Electrical resistance
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Electrical resistance is a measure of the degree to which an object opposes the passage of an electric current. The SI unit of electrical resistance is the ohm. Its reciprocal quantity is electrical conductance measured in siemens.
The quantity of resistance in an electric circuit determines the amount of current flowing in the circuit for any given voltage applied to the circuit.
- [R = \frac]
- R is the resistance of the object, usually measured in ohms, equivalent to J·s/C2
- V is the potential difference across the object, usually measured in volts
- I is the current passing through the object, usually measured in amperes
Resistive loss
When a current, I, flows through an object with resistance, R, electrical energy is converted to heat at a rate (power) equal to- [P = \cdot R} \,]
- P is the power measured in watts
- I is the current measured in amperes
- R is the resistance measured in ohms
Resistance of a conductor
DC resistance
As long as the current density is totally uniform in the conductor, the DC resistance R of a conductor of regular cross section can be computed as- [R = \,]
- L is the length of the conductor, measured in meters
- A is the cross-sectional area, measured in square meters
- ρ (Greek: rho) is the electrical resistivity (also called specific electrical resistance) of the material, measured in ohm · meter. Resistivity is a measure of the material's ability to oppose the flow of electric current.
AC resistance
If a wire conducts high-frequency alternating current then the effective cross sectional area of the wire is reduced. This is because of the skin effect.This formula applies to isolated conductors. In a conductor close to others, the actual resistance is higher because of the proximity effect.
Causes of resistance
In metals
A metal consists of a lattice of atoms, each with a shell of electrons. This can also be known as positive ionic lattice. The outer electrons are free to dissociate from their parent atoms and travel through the lattice, creating a 'sea' of electrons, making the metal a conductor. When an electrical potential difference (a voltage) is applied across the metal, the electrons drift from one end of the conductor to the other under the influence of the electric field.In a metal the thermal motion of ions is the primary source of scattering of electrons (due to destructive interference of free electron wave on non-correlating potentials of ions) - thus the prime cause of metal resistance. Imperfections of lattice also contribute into resistance, although their contribution in pure metals is negligible.
The larger the cross-sectional area of the conductor, the more electrons are available to carry the current, so the lower the resistance. The longer the conductor, the more scattering events occur in each electron's path through the material, so the higher the resistance. [link]
In semiconductors and insulators
Semiconductors have properties that are part-way between those of metals and of insulators. A silicon boule has a grayish metallic sheen, like a metal, but is brittle, like glass. It is possible to manipulate the resistive properties of semiconductor materials by doping those materials with atomic elements, such as arsenic or boron, which create electrons or holes which can move across the material lattice.In ionic liquids/electrolytes
In electrolytes, electrical conduction happens not by band electrons or holes, but by full atomic species (ions) traveling, each carrying an electrical charge. The resistivity of ionic liquids varies tremendously by the salt concentration - while distilled water is almost an insulator, salt water is a very efficient electrical conductor. In biological membranes, currents are carried by ionic salts. Small holes in the membranes, called ion channels, are selective to specific ions and determine the membrane resistance.Resistance of various materials
| Material | Resistivity, [ \rho ] ohm-meter |
| Metals | [10^] |
| Semiconductors | variable |
| Electrolytes | variable |
| Insulators | [10^] |
Band theory
Quantum mechanics states that the energy of an electron in an atom cannot be any arbitrary value. Rather, there are fixed energy levels which the electrons can occupy, and values in between these levels are impossible. The energy levels are grouped into two bands: the valence band and the conduction band (the latter is generally above the former). Electrons in the conduction band may move freely throughout the substance in the presence of an electrical field.
In insulators and semiconductors, the atoms in the substance influence each other such that between the valence band and the conduction band, there exists a forbidden band of energy levels that the electrons simply cannot occupy. In order for a current to flow, a relatively large amount of energy must be furnished to an electron for it to leap across this forbidden gap and into the conduction band. Thus, large voltages yield relatively small currents.
Differential resistance
When resistance may depend on voltage and current, differential resistance, incremental resistance or slope resistance is defined as the slope of the V-I graph at a particular point, thus:- [R = \frac \,]
Temperature-dependence
Near room temperature, the electric resistance of a typical metal conductor increases linearly with the temperature:- [R = R_0(1 + aT) \,],
The electric resistance of a typical intrinsic (non doped) semiconductor decreases exponentially with the temperature:
- [R= R_0 e^\,]
The electric resistance of electrolytes and insulators is highly nonlinear, and case by case dependent, therefore no generalized equations are given.
See also
- Resistor
- Electrical conduction for more information about the physical mechanisms for conduction in materials.
- voltage divider
- Voltage drop
- current divider
- Thermal resistance
- Electrical resistivity
- Electrical impedance
- SI electromagnetism units
External links
- [Circuits]
- [Resistance, Reactance, and Impedance]
- [Calculation: Electrical resistance, voltage, current, and power]
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