Tesla (unit)

Tesla
The tesla definition T = Wb/m2 is prominently depicted on the 100 Serbian dinars banknote, along with the picture of Nikola Tesla.
Unit information
Unit system	SI derived unit
Unit of	Magnetic field strength
Symbol	T
Named after	Nikola Tesla
In SI base units:	1 T = 1 kg·s−2·A−1

The tesla (symbol T, commonly denoted as B) is a unit of measurement of the strength of the magnetic field. It is a derived unit of the International System of Units, the modern form of the metric system.

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^[1] in honour of Nikola Tesla.

The strongest fields encountered from permanent magnets are from Halbach spheres which can be over 4.5 T. The strongest field trapped in a laboratory superconductor as of July 2014 is 17.6 T.^[2] The record magnetic field has been produced by scientists at the Los Alamos National Laboratory campus of the National High Magnetic Field Laboratory, the world's first 100-tesla, non-destructive magnetic field.^[3]

Definition

A particle, carrying a charge of 1 coulomb, and passing through a magnetic field of 1 tesla, at a speed of 1 metre per second, perpendicular to said field, experiences a force with magnitude 1 newton, according to the Lorentz force law. As an SI derived unit, the tesla can also be expressed as

\mathrm{T} = \dfrac{\mathrm{V}\cdot{\mathrm{s}}}{\mathrm{m}^2} = \dfrac{\mathrm{N}}{\mathrm{A}{\cdot}\mathrm{m}} = \dfrac{\mathrm{J}}{\mathrm{A}{\cdot}\mathrm{m}^2} = \dfrac{\mathrm{H}{\cdot}\mathrm{A}}{\mathrm{m}^2} = \dfrac{\mathrm{Wb}}{\mathrm{m}^2} = \dfrac{\mathrm{kg}}{\mathrm{C}{\cdot}\mathrm{s}} = \dfrac{\mathrm{N}{\cdot}\mathrm{s}}{\mathrm{C}{\cdot}\mathrm{m}} = \dfrac{\mathrm{kg}}{\mathrm{A}{\cdot}\mathrm{s}^2}

(The last equivalent is in SI base units).^[4]

Units used:

A = ampere

C = coulomb

kg = kilogram

m = metre

N = newton

s = second

H = henry

T = tesla

V = volt

J = joule

Wb = weber

Electric vs. magnetic field

In the production of the Lorentz force, the difference between these types of field is that a force from a magnetic field on a charged particle is generally due to the charged particle's movement^[5] 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/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).^[6][7]

In ferromagnets, the movement creating the magnetic field is the electron spin^[8] (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).

Conversions

1 tesla is equivalent to:^[9]

10,000 (or 10⁴) G (gauss), used in the CGS system. Thus, 10 kG = 1 T (tesla), and 1 G = 10⁻⁴ T.

1,000,000,000 (or 10⁹) γ (gamma), used in geophysics.^[10] Thus, 1 γ = 1 nT (nanotesla).

42.6 MHz of the ¹H nucleus frequency, in NMR. Thus, the magnetic field associated with NMR at 1 GHz is 23.5 T.

For those concerned with low-frequency electromagnetic radiation in the home, the following conversions are needed most:

1000 nT (nanotesla) = 1 µT (microtesla) = 10 mG (milligauss)

1,000,000 µT = 1 T

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

Examples

• 31.869 µT (3.2 × 10⁻⁵ T) – strength of Earth's magnetic field at 0° latitude, 0° longitude
• 5 mT – the strength of a typical refrigerator magnet
• 0.3 T – the strength of solar sunspots
• 1.25 T – magnetic flux density at the surface of a neodymium magnet
• 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^[11]
• 4 T – strength of the superconducting magnet built around the CMS detector at CERN^[12]
• 8 T – the strength of LHC magnets.
• 11.75 T – the strength of INUMAC magnets, largest MRI scanner.^[13]
• 13 T – strength of the superconducting ITER magnet system^[14]
• 16 T – magnetic field strength required to levitate a frog^[15] (via diamagnetic levitation of the water in its body tissues) according to the 2000 Ig Nobel Prize in Physics.^[16]
• 17.6 T – strongest field trapped in superconductor in lab as of July 2014^[17]
• 10-20 T – maximum field strengths of superconducting electromagnets at cryogenic temperatures
• 33.8 T – the current (2009) world record for superconducting electromagnets ^[18]
• 45 T – the current (2015) world record for continuous field magnets ^[18]
• 10⁸-10¹¹ T (100 MT-100 GT) – magnetic strength of the average magnetar

Notes and references

External links

• Gauss<->Tesla Conversion Tool

SI units Base units ampere candela kelvin kilogram metre mole second Derived units with special names becquerel coulomb degree Celsius farad gray henry hertz joule katal lumen lux newton ohm pascal radian siemens sievert steradian tesla volt watt weber Other accepted units astronomical unit dalton day decibel degree Celsius degree of arc electronvolt hectare hour litre minute minute of arc neper second of arc tonne atomic units natural units See also Conversion of units History of the metric system Metric prefixes Proposed redefinitions Systems of measurement Book Category Outline