|Unit system||SI derived unit|
|Unit of||magnetic flux|
|Named after||Wilhelm Eduard Weber|
|Derivation||1 Wb = 1 V⋅s|
|1 Wb in ...||... is equal to ...|
|SI base units||1 Wb = 1 kg⋅m2⋅s−2⋅A−1|
|Gaussian units||1 Wb ≘ 1×108 Mx|
In physics, the weber (/ /-, VAY-, WEH-bər; symbol: Wb) is the SI derived unit of magnetic flux whose units are volt-second. A flux density of one Wb/m2 (one weber per square metre) is one tesla.
The weber is named after the German physicist Wilhelm Eduard Weber (1804–1891).
The weber may be defined in terms of Faraday's law, which relates a changing magnetic flux through a loop to the electric field around the loop. A change in flux of one weber per second will induce an electromotive force of one volt (produce an electric potential difference of one volt across two open-circuited terminals).
Weber (unit of magnetic flux) — The weber is the magnetic flux that, linking a circuit of one turn, would produce in it an electromotive force of 1 volt if it were reduced to zero at a uniform rate in 1 second.
The weber is commonly expressed in a multitude of other units:
The weber is named after Wilhelm Eduard Weber. As with every SI unit named for a person, its symbol starts with an upper case letter (Wb), but when written in full it follows the rules for capitalisation of a common noun; i.e., "weber" becomes capitalised at the beginning of a sentence and in titles, but is otherwise in lower case.
In 1861, the British Association for the Advancement of Science (known as "The BA") established a committee under William Thomson (later Lord Kelvin) to study electrical units. In a February 1902 manuscript, with handwritten notes of Oliver Heaviside, Giovanni Giorgi proposed a set of rational units of electromagnetism including the weber, noting that "the product of the volt into the second has been called the weber by the B. A."
The International Electrotechnical Commission began work on terminology in 1909 and established Technical Committee 1 in 1911, its oldest established committee, "to sanction the terms and definitions used in the different electrotechnical fields and to determine the equivalence of the terms used in the different languages."
It was not until 1927 that TC1 dealt with the study of various outstanding problems concerning electrical and magnetic quantities and units. Discussions of a theoretical nature were opened at which eminent electrical engineers and physicists considered whether magnetic field strength and magnetic flux density were in fact quantities of the same nature. As disagreement continued, the IEC decided on an effort to remedy the situation. It instructed a task force to study the question in readiness for the next meeting.
In 1930, TC1 decided that the magnetic field strength (H) is of a different nature from the magnetic flux density (B), and took up the question of naming the units for these fields and related quantities, among them the integral of magnetic flux density.
In 1935, TC 1 recommended names for several electrical units, including the weber for the practical unit of magnetic flux (and the maxwell for the CGS unit).
It was decided to extend the existing series of practical units into a complete comprehensive system of physical units, the recommendation being adopted in 1935 "that the system with four fundamental units proposed by Professor Giorgi be adopted subject to the fourth fundamental unit being eventually selected". This system was given the designation of "Giorgi system".
Also in 1935, TC1 passed responsibility for "electric and magnetic magnitudes and units" to the new TC24. This "led eventually to the universal adoption of the Giorgi system, which unified electromagnetic units with the MKS dimensional system of units, the whole now known simply as the SI system (Système International d'unités)."
In 1938, TC24 "recommended as a connecting link [from mechanical to electrical units] the permeability of free space with the value of μ0 = 4π×10−7 H/m. This group also recognized that any one of the practical units already in use (ohm, ampere, volt, henry, farad, coulomb, and weber), could equally serve as the fourth fundamental unit. "After consultation, the ampere was adopted as the fourth unit of the Giorgi system in Paris in 1950."
Like other SI units, the weber can modified by adding a prefix that multiplies it by a power of 10.
|Value||SI symbol||Name||Value||SI symbol||Name|
|10−1 Wb||dWb||deciweber||101 Wb||daWb||decaweber|
|10−2 Wb||cWb||centiweber||102 Wb||hWb||hectoweber|
|10−3 Wb||mWb||milliweber||103 Wb||kWb||kiloweber|
|10−6 Wb||µWb||microweber||106 Wb||MWb||megaweber|
|10−9 Wb||nWb||nanoweber||109 Wb||GWb||gigaweber|
|10−12 Wb||pWb||picoweber||1012 Wb||TWb||teraweber|
|10−15 Wb||fWb||femtoweber||1015 Wb||PWb||petaweber|
|10−18 Wb||aWb||attoweber||1018 Wb||EWb||exaweber|
|10−21 Wb||zWb||zeptoweber||1021 Wb||ZWb||zettaweber|
|10−24 Wb||yWb||yoctoweber||1024 Wb||YWb||yottaweber|
|Common multiples are in bold face.|