Natural units

Natural units or Planck units are a natural system of units of measurement based on the fundamental constants:

Constant Symbol Dimensions
gravitational constant G M⁻¹L³T⁻²
Dirac's constant (=h/2, where h is Planck's constant) ML²T⁻¹
speed of light in vacuum c L¹T⁻¹
Boltzmann constant k ML²T⁻²K⁻¹
permittivity of vacuum ε₀ Q²M⁻¹L⁻³T²
electric charge e Q

Constant	Symbol	Dimensions
gravitational constant	G	M⁻¹L³T⁻²
Dirac's constant	(=h/2, where h is Planck's constant)	ML²T⁻¹
speed of light in vacuum	c	L¹T⁻¹
Boltzmann constant	k	ML²T⁻²K⁻¹
permittivity of vacuum	ε₀	Q²M⁻¹L⁻³T²
electric charge	e	Q

The Planck units are often semi-humorously referred to by physicists as "God's units". They eliminate all arbitrariness from the system of units: some physicists believe that an extra-terrestrial intelligence might be expected to use the same system. These units have the advantage of simplifying many equations in physics by removing conversion factors.

For example, Einstein's famous equation E=m·c² becomes simply E=m·1² (or effectively E=m), i.e. a body with mass = 5000 Planck Mass units will have an intrinsic energy of 5000 Planck Energy units. For this reason, the units are popular in quantum gravity research. However, they are too small or too large for practical use, unless prefixed with large powers of ten. They also suffer from uncertainties in the measurement of some of the constants on which they are based, especially of the gravitational constant G.

Table of contents

1 Planck units
2 Other Natural Units
3 Discussion
4 Max Planck's creation of the natural units
5 See also
6 External link

Planck units

Name Dimensions Expression Approx. SI equivalent measure
Planck length Length (L) 1.616 × 10^-35 m
Planck mass Mass (M) 2.177 × 10^-8 kg
Planck time Time (T) 5.391 × 10^-44 s
Planck current Electric current (Q/T) 2.972 × 10²⁴ A
Planck temperature Temperature (ML²T⁻²/k) 1.415 × 10³² K

Name Dimensions Expression Approx. SI equivalent measure
Planck force Force (MLT⁻²) 1.210 × 10⁴⁴ N
Planck energy Energy (ML²T⁻²) 10¹⁹ GeV = 1.956 × 10⁹ J
Planck power Power (ML²T⁻³) 3.629 × 10⁵² W
Planck density Density (ML^-3) 5.1 × 10⁹⁶ kg/m³
Planck frequency Frequency (T⁻¹) 1.855 × 10⁴³ Hz
Planck pressure Pressure (ML⁻¹T⁻²) 4.635 × 10¹¹³ Pa

Other Natural Units
Although not formally part of the system of Planck units, the following SI derived units are defined naturally.
Name Dimensions Expression Approx. SI equivalent measure
Radian Angle (dimensionless) 1 rad
Steradian Solid angle (dimensionless) 1 sr

Name	Dimensions	Expression	Approx. SI equivalent measure
Planck length	Length (L)		1.616 × 10^-35 m
Planck mass	Mass (M)		2.177 × 10^-8 kg
Planck time	Time (T)		5.391 × 10^-44 s
Planck current	Electric current (Q/T)		2.972 × 10²⁴ A
Planck temperature	Temperature (ML²T⁻²/k)		1.415 × 10³² K

Name	Dimensions	Expression	Approx. SI equivalent measure
Planck force	Force (MLT⁻²)		1.210 × 10⁴⁴ N
Planck energy	Energy (ML²T⁻²)		10¹⁹ GeV = 1.956 × 10⁹ J
Planck power	Power (ML²T⁻³)		3.629 × 10⁵² W
Planck density	Density (ML^-3)		5.1 × 10⁹⁶ kg/m³
Planck frequency	Frequency (T⁻¹)		1.855 × 10⁴³ Hz
Planck pressure	Pressure (ML⁻¹T⁻²)		4.635 × 10¹¹³ Pa
Other Natural Units Although not formally part of the system of Planck units, the following SI derived units are defined naturally.
Name	Dimensions	Expression	Approx. SI equivalent measure
Radian	Angle (dimensionless)		1 rad
Steradian	Solid angle (dimensionless)		1 sr

Discussion

At the "Planck scales" in length, time, density, or temperature, one must consider both the effects of quantum mechanics and general relativity. Unfortunately this requires a theory of quantum gravity which does not yet exist.

The Planck mass is credible, indeed many living thingss (such as some fleas) are smaller than it; the issue is that general relativity predicts that smaller black holes can exist within the event horizon (with a radius less than the Planck length), while quantum mechanics predicts that the mass would probably be outside the event horizon.

Max Planck's creation of the natural units

Max Planck first listed his set of units (and gave values for them remarkably close to those used today) in May of 1899 in a paper presented to the Prussian Academy of Sciences. Max Planck: 'ÃÂber irreversible StrahlungsvorgÃÂ¤nge'. Sitzungsberichte der PreuÃÂischen Akademie der Wissenschaften, vol. 5, p. 479 (1899)

At the time he presented the units, quantum mechanics had not been invented. He himself had not yet discovered the theory of black-body radiation (first published December 1900) in which the Planck's Constant h made its first appearance and for which Planck was later awarded the Nobel prize. The relevant parts of Planck's 1899 paper leave some confusion as to how he managed to come up with the units of time, length, mass, temperature etc. which today we define using Dirac's Constant and motivate by references to quantum physics before things like and quantum physics were known. Here's a quote from the 1899 paper that gives an idea of how Planck thought about the set of units.

...ihre Bedeutung fÃÂ¼r alle Zeiten und fÃÂ¼r alle, auch ausserirdische und ausser menschliche Culturen nothwendig behalten und welche daher als 'natÃÂ¼rliche Maasseinheiten' bezeichnet werden kÃÂ¶nnen...

...These necessarily retain their meaning for all times and for all civilizations, even extraterrestrial and non-human ones, and can therefore be designated as 'natural units'...

External link

The NIST website(National Institute of Standards and Technology) is a convenient source of data on the commonly recognized constants, including Planck units.
Planck's original paper