Planck particle

A Planck particle, named after physicist Max Planck, is a hypothetical particle defined as a tiny black hole whose Compton wavelength is equal to its Schwarzschild radius.^[1] Its mass is thus approximately the Planck mass, and its Compton wavelength and Schwarzschild radius are about the Planck length.^[2] Planck particles are sometimes used as an exercise to define the Planck mass and Planck length.^[3] They play a role in some models of the evolution of the universe during the Planck epoch.^[4]

Compared to a proton, for example, the Planck particle would be extremely small (its radius being equal to the Planck length, which is about 10⁻²⁰ times the proton's radius) and massive (the Planck mass being 10¹⁹ times the proton's mass).^[5]

Derivation

While opinions vary as to its proper definition, the most common definition of a Planck particle is a particle whose Compton wavelength is equal to its Schwarzschild radius. This sets the relationship:

\lambda ={\frac {h}{mc}}={\frac {2Gm}{c^{2}}}

Thus making the mass of such a particle:

m={\sqrt {\frac {hc}{2G}}}

This mass will be ${\sqrt {\pi }}$ times larger than the Planck mass, making a Planck particle 1.772 times more massive than the Planck unit mass.

Its radius will be the Compton wavelength:

r={\frac {h}{mc}}={\sqrt {\frac {2Gh}{c^{3}}}}

Dimensions

Using the above derivations we can substitute the universal constants h, G, and c, and determine physical values for the particle's mass and radius. Assuming this radius represents a sphere of uniform density we can further determine the particle's volume and density.

Table 1: Physical dimensions of a Planck particle
Parameter	Dimension	Value in SI units
Mass	M	6992385763000000000♠3.85763×10⁻⁸ kg
Radius	L	6965572947000000000♠5.72947×10⁻³⁵ m
Volume	L³	6897787827000000000♠7.87827×10⁻¹⁰³ m³
Density	M L⁻³	7094489655000000000♠4.89655×10⁹⁴ kg m⁻³

The above dimensions do not correspond to any known physical entity or material.

References

↑ Michel M. Deza; Elena Deza. Encyclopedia of Distances. Springer; 1 June 2009. ISBN 978-3-642-00233-5. p. 433.
↑ "Light element synthesis in Planck fireballs" - SpringerLink
↑ B. Roy Frieden; Robert A. Gatenby. Exploratory data analysis using Fisher information. Springer; 2007. ISBN 978-1-84628-506-6. p. 163.
↑ Harrison, Edward Robert (2000), Cosmology: the science of the universe, Cambridge University Press, ISBN 978-0-521-66148-5 p. 424
↑ Harrison 2000, p. 478.

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Planck particle

Derivation

Dimensions

See also

References

External links