-
(2003-07-26) c = 299792458 m/s Einstein's Constant
The speed of light in a vacuum. [Exact, by definition of the meter (m)] -
In April 2000, Kenneth Brecher (of Boston University) produced experimental evidence, at an unprecedented level of accuracy, which supports the main tenet of Einstein's Special Theory of Relativity, namely that the speed of light (c) does not depend on the speed of the source.
Brecher was able to claim a fabulous accuracy of less than one part in 1020, improving the state-of-the-art by 10 orders of magnitude! Brecher's conclusions were based on the study of the sharpness of gamma ray bursts (GRB) received from very distant sources: In such explosive events, gamma rays are emitted from points of very different [vectorial] velocities. Even minute differences in the speeds of these photons would translate into significantly different times of arrival, after traveling over immense cosmological distances. As no such spread is observed, a careful analysis of the data translates into the fabulous experimental accuracy quoted above in support of Einstein's theoretical hypothesis.
When he announced his results, Brecher declared that the constant c appears "even more fundamental than light itself" and he urged his colleagues to give it a proper name and start calling it Einstein's constant. The proposal was well received and has only been gaining momentum ever since, to the point that the "new" name seems now fairly well accepted.
Since 1983, the constant c has been used to define the meter in terms of the second, by enacting as exact the above value of 299792458 m/s.
Where does the symbol "c" come from?
Historically, "c" was used for a constant which later came to be identified as the speed of electromagnetic propagation multiplied by the square root of 2 (this would be cÖ2, in modern terms). This constant appeared in Weber's force law and was thus known as "Weber's constant" for a while. On at least one occasion, in 1873, James Clerk Maxwell (who normally used "V" to denote the speed of light) adjusted the meaning of "c" to let it denote the speed of electromagnetic waves instead.
In 1894, Paul Drude (1863-1906) made this explicit and was instrumental in popularizing "c" as the preferred notation for the speed of electromagnetic propagation. However, Drude still kept using the symbol "V" for the speed of light in an optical context, because the identification of light with electromagnetic waves was not yet common knowledge: 
Electromagnetic waves had first been observed in 1888, by Heinrich Hertz (1857-1894). Einstein himself used "V" for the speed of light and/or electromagnetic waves as late as 1907.
c may also be called the celerity of light: [Phase] celerity and [group] speed are normally two different things, but the two concepts coincide for light.
For more details, see: Why is c the symbol for the speed of light? by Philip Gibbs
-
(2003-07-26) mo = 4p 10-7 N/A2 = 1.256637061435917295... mH/m
Magnetic permeability of the vacuum. [Definition of the ampere (A)] -
The relation eo mo c 2 = 1 and the exact value of c yield an exact SI value, with a finite decimal expansion, for Coulomb's constant (see Coulomb's law):
| 1 | = 8.9875517873681764 ´ 10 9 » 9 ´ 10 9 N . m 2 / C 2 |
 |
| 4peo |
-
(2003-08-10) Planck's Constant(s): h and h/2p
Quantum of action: h = 6.626 068 96(33) 10-34 J/Hz
Quantum of spin: h/2p = 1.054 571 628(53) 10-34 J.s/rad -
A photon of frequency n has an energy hn where h is Planck's constant. With the pulsatance w = 2pn, this equals 
w, where is Dirac's constant.
The constant = h/2p is actually known under several names:
- Dirac's constant.
- The reduced Planck constant.
- The rationalized Planck constant.
- The quantum of angular momentum.
- The quantum of spin (although some spins are half-multiples of this).
The constant (pronounced h-bar) is equal to unity in the natural system of units of theoreticians (h is 2p). The spins of all particles are multiples of /2 = h/4p (an even multiple for bosons, an odd multiple for fermions).
Current technology of the watt balance (which compares an electromagnetic force with a weight) is almost able to measure Planck's constant with the same precision as the best comparisons with the International prototype of the kilogram, the only SI unit still defined in terms of an arbitrary artifact. It is thus fairly likely that Planck's constant could be given a de jure value in the near future, which would constitute a new definition of the SI unit of mass.
Resolution 7 of the 21st CGPM (October 1999) recommends "that national laboratories continue their efforts to refine experiments that link the unit of mass to fundamental or atomic constants with a view to a future redefinition of the kilogram". Although precise determinations of Avogadro's constant were mentioned in the discussion leading up to that resolution, the watt balance approach was considered more promising. It's also more satisfying to define the kilogram in terms of the fundamental Planck constant, rather than make it equivalent to a certain number of atoms in a silicon crystal. (Incidentally, the mass of N identical atoms in a crystal is slightly less than N times the mass of an isolated atom, because of the negative energy of interaction involved.)
Peter J. Mohr and Barry N. Taylor have proposed to define the kilogram in terms of an equivalent frequency n = 1.35639274 1050 Hz, which would make the constant h equal to c2/n, or 6.626068927033756019661385... 10-34 J/Hz.
Instead, it would probably be better to assign h or [rather] h/2p a rounded decimal value de jure. This would make the future definition of the kilogram somewhat less straightforward, but would facilitate actual usage when the utmost precision is called for. To best fit the "kilogram frequency" proposed by Mohr and Taylor, the de jure value of could be exactly 1.054571623 10-34 J.s/rad.
Note: " ħ " is how your browser displays UNICODE's "h-bar" (ħ)... OK?
-
(2003-08-10) Boltzmann's Constant k = 1.380 6504(24) 10-23 J/K
Defining entropy and/or relating temperature to energy. -
Named after Ludwig Boltzmann (1844-1906) the constant k = R/N is the ratio of the ideal gas constant (R) to Avogadro's number (N).
Boltzmann's constant is currently a measured quantity. However, it could possibly be given a de jure value which would define the unit of thermodynamic temperature, the kelvin (K) which is now defined in terms of the temperature of the triple point of water (273.16 K = 0.01°C, exact by definition).
History :
Following Abraham Pais, Eric W. Weisstein reports that Max Planck first used the constant k in 1900, in what's now known as Boltzmann's relation (giving the entropy S of a system known to be in one of W equiprobable states). 
S = k ln (W)
The constant k became known as Boltzmann's constant around 1911. Before that time, some authors (including Lorentz) had named the constant after Planck.
Philosophy of Statistical Mechanics by Lawrence Sklar (2001)
-
(2003-08-10) Avogadro Number
Number of things per mole of stuff: 6.02214179(30) 1023/mol -
Named after the Italian chemist and physicist Amedeo Avogadro (1776-1856) who formulated what is now known as Avogadro's Law, namely:
At the same temperature and [low] pressure, equal volumes of different gases contain the same number of molecules.
The current definition of the mole states that there are as many countable things in a mole as there are atoms in 12 grams of carbon-12 (the most common isotope of carbon). Keeping this definition and giving a de jure value to the Avogadro number would effectively constitute a definition of the unit of mass. Rather, the above definition could be dropped, so that a de jure value given to Avogadro's number would constitute a proper definition of the mole.
-
(2003-07-26) 683 lm/W (lumen per watt) at 540 THz
The "mechanical equivalent of light". [Definition of the candela (cd)] -
The frequency of 540 THz (5.4 1014 Hz) corresponds to yellowish-green light. This translates into a wavelength of about 555.1712185 nm in a vacuum, or about 555.013 nm in the air, which is usually quoted as 555 nm.
This frequency, sometimes dubbed "the most visible light", was chosen as a basis for luminous units because it corresponds to a maximal combined sensitivity for the cones of the human retina (the receptors which allow normal color vision under bright-light photopic conditions).
The situation is quite different under low-light scotopic conditions, where human vision is essentially black-and-white (due to rods not cones ) with a peak response around a wavelength of 507 nm.
Brightness by Rod Nave | The Power of Light | Luminosity Function
-
(2007-10-25) The ultimate dimensionful constant...
Newton's constant of gravitation: G = 6.67428(67) 10-11 m3 / kg s2 -
Assuming the above evolutions [ 1, 2, 3 ] come to pass, the SI scheme would define every unit in terms of de jure values of fundamental constants, using only one arbitrary definition for the unit of time (the second). There would be no need for that remaining arbitrary definition if the Newtonian constant of gravitation (the remaining fundamental constant) was given a de jure value.
There's no hope of ever measuring the constant of gravitation directly with enough precision to allow a metrological definition of the unit of time (the SI second) based on such a measurement.
However, if our mathematical understanding of the physical world progresses well beyond its current state, we may eventually be able to find a theoretical expression for the mass of the electron in terms of G. This would equate the determination of G to a measurement of the mass of the electron. Possibly, that could be done with the required metrological precision...
(2003-07-26) i, the basic imaginary number.
www.numericana.com/answer/constants.htm updated 2009-05-05 09:56
