மின்கடத்து திறன்
கட்டற்ற கலைக்களஞ்சியமான விக்கிபீடியாவில் இருந்து.
Electrical conductivity is a measure of a material's ability to conduct an electric current. When an electrical potential difference is placed across a conductor, its movable charges flow, giving rise to an electric current. The conductivity σ is defined as the ratio of the current density to the electric field strength :
- . It is also possible to have materials in which the conductivity is anisotropic, in which case σ is a 3×3 matrix (or more technically a rank-2 tensor) which is generally symmetric.
Conductivity is the reciprocal (inverse) of electrical resistivity, and has the SI units of siemens per metre (S·m-1). It is commonly represented by the Greek letter σ, but κ or γ are also occasionally used.
பொருளடக்கம் |
[தொகு] Classification of materials by conductivity
- A conductor such as a metal has high conductivity.
- An insulator like glass or a vacuum has low conductivity.
- The conductivity of a semiconductor is generally intermediate, but varies widely under different conditions, such as exposure of the material to electric fields or certain frequencies of light.
[தொகு] சில பொதுவான மின்கடத்து திறன் மதிப்புகள்
மின்கடத்து திறன் (S·m-1) | வெப்பநிலை(°C) | குறிப்புகள் | |
---|---|---|---|
வெள்ளி | 63.01 × 106 | 20 | உலோகங்களில் மிக அதிகமான மின்கடத்து திறன் |
தாமிரம் | 59.6 × 106 | 20 | |
Annealed Copper | 58.0 × 106 | 20 | Referred to as 100 %IACS or International Annealed Copper Standard. The unit for expressing the conductivity of nonmagnetic materials by testing using the eddy-current method. Generally used for temper and alloy verification of Aluminum. |
அலுமினியம் | 37.8 × 106 | 20 | |
கடல் நீர் | 5 | ||
குடி நீர் | 0.0005 – 0.05 | ||
Deionized water | 5.5 × 10-6 | changes to 1.2 × 10-4 in degassed water; see J. Phys. Chem. B 2005, 109, 1231-1238 |
[தொகு] Complex conductivity
To analyse the conductivity of materials exposed to alternating electric fields, it is necessary to treat conductivity as a complex number (or as a matrix of complex numbers, in the case of anisotropic materials mentioned above) called the admittivity. This method is used in applications such as electrical impedance tomography, a type of industrial and medical imaging. Admittivity is the sum of a real component called the conductivity and an imaginary component called the susceptivity. [1]
[தொகு] Temperature dependence
Electrical conductivity is more or less strongly dependent on temperature. In metals, electrical conductivity decreases with increasing temperature, whereas in semiconductors, electrical conductivity increases with increasing temperature. Over a limited temperature range, the electrical conductivity can be approximated as being directly proportional to temperature. In order to compare electrical conductivity measurements at different temperatures, they need to be standardized to a common temperature. This dependance is often expressed as a slope in the conductivity-vs-temperature graph, and can be used:
where
- σT′ is the electrical conductivity at a common temperature, T′
- σT is the electrical conductivity at a measured temperature, T
- α is the temperature compensation slope of the material,
- T is the measured temperature,
- T′ is the common temperature.
The temperature compensation slope for most naturally occurring waters is about 2 %/°C, however it can range between 1 to 3 %/°C. This slope is influenced by the geochemistry, and can be easily determined in a laboratory.
[தொகு] See also
- electrical conduction for a discussion of the physical origin of electrical conductivity.
- electrical resistance
- electrical resistivity is the inverse of electric conductivity
- SI electromagnetism units