Information about Zeptometre

The metre or meter^[1](symbol: m) is the fundamental unit of length in the International System of Units (SI). The metre was originally defined by a prototype object meant to represent ¹⁄_10 000 000 the distance between the poles and the Equator. Today, it is defined as ¹⁄_{299 792 458} of a light-second.

Because it is the base unit of length in the SI, all SI units which involve length (such as area or speed) are defined relative to the metre. Additionally, due to the metre being the only SI base unit used to measure a vector (e.g. displacement), all vector units are defined relative to the metre. However, decimal multiples and submultiples of the metre— such as kilometre (1000 metres) and centimetre (0.01 metres)— can be formed by adding SI prefixes to metre (see the table below).

Etymology

The word is from the Greek metron (μέτρον), "a " via the French mètre. Its first recorded usage in English meaning this unit of length is from 1797.

History

Meridional definition

In the eighteenth century, there were two favoured approaches to the definition of the standard unit of length. One suggested defining the metre as the length of a pendulum with a half-period of one second. The other suggested defining the metre as one ten-millionth of the length of the Earth's meridian along a quadrant, that is the distance from the equator to the north pole. In 1791, the French Academy of Sciences selected the meridional definition.

In order to establish a universally accepted foundation for the definition of the metre, measurements of this meridian more accurate than those available at that time were imperative. The Bureau des Longitudes commissioned an expedition led by Delambre and Pierre Méchain, lasting from 1792 to 1799, which measured the length of the meridian between Dunkerque and Barcelona. This portion of the meridian, which also passes through Paris, was to serve as the basis for the length of the half meridian, connecting the North Pole with the Equator.

However, in 1793, France adopted the metre based on provisional results from the expedition as its official unit of length. Although it was later determined that the first prototype metre bar was short by a fifth of a millimetre due to miscalculation of the flattening of the Earth, this length became the standard. So, the circumference of the Earth through the poles is approximately forty million metres.

Prototype metre bar

In the 1870s and in light of modern precision, a series of international conferences were held to devise new metric standards. The Metre Convention (Convention du Mètre) of 1875 mandated the establishment of a permanent International Bureau of Weights and Measures (BIPM: Bureau International des Poids et Mesures) to be located in Sèvres, France. This new organisation would preserve the new prototype metre and kilogram when constructed, distribute national metric prototypes, and maintain comparisons between them and non-metric measurement standards. This organization created a new prototype bar in 1889 at the first General Conference on Weights and Measures (CGPM: Conférence Générale des Poids et Mesures), establishing the International Prototype Metre as the distance between two lines on a standard bar of an alloy of ninety percent platinum and ten percent iridium, measured at 0 degrees Celsius

Standard wavelength of krypton-86 emission

In 1893, the standard metre was first measured with an interferometer by Albert A. Michelson, the inventor of the device and an advocate of using some particular wavelength of light as a standard of distance. By 1925, interferometry was in regular use at the BIPM. However, the International Prototype Metre remained the standard until 1960, when the eleventh CGPM defined the metre in the new SI system as equal to 1,650,763.73 wavelengths of the orange-red emission line in the electromagnetic spectrum of the krypton-86 atom in a vacuum. The original international prototype of the metre is still kept at the BIPM under the conditions specified in 1889.

Standard wavelength of helium-neon laser light

To further reduce uncertainty, the seventeenth CGPM in 1983 replaced the definition of the metre with its current definition, thus fixing the length of the metre in terms of time and the speed of light:

The metre is the length of the path travelled by light in vacuum during a time interval of 1/299 792 458 of a second.^[2]

Note that this definition had the effect of fixing the speed of light in a vacuum at precisely 299 792 458 metres per second. Although the metre is now defined in terms of time-of-flight, actual laboratory realisations of the metre are still delineated by counting the required number of wavelengths of light along the distance. An intended byproduct of the 17^th CGPM’s definition was that it enabled scientists to measure the wavelength of their lasers with one-fifth the uncertainty. To further facilitate reproducibility from lab to lab, the 17^th CGPM also made the iodine-stabilised helium-neon laser "a recommended radiation" for realising the metre. Today's best determination of the wavelength of the relevant transition in ¹²⁷I₂ used for this purpose is λ = 632 991 212.58 fm with an estimated relative standard uncertainty (U) of 2.1 Ã— 10^-11. This uncertainty is currently the limiting factor in laboratory realisations of the metre as it is several orders of magnitude poorer than that of the second (U = 5 Ã— 10^-16)^[3] Consequently, a practical realisation of the metre is usually delineated (not defined) today in labs as 1 579 800.762 042(33) wavelengths of helium-neon laser light in a vacuum.

Timeline of definition

• 1790May 8 — The French National Assembly decides that the length of the new metre would be equal to the length of a pendulum with a half-period of one second.
• 1791March 30 — The French National Assembly accepts the proposal by the French Academy of Sciences that the new definition for the metre be equal to one ten-millionth of the length of the Earth's meridian along a quadrant through Paris, that is the distance from the equator to the north pole.
• 1795 — Provisional metre bar constructed of brass.
• 1799December 10 — The French National Assembly specifies the platinum metre bar, constructed on 23 June 1799 and deposited in the National Archives, as the final standard.
• 1889September 28 — The first General Conference on Weights and Measures (CGPM) defines the length as the distance between two lines on a standard bar of an alloy of platinum with ten percent iridium, measured at the melting point of ice.
• 1927October 6 — The seventh CGPM adjusts the definition of the length to be the distance, at 0 Â°C, between the axes of the two central lines marked on the prototype bar of platinum-iridium, this bar being subject to one standard atmosphere of pressure and supported on two cylinders of at least one centimetre diameter, symmetrically placed in the same horizontal plane at a distance of 571 millimetres from each other.
• 1960October 20 — The eleventh CGPM defines the length to be equal to 1,650,763.73 wavelengths in vacuum of the radiation corresponding to the transition between the 2p¹⁰ and 5d⁵ quantum levels of the krypton-86 atom.
• 1983October 21 — The seventeenth CGPM defines the length as equal to the distance travelled by light in vacuum during a time interval of 1/299 792 458 of a second.

SI prefixed forms of metre

Orders of magnitude (length) in E notation
1 E-24 m 1 E-23 m 1 E-22 m 1 E-21 m 1 E-20 m 1 E-19 m 1 E-18 m 1 E-17 m 1 E-16 m 1 E-15 m 1 E-14 m 1 E-13 m 1 E-12 m 1 E-11 m 1 E-10 m 1 E-9 m 1 E-8 m 1 E-7 m 1 E-6 m 1 E-5 m 1 E-4 m 1 E-3 m 1 E-2 m 1 E-1 m	1 E0 m 1 E+1 m 1 E+2 m 1 E+3 m 1 E+4 m 1 E+5 m 1 E+6 m 1 E+7 m 1 E+8 m 1 E+9 m 1 E+10 m 1 E+11 m 1 E+12 m 1 E+13 m 1 E+14 m 1 E+15 m 1 E+16 m 1 E+17 m 1 E+18 m 1 E+19 m 1 E+20 m 1 E+21 m 1 E+22 m 1 E+23 m 1 E+24 m 1 E+25 m 1 E+26 m
↓/↓

SI prefixes are often employed to denote decimal multiples and submultiples of the metre, as shown in the table below.

Multiple	Name	Symbol		Multiple	Name	Symbol
100	metre	m
101	decametre	dam		10–1	decimetre	dm
102	hectometre	hm		10–2	centimetre	cm
103	kilometre	km		10–3	millimetre	mm
106	megametre	Mm		10–6	micrometre	m
109	gigametre	Gm		10–9	nanometre	nm
1012	terametre	Tm		10–12	picometre	pm
1015	petametre	Pm		10–15	femtometre	fm
1018	exametre	Em		10–18	attometre	am
1021	zettametre	Zm		10–21	zeptometre	zm
1024	yottametre	Ym		10–24	yoctometre	ym

Equivalents in other units

Metric unit expressed in non-SI unit					Non-SI unit expressed in metric unit
1 metre	≡	10−4	mil		1 mil	≡	104	metres
1 metre	≈	39.37	inches		1 inch	≡	0.0254	metres
1 centimetre	≈	0.3937	inch		1 inch	≡	2.54	centimetres
1 millimetre	≈	0.03937	inch		1 inch	≡	25.4	millimetres
1 metre	≡	1×1010	Ã…ngström		1 Ã…ngström	≡	1×10-10	metre
1 nanometre	≡	10	Ã…ngström		1 Ã…ngström	≡	100	picometres

See also

• SI (International System of Units)
• Convention du Mètre
• SI prefix
• Conversion of units for comparisons with other units
• Orders of magnitude (length)
• Speed of light
• Metrication

Notes

References

• Bureau International des Poids et Mesures. The BIPM and the evolution of the definition of the metre. URL accessed on 2006 June 3.
• Resolutions of the CGPM. URL accessed on 2006 June 3.
• Penzes, William B. at the U.S. National Institute of Standards and Technology Precision Engineering Division (2005 December 29). Time Line for the Definition of the Meter. URL accessed on 2006 June 3.
• U.S. National Institute of Standards and Technology (October 2000). The NIST Reference on Constants, Units, and Uncertainty: International System of Units (SI):
• SI base units. URL accessed on 2006 June 3.
• Definitions of the SI base units. URL accessed on 2006 June 3.
• Historical context of the SI: meter. URL accessed on 2006 June 3.

External links

• Official BIPM definition of the metre
• Length—Evolution from Measurement Standard to a Fundamental Constant at U.S. NIST
• The History of the Meter By Tibo Qorl (Translated by Sibille Rouzaud)