^{-1}(\mathrm {nm} )={\frac {0.304}{\sqrt {I(\mathrm {M} )}}}

where

κ⁻¹ is expressed in nanometers (nm)

I is the ionic strength expressed in molar (M or mol/L)

In semiconductors

The Debye length has become increasingly significant in the modeling of solid state devices as improvements in lithographic technologies have enabled smaller geometries.^[9]^[10]^[11]

The Debye length of semiconductors is given:

{\mathit {L}}_{D}={\sqrt {\frac {\varepsilon k_{B}T}{q^{2}N_{d}}}}

where

ε is the dielectric constant,

k_B is the Boltzmann's constant,

T is the absolute temperature in kelvins,

q is the elementary charge, and

N_d is the density of dopants (either donors or acceptors).

When doping profiles exceed the Debye length, majority carriers no longer behave according to the distribution of the dopants. Instead, a measure of the profile of the doping gradients provides an "effective" profile that better matches the profile of the majority carrier density.

In the context of solids, the Debye length is also called the Thomas–Fermi screening length.

References

↑ Kirby BJ. Micro- and Nanoscale Fluid Mechanics: Transport in Microfluidic Devices.
↑ Li D (2004). Electrokinetics in Microfluidics.
↑ PC Clemmow & JP Dougherty (1969). Electrodynamics of particles and plasmas. Redwood City CA: Addison-Wesley. pp. § 7.6.7, p. 236 ff. ISBN 0-201-47986-9.
↑ RA Robinson &RH Stokes (2002). Electrolyte solutions. Mineola, NY: Dover Publications. p. 76. ISBN 0-486-42225-9.
↑ See Brydges, David C.; Martin, Ph. A. (1999). "Coulomb Systems at Low Density: A Review". Journal of Statistical Physics. 96 (5/6): 1163–1330. arXiv:cond-mat/9904122. Bibcode:1999JSP....96.1163B. doi:10.1023/A:1004600603161.
↑ I. H. Hutchinson Principles of plasma diagnostics ISBN 0-521-38583-0
↑ Russel, W.B., Saville, D.A. and Schowalter, W. R. Colloidal Dispersions, Cambridge University Press, 1989
↑ Israelachvili, J., Intermolecular and Surface Forces, Academic Press Inc., 1985, ISBN 0-12-375181-0
↑ Stern, Eric; Robin Wagner; Fred J. Sigworth; Ronald Breaker; Tarek M. Fahmy; Mark A. Reed (2007-11-01). "Importance of the Debye Screening Length on Nanowire Field Effect Transistor Sensors". Nano Letters. 7 (11): 3405–3409. Bibcode:2007NanoL...7.3405S. doi:10.1021/nl071792z.
↑ Guo, Lingjie; Effendi Leobandung; Stephen Y. Chou (199). "A room-temperature silicon single-electron metal–oxide–semiconductor memory with nanoscale floating-gate and ultranarrow channel". Applied Physics Letters. 70 (7): 850. Bibcode:1997ApPhL..70..850G. doi:10.1063/1.118236.
↑ Tiwari, Sandip; Farhan Rana; Kevin Chan; Leathen Shi; Hussein Hanafi (1996). "Single charge and confinement effects in nano-crystal memories". Applied Physics Letters. 69 (9): 1232. Bibcode:1996ApPhL..69.1232T. doi:10.1063/1.117421.

Debye length

Physical origin

Typical values

In a plasma

In an electrolyte solution

In semiconductors

See also

References

Further reading