Electrical resistivity
Electrical resistivity (also known as specific electrical resistance) is a measure indicating how strongly a material opposes the flow of electric current. A low resistivity indicates a material that readily allows the movement of electrons. The SI unit for electrical resistivity is the ohm metre.
The electrical resistivity of a material is usually given by :
- <math>\rho={{RS}\over l}<math>
where
- R is the resistance of a uniform specimen of the material (measured in ohms)
- l is the length of the specimen (measured in metres)
- S is the cross-sectional area of the specimen (measured in square metres)
Electrical resistivity can also be defined as:
- <math>\rho={E \over J}<math>
where
- E is the magnitude of the electric field (measured in volt metres)
- J is the magnitude of the current density (measured in amperes per square metre)
In general, electrical resistivity of metals increases with temperature, while the resistivity of semiconductors decreases with temperature. As the temperature of a metal is reduced, the resistance usually reduces until it reaches a constant value, known as the residual resistivity. This value depends not only on the type of metal, but on its purity and thermal history. Some materials lose all electrical resistivity at sufficiently low temperatures, due to an effect known as superconductivity.
The reciprocal quantity is electrical conductivity.
Typical values
Typical resistivities for various materials (at 20 °C; 10-6 Ωm equals Ω·mm²/m) are shown in the table below:
| Material | Resistivity (ohm metres) |
| Silver | 0.0159 × 10-6 |
| Copper | 0.017 × 10-6 |
| Gold | 0.0244 × 10-6 |
| Aluminium | 0.0282 × 10-6 |
| Tungsten | 0.056 × 10-6 |
| Iron | 0.1 × 10-6 |
| Steel, Stainless | 0.72 × 10-6 |
| Platinum | 0.11 × 10-6 |
| Lead | 0.22 × 10-6 |
| Nichrome (A nickel-chromium alloy commonly used in heating elements) | 1.50 × 10-6 |
| Carbon | 35 × 10-6 |
| Germanium | 0.46 |
| Silicon | 640 |
| Glass | 1010 to 1014 |
| Hard rubber | approximately 1013 |
| Sulfur | 1015 |
| Quartz (fused) | 75 × 1016 |
Temperature dependence
- The electric resistivity of a typical metal conductor increases linearly with the temperature.
- The electric resistivity of a typical semiconductor decreases exponentialy with the temperature.
An even better approximation of the temperature dependence of the resistivity of a semiconductor is given by the Steinhardt-Hart equation:
- <math>1/T = A + B \ln(R) + C (\ln(R))^3 \,<math>
where A, B and C are the so-called Steinhardt coefficients.
This equation is used to calibrate thermistors.
SI electricity units
| SI electricity units Edit (http://www.mywiseowl.com/index.php?title=Template:SI_electricity_units&action=edit) | |||
|---|---|---|---|
| SI Base unit | |||
| Name | Symbol | Quantity | Notes |
| ampere | A | Current | |
| SI Derived units | |||
| Name | Symbol | Quantity | Notes |
| volt | V | Potential difference | |
| ohm | Ω | Resistance, Impedance, Reactance | |
| farad | F | Capacitance | |
| henry | H | Inductance | |
| siemens | S | Conductance, Admittance, Susceptance | =Ω−1 |
| coulomb | C | Electric charge | |
| ohm · metre | Ω · m | Resistivity | |
| siemens per metre | S / m | Conductivity | |
| henry per metre | H /m | Permeability | μ |
| farad per metre | F / m | Permittivity | ε |
| reciprocal farad | F−1 | Elastance | =F−1 |
See also
External links
da:Elektrisk resistivitet de:Spezifischer_Widerstand fi:Ominaisvastus pl:Rezystywność sl:specifična upornost sv:Resistivitet