Tesla (unit)

Template:Short description Template:Infobox Unit The tesla (symbol: T) is the unit of magnetic flux density (also called magnetic B-field strength) in the International System of Units (SI).

One tesla is equal to one weber per square metre. The unit was announced during the General Conference on Weights and Measures in 1960 and is named<ref>Template:Cite web</ref> in honour of Serbian-American electrical and mechanical engineer Nikola Tesla, upon the proposal of the Slovenian electrical engineer France Avčin.

A particle, carrying a charge of one coulomb (C), and moving perpendicularly through a magnetic field of one tesla, at a speed of one metre per second (m/s), experiences a force with magnitude one newton (N), according to the Lorentz force law. That is, <math display=block>\mathrm{T = \dfrac{N{\cdot}s}{C{\cdot}m}}.</math>

As an SI derived unit, the tesla can also be expressed in terms of other units. For example, a magnetic flux of 1 weber (Wb) through a surface of one square meter is equal to a magnetic flux density of 1 tesla.<ref name="brochure">The International System of Units (SI), 8th edition, BIPM, eds. (2006), Template:ISBN, Table 3. Coherent derived units in the SI with special names and symbols Template:Webarchive</ref> That is, <math display=block>\mathrm{T = \dfrac{Wb}{m^2}}.</math>

Expressed only in SI base units, 1 tesla is: <math display=block>\mathrm{T = \dfrac{kg}{A{\cdot}s^2}},</math> where A is ampere, kg is kilogram, and s is second.<ref name="brochure" />

Additional equivalences result from the derivation of coulombs from amperes (A), <math>\mathrm{C = A {\cdot} s}</math>: <math display=block>\mathrm{T = \dfrac{N}{A{\cdot}m}},</math> the relationship between newtons and joules (J), <math>\mathrm{J = N {\cdot} m}</math>: <math display=block>\mathrm{T = \dfrac{J}{A{\cdot}m^2}},</math> and the derivation of the weber from volts (V), <math>\mathrm{Wb = V {\cdot} s}</math>: <math display=block>\mathrm{T = \dfrac{V{\cdot}{s}}{m^2}}.</math> Template:SI unit lowercase

In the production of the Lorentz force, the difference between electric fields and magnetic fields is that a force from a magnetic field on a charged particle is generally due to the charged particle's movement,<ref>Template:Cite book</ref> while the force imparted by an electric field on a charged particle is not due to the charged particle's movement. This may be appreciated by looking at the units for each. The unit of electric field in the MKS system of units is newtons per coulomb, N/C, while the magnetic field (in teslas) can be written as N/(C⋅m/s). The dividing factor between the two types of field is metres per second (m/s), which is velocity. This relationship immediately highlights the fact that whether a static electromagnetic field is seen as purely magnetic, or purely electric, or some combination of these, is dependent upon one's reference frame (that is, one's velocity relative to the field).<ref>Template:Cite book</ref><ref>Template:Cite book</ref>

In ferromagnets, the movement creating the magnetic field is the electron spin<ref>Template:Cite book</ref> (and to a lesser extent electron orbital angular momentum). In a current-carrying wire (electromagnets) the movement is due to electrons moving through the wire (whether the wire is straight or circular).

One tesla is equivalent to:<ref>McGraw Hill Encyclopaedia of Physics (2nd edition), C. B. Parker, 1994, Template:ISBN.</ref>Template:Pn Template:Plainlist

For the relation to the units of the magnetising field (ampere per metre or oersted), see the article on permeability.

Template:SI multiples

Template:Main article The following examples are listed in the ascending order of the magnetic-field strength.

• Template:Val (31.869 μT) – strength of Earth's magnetic field at 0° latitude, 0° longitude
• Template:Val (40 μT) – walking under a high-voltage power line<ref>Template:Cite web</ref>
• Template:Val (5 mT) – the strength of a typical refrigerator magnet
• 0.3 T – the strength of solar sunspots
• 1 T to 2.4 T – coil gap of a typical loudspeaker magnet
• 1.5 T to 3 T – strength of medical magnetic resonance imaging systems in practice, experimentally up to 17 T<ref>Template:Cite web</ref>
• 4 T – strength of the superconducting magnet built around the CMS detector at CERN<ref>Template:Cite web</ref>
• 5.16 T – the strength of a specially designed room temperature Halbach array<ref>Template:Cite web</ref>
• 8 T – the strength of LHC magnets
• 11.75 T – the strength of INUMAC magnets, largest MRI scanner<ref>Template:Cite web</ref>
• 13 T – strength of the superconducting ITER magnet system<ref>Template:Cite web</ref>
• 14.5 T – highest magnetic field strength ever recorded for an accelerator steering magnet at Fermilab<ref>Template:Cite web</ref>
• 16 T – magnetic field strength required to levitate a frog<ref>Template:Cite journal</ref> (by diamagnetic levitation of the water in its body tissues) according to the 2000 Ig Nobel Prize in Physics<ref>Template:Cite web)</ref>
• 17.6 T – strongest field trapped in a superconductor in a lab as of July 2014<ref>Template:Cite web</ref>
• 20 T - strength of the large scale high temperature superconducting magnet developed by MIT and Commonwealth Fusion Systems to be used in fusion reactorsTemplate:Citeneeded
• 27 T – maximal field strengths of superconducting electromagnets at cryogenic temperatures
• 35.4 T – the current (2009) world record for a superconducting electromagnet in a background magnetic field<ref name="MagnetLab">Template:Cite web</ref>
• 45 T – the current (2015) world record for continuous field magnets<ref name="MagnetLab"/>
• 97.4 T – strongest magnetic field produced by a "non-destructive" magnet<ref>Template:Cite news)</ref>
• 100 T – approximate magnetic field strength of a typical white dwarf star
• 1200 T – the field, lasting for about 100 microseconds, formed using the electromagnetic flux-compression technique<ref>D. Nakamura, A. Ikeda, H. Sawabe, Y. H. Matsuda, and S. Takeyama (2018), Magnetic field milestone</ref>
• 10⁹ T – Schwinger limit above which the electromagnetic field itself is expected to become nonlinear
• 10⁸ – 10¹¹ T (100 MT – 100 GT) – magnetic strength range of magnetar neutron stars

Template:Reflist

Template:Sister project

• Gauss ↔ Tesla Conversion Tool

Template:SI units Template:Nikola Tesla