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==Alternative unit systems==
==Alternative unit systems==
{{main|Centimetre gram second system of units#Alternative ways of deriving CGS units in electromagnetism|l1=Alternative CGS units in electromagnetism}}
{{main|Centimetre gram second system of units#Alternative ways of deriving CGS units in electromagnetism|l1=Alternative CGS units in electromagnetism}}
The main alternative to the Gaussian unit system is [[International System of Units|SI units]], historically also called the [[MKS system of units]] for metres-kilogram-seconds.<ref name=Rowlett/>
The main alternative to the Gaussian unit system is [[International System of Units|SI units]], historically also called the [[MKS system of units]] for metre-kilogram-second.<ref name=Rowlett/>


The Gaussian unit system is just one of several electromagnetic unit systems within CGS. Others include "[[Centimetre gram second system of units#Electrostatic units (ESU)|electrostatic units]]", "[[Centimetre gram second system of units#Electromagnetic units (EMU)|electromagnetic units]]", and [[Lorentz–Heaviside units]].
The Gaussian unit system is just one of several electromagnetic unit systems within CGS. Others include "[[Centimetre gram second system of units#Electrostatic units (ESU)|electrostatic units]]", "[[Centimetre gram second system of units#Electromagnetic units (EMU)|electromagnetic units]]", and [[Lorentz–Heaviside units]].

Revision as of 02:47, 23 January 2012

Carl Gauss

Gaussian units comprise a metric system of physical units. This system is the most common of the several electromagnetic unit systems based on cgs (centimetre-gram-second) units. It is also called the Gaussian unit system, Gaussian-cgs units, or often just cgs units.[1] The term "cgs units" is ambiguous and therefore to be avoided if possible: cgs contains within it several conflicting sets of electromagnetism units, not just Gaussian units, as described below.

The most common alternative to Gaussian units are SI units. SI units are predominant in most fields, and continue to increase in popularity at the expense of Gaussian units.[2][3] (Other alternative unit systems also exist, as discussed below.) Conversions between Gaussian units and SI units are not as simple as normal unit conversions. For example, the formulas for physical laws of electromagnetism (such as Maxwell's equations) need to be adjusted depending on what system of units one uses. As another example, quantities that are unitless in one system may have dimensions in another.

Alternative unit systems

The main alternative to the Gaussian unit system is SI units, historically also called the MKS system of units for metre-kilogram-second.[2]

The Gaussian unit system is just one of several electromagnetic unit systems within CGS. Others include "electrostatic units", "electromagnetic units", and Lorentz–Heaviside units.

Some other unit systems are called "natural units", a category that includes atomic units, Planck units, and others. These are closer to CGS units than to SI units in some respects.[4]

SI units are by far the most common today. In engineering and practical areas, SI is near-universal and has been for decades,[2] while in technical, scientific literature (such as theoretical physics and astronomy), Gaussian units were predominant until recent decades, but are now getting progressively less so.[2][3]

Natural units are most common in more theoretical and abstract fields of physics, particularly particle physics and string theory.

Major differences between Gaussian and SI units

"Rationalized" unit systems

One difference between Gaussian and SI units is in the factors of 4π in various formulas. SI is called "rationalized",[5][6] because Maxwell's equations have no explicit factors of 4π in the formulas. On the other hand, the force laws, Coulomb's law and the Biot–Savart law, do have factors of 4π in them. In Gaussian units, which are not "rationalized", the situation is reversed: Two of Maxwell's equations have factors of 4π in the formulas, while both of the force laws, Coulomb's law and the Biot–Savart law, have no factors of 4π.

Unit of charge

A major difference between Gaussian and SI units is in the definition of the unit of charge. In SI, a separate base unit (the ampere) is associated with electrical phenomena, with the consequence that something like electrical charge (1 coulomb=1 ampere × 1 second) cannot be expressed purely in terms of the mechanical units (kilogram, metre, second). On the other hand, in Gaussian units, the unit of electrical charge (the statcoulomb, statC) can be written entirely as a dimensional combination of the mechanical units (gram, centimetre, second), as:

1 statC = 1 g1/2 cm3/2 s−1

For example, Coulomb's law in cgs units is particularly simple:

where F is the repulsive force between two electrical charges, Q1 and Q2 are the two charges in question, and r is the distance separating them. If Q1 and Q2 are expressed in statC and r in cm, then F will come out expressed in dyne.

By contrast, the same law in SI units is:

where ε0 is the vacuum permitivity, a quantity with dimensions, namely A2 s4 kg−1 m−3. Without ε0, the two sides could not have consistent dimensions in SI, and in fact the quantity ε0 does not even exist in Gaussian units.

Units for magnetism

In Gaussian units, unlike SI units, the electric field E and the magnetic field B have the same dimension. This amounts to a factor of c difference between how B is defined in the two unit systems, on top of the other differences.[5] (The same factor applies to other magnetic quantities such as H and M.) For example, in a planar light wave in vacuum, |E(r,t)|=|B(r,t)| in Gaussian units, while |E(r,t)|=c|B(r,t)| in SI units.

Polarization, magnetization

There are further differences between Gaussian and SI units in how quantities related to polarization and magnetization are defined. For one thing, in Gaussian units, all of the following quantities have the same dimension: E, D, P, B, H, and M. Another important point is that the electric and magnetic susceptibility of a material is dimensionless in both Gaussian and SI units, but a given material will have a different numerical susceptibility in the two systems. (Equation is given below.)

List of equations

This section has a list of the basic formulae of electromagnetism, given in both Gaussian and SI units. Most symbol names are not given; for complete explanations and definitions, please click to the appropriate dedicated article for each equation. All formulas except otherwise noted are from Ref.[5]

Maxwell's equations

Here are Maxwell's equations, both in macroscopic and microscopic forms. Only the "differential form" of the equations is given, not the "integral form"; to get the integral forms apply the divergence theorem or Kelvin–Stokes theorem.

Name Gaussian units SI units
Gauss's law
(macroscopic)
Gauss's law
(microscopic)
Gauss's law for magnetism:
Maxwell–Faraday equation
(Faraday's law of induction):
Ampère–Maxwell equation
(macroscopic):
Ampère–Maxwell equation
(microscopic):

Other basic laws

Name Gaussian units SI units
Lorentz force
Coulomb's law
Electric field of
stationary point charge
Biot–Savart law

Dielectric and magnetic materials

Below are the expressions for the various fields in a dielectric medium. It is assumed here for simplicity that the medium is homogeneous, linear, isotropic, and nondispersive, so that the permittivity is a simple constant.

Gaussian units SI units

where

The quantities in Gaussian units and in SI are both dimensionless, and they have the same numeric value. By contrast, the electric susceptibility is unitless in both systems, but has different numeric values in the two systems for the same material:

Next, here are the expressions for the various fields in a magnetic medium. Again, it is assumed that the medium is homogeneous, linear, isotropic, and nondispersive, so that the permeability is a simple constant.

Gaussian units SI units

where

The quantities in Gaussian units and in SI are both dimensionless, and they have the same numeric value. By contrast, the magnetic susceptibility is unitless in both systems, but has different numeric values in the two systems for the same material:

Vector and scalar potentials

The electric and magnetic fields can be written in terms of a vector potential A and a scalar potential φ:

Name Gaussian units SI units
Electric field
(static)
Electric field
(general)
Magnetic B field

Electromagnetic unit names

(For non-electromagnetic units, see main cgs article.)

Conversion of SI units in electromagnetism to Gaussian subsystem of CGS[7]
c = 29,979,245,800 ≈ 3·1010
Quantity Symbol SI unit Gaussian unit
electric charge q 1 C ↔ (10−1 c) Fr
electric current I 1 A ↔ (10−1 c) Fr·s−1
electric potential
voltage
φ
V
1 V ↔ (108 c−1) statV
electric field E 1 V/m ↔ (106 c−1) statV/cm
magnetic induction B 1 T ↔ (104) G
magnetic field strength H 1 A/m ↔ (4π 10−3) Oe
magnetic dipole moment μ 1 A· ↔ (103) erg/G
magnetic flux Φm 1 Wb ↔ (108) G·cm²
resistance R 1 Ω ↔ (109 c−2) s/cm
resistivity ρ 1 Ω·m ↔ (1011 c−2) s
capacitance C 1 F ↔ (10−9 c2) cm
inductance L 1 H ↔ (109 c−2) s2·cm−1

In this table, the letter c represents the number 29,979,245,800 ≈ 3·1010, the numerical value of the speed of light expressed in cm/s. The symbol "↔" was used instead of "=" as a reminder that the SI and Gaussian units are corresponding but not equal because they have incompatible dimensions. For example, according to the top row of the table, something with a charge of 1 C also has a charge of (10−1 c) Fr, but it is usually incorrect to replace "1 C" with "(10−1 c) Fr" within an equation or formula.

It is surprising to think of measuring capacitance in centimetres. One useful example is that a centimetre of capacitance is the capacitance between a sphere of radius 1 cm in vacuum and infinity.

Another surprising unit is measuring resistivity in units of seconds. A physical example is: Take a parallel-plate capacitor, which has a "leaky" dielectric with permittivity 1 but a finite resistivity. After charging it up, the capacitor will discharge itself over time, due to current leaking through the dielectric. If the resistivity of the dielectric is "X" seconds, the half-life of the discharge is ~0.05X seconds. This result is independent of the size, shape, and charge of the capacitor, and therefore this example illuminates the fundamental connection between resistivity and time-units.

Dimensionally-equivalent units

A number of the units defined by the table have different names but are in fact dimensionally equivalent—i.e., the have the same expression in terms of the base units cm, g, s. (This is analogous to the distinction in SI between becquerel and Hz, or between Newton metre and Joule.) The different names help avoid ambiguities and misunderstandings as to what physical quantity is being measured. In particular, all of the following quantities are dimensionally equivalent in Gaussian units, but they are nevertheless given different unit names as follows:[8]

Quantity In Gaussian
base units
Gaussian unit
of measure
E cm-1/2 g1/2 s−1 statV/cm
D cm-1/2 g1/2 s−1 statC/cm2
P cm-1/2 g1/2 s−1 statC/cm2
B cm-1/2 g1/2 s−1 G
H cm-1/2 g1/2 s−1 Oe
M cm-1/2 g1/2 s−1 Mx/cm2
or emu/cm3
[9]

General rules to translate a formula

To convert any formula from Gaussian units to SI units, replace the quantity in the Gaussian column by the quantity in the SI column (vice-versa to convert the other way). This will reproduce any of the specific formulas given in the list above, such as Maxwell's equations, as well as any other formula not listed.[10][11] It may also be necessary to use the relation to simplify. For some examples of how to use this table, see:[12]

Name Gaussian units SI units
Electric field, Electric potential
Electric displacement field
Charge, Charge density, Current,
Current density, Polarization density,
Electric dipole moment
Magnetic B field, Magnetic flux,
Magnetic vector potential
Magnetic H field
Magnetic moment, Magnetization
Relative permittivity,
Relative permeability
, or equivalently,
Electric susceptibility,
Magnetic susceptibility
Conductivity, Conductance,
Capacitance
Resistivity, Resistance, Inductance

Notes and references

  1. ^ One of many examples of using the term "cgs units" to refer to Gaussian units is: Lecture notes from Stanford University
  2. ^ a b c d "CGS", in How Many? A Dictionary of Units of Measurement, by Russ Rowlett and the University of North Carolina at Chapel Hill
  3. ^ a b For example, one widely-used graduate electromagnetism textbook is Classical Electrodynamics by J.D. Jackson. The second edition, published in 1975, used Gaussian units exclusively, but the third edition, published in 1998, uses mostly SI units.
  4. ^ For example, both natural units and CGS have a factor of in Gauss's law but not Coulomb's law, while SI is the other way around. Also, Gaussian units have one fewer base unit than SI units (namely, no base unit for charge), and natural units have fewer still.
  5. ^ a b c Littlejohn, Robert (Fall 2007). "Gaussian, SI and Other Systems of Units in Electromagnetic Theory" (pdf). Physics 221A, University of California, Berkeley lecture notes. Retrieved 2008-05-06.
  6. ^ Kowalski, Ludwik, 1986, "A Short History of the SI Units in Electricity," The Physics Teacher 24(2): 97-99. Alternate web link (subscription required)
  7. ^ Cardarelli, F. (2004). Encyclopaedia of Scientific Units, Weights and Measures: Their SI Equivalences and Origins (2nd ed.). Springer. pp. 20–25. ISBN 1-8523-3682-X.
  8. ^ Demystifying Electromagnetic Equations page 155
  9. ^ Despite this usage, "emu" on its own is not a unit; see CRC handbook of chemistry and physics
  10. ^ lecture notes on units in electrodynamics
  11. ^ Бредов М.М., Румянцев В.В., Топтыгин И.Н. (1985). "Appendix 5: Units transform (p.385)". Классическая электродинамика. Nauka.{{cite book}}: CS1 maint: multiple names: authors list (link)
  12. ^ Units in Electricity and Magnetism. See the section "Conversion of Gaussian formulae into SI" and the subsequent text.