In physics, the Planck mass, denoted by mP, is the unit of mass in the system of natural units known as Planck units. It is approximately 0.0217651 milligrams—about the mass of a flea egg.
Contents
- Significance
- Dimensional analysis
- Elimination of a coupling constant
- Compton wavelength and Schwarzschild radius
- References
It is defined so that
where c is the speed of light in a vacuum, G is the gravitational constant, and ħ is the reduced Planck constant.
Particle physicists and cosmologists often use an alternative normalization with the reduced Planck mass, which is
The factor of
Significance
Unlike all other Planck base units and most Planck derived units, the Planck mass has a scale more or less conceivable to humans. It is traditionally said to be about the mass of a flea, but more accurately it is about the mass of a flea egg at 0.0217651 milligrams.
In one discrete model of quantum space-time, particles greater than the Planck mass have no wave function, implying (among other things) that large particles and cannonballs will show no interference in the 2-slit experiment.
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 attempt to combine them to get a quantity with units of mass. The expected formula is of the form
where
Therefore,
If one wants dimensions of mass, the following equations must hold:
The solution of this system is:
Thus, the Planck mass is:
Elimination of a coupling constant
Equivalently, the Planck mass is defined such that the gravitational potential energy between two masses mP of separation r is equal to the energy of a photon (or graviton) of angular wavelength r (see the Planck relation), or that their ratio equals one.
Isolating mP, we get that
Note that if, instead of Planck masses, the electron mass were used, the equation would require a gravitational coupling constant, analogous to how the equation of the fine-structure constant relates the elementary charge and the Planck charge. Thus, the Planck mass can be viewed as resulting from absorbing the gravitational coupling constant into the unit of mass (and those of distance/time as well), like the Planck charge does for the fine-structure constant.
Compton wavelength and Schwarzschild radius
The Planck mass can be derived approximately by setting it as the mass whose Compton wavelength and Schwarzschild radius are equal. The Compton wavelength is, loosely speaking, the length-scale where quantum effects start to become important for a particle; the heavier the particle, the smaller the Compton wavelength. The Schwarzschild radius is the radius in which a mass, if it were a black hole, would have its event horizon located; the heavier the particle, the larger the Schwarzschild radius. If a particle were massive enough that its Compton wavelength and Schwarzschild radius were approximately equal, its dynamics would be strongly affected by quantum gravity. This mass is (approximately) the Planck mass.
The Compton wavelength is
and the Schwarzschild radius is
Setting them equal:
This is not quite the Planck mass: It is a factor of