Planck mass

In physics, the Planck mass, denoted by m_P, is the unit of mass in the system of natural units known as Planck units. It is approximately 21 micrograms,[1] or roughly the mass of a flea egg.[2]

Unlike some other Planck units, such as Planck length, Planck mass is not a fundamental lower or upper bound; instead, Planck mass is a unit of mass defined using only what Max Planck considered fundamental and universal units. For comparison, this value is of the order of 10¹⁵ (a quadrillion) times larger than the highest energy available to particle accelerators as of 2015.[lower-alpha 1]

It is defined as:

m_{\text{P}}={\sqrt {\frac {\hbar c}{G}}},

where c is the speed of light in a vacuum, G is the gravitational constant, and ħ is the reduced Planck constant.

Substituting values for the various components in this definition gives the approximate equivalent value of this unit in terms of other units of mass:

1\ m_{\mathrm {P} }\approx

1.220910×10¹⁹ GeV/c²

= 2.176435(24)×10⁻⁸ kg[3]

= 21.76470 μg

= 1.3107×10¹⁹ u .[4][5]

For the Planck mass $m_{\rm {P}}={\sqrt {\hbar c/G}}$ , the Schwarzschild radius ( $r_{\rm {S}}=2l_{\rm {P}}$ ) and the Compton wavelength ( $\lambda _{\rm {C}}=2\pi l_{\rm {P}}$ ) are of the same order as the Planck length $l_{\rm {P}}={\sqrt {\hbar G/c^{3}}}$ .

Particle physicists and cosmologists often use an alternative normalization with the reduced Planck mass, which is

M_{\text{P}}={\sqrt {\frac {\hbar c}{8\pi G}}}\approx \

4.341×10⁻⁹ kg = 2.435×10¹⁸ GeV/c² .[lower-alpha 2]

History

The Planck mass was first suggested by Max Planck[6] in 1899. He suggested that there existed some fundamental natural units for length, mass, time, and energy. He derived these units using only dimensional analysis of what he considered the most fundamental universal constants: The speed of light, the Newton gravitational constant, and the Planck constant.

Derivations

Dimensional analysis

The formula for the Planck mass can be derived by dimensional analysis. In this approach, one starts with the three physical constants ħ, c, and G, and attempts to combine them to get a quantity whose dimension is mass. The formula sought is of the form

m_{\text{P}}=c^{n_{1}}G^{n_{2}}\hbar ^{n_{3}},

where $n_{1},n_{2},n_{3}$ are constants to be determined by equating the dimensions of both sides. Using the symbols ${\mathsf {M}}$ for mass, ${\mathsf {L}}$ for length and ${\mathsf {T}}$ for time, and writing [ $x$ ] to denote the dimension of some physical quantity $x$ , we have the following:

\,[c]\,={\mathsf {L}}{\mathsf {T}}^{-1}\

[G]={\mathsf {M}}^{-1}{\mathsf {L}}^{3}{\mathsf {T}}^{-2}

\,[\hbar ]\,={\mathsf {M}}{\mathsf {L}}^{2}{\mathsf {T}}^{-1}\

.

Therefore,

[c^{n_{1}}G^{n_{2}}\hbar ^{n_{3}}]={\mathsf {M}}^{-n_{2}+n_{3}}{\mathsf {L}}^{n_{1}+3n_{2}+2n_{3}}{\mathsf {T}}^{-n_{1}-2n_{2}-n_{3}}.

If one wants this to equal ${\mathsf {M}}$ , the dimension of mass, using ${\mathsf {M}}={\mathsf {M}}^{1}{\mathsf {L}}^{0}{\mathsf {T}}^{0}$ , the following equations need to hold:

~~~~~~~~~-n_{2}+~~n_{3}=1\

~~~n_{1}+3n_{2}+2n_{3}=0\

-n_{1}-2n_{2}-~~n_{3}=0\

.

The solution of this system is:

n_{1}=1/2,n_{2}=-1/2,n_{3}=1/2.\

Thus, the Planck mass is:

m_{\text{P}}=c^{1/2}G^{-1/2}\hbar ^{1/2}={\sqrt {\frac {c\hbar }{G}}}\

.

Dimensional analysis can only determine a formula up to a dimensionless multiplicative factor. There is no a priori reason for starting with the reduced Planck constant ħ instead of the original Planck constant h, which differs from it by a factor of 2π.

Elimination of a coupling constant

Equivalently, the Planck mass is defined such that the gravitational potential energy between two masses m_P of separation r is equal to the energy of a photon (or the mass–energy of a graviton, if such a particle exists) of angular wavelength r (see the Planck relation), or that their ratio equals one.

E={\frac {Gm_{\text{P}}^{2}}{r}}={\frac {\hbar c}{r}}\

.

Isolating m_P, we get that

m_{\text{P}}={\sqrt {\frac {\hbar c}{G}}}

Footnotes

Maximum energy of the Large Hadron Collider: 13 TeV (as of 2015).
The convention of including the factor ${\frac {1}{\sqrt {8\pi }}}$ simplifies several other equations in general relativity.

References

"Planck mass". wolframalpha.com.
Dryden, M.W. (1990). "Blood consumption and feeding behavior of the cat flea". [journal name missing]: 51. average weight of a flea egg (3.42×10⁻² mg)
"2018 CODATA Value: Planck mass". The NIST Reference on Constants, Units, and Uncertainty. NIST. 20 May 2019. Retrieved 2019-05-20.
"Planck mass value in GeV". CODATA. 2016.
"Planck mass value in kg". CODATA. 2016.
Planck, M. (1899). "Naturlische Masseinheiten". [journal name missing] (in German). Der Koniglich Preussischen Akademie der Wissenschaften: 479.

Bibliography

Sivaram, C. (2007). "What is special about the Planck mass?". arXiv:0707.0058v1 [gr-qc].

External links

"Reference on Constants, Units, and Uncertainty". NIST.

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[3] Maximum energy of the Large Hadron Collider: 13 TeV (as of 2015).

[7] The convention of including the factor ${\frac {1}{\sqrt {8\pi }}}$ simplifies several other equations in general relativity.

[1] "Planck mass". wolframalpha.com.

[2] Dryden, M.W. (1990). "Blood consumption and feeding behavior of the cat flea". [journal name missing]: 51. average weight of a flea egg (3.42×10⁻² mg)

[physconst-mP-4] "2018 CODATA Value: Planck mass". The NIST Reference on Constants, Units, and Uncertainty. NIST. 20 May 2019. Retrieved 2019-05-20.

[5] "Planck mass value in GeV". CODATA. 2016.

[6] "Planck mass value in kg". CODATA. 2016.

[8] Planck, M. (1899). "Naturlische Masseinheiten". [journal name missing] (in German). Der Koniglich Preussischen Akademie der Wissenschaften: 479.

Planck's natural units
Planck constant Planck units
Planck units	Planck time Planck length Planck mass Planck temperature