Time variation of fundamental constants

Dimensionality

It is problematic to discuss the proposed rate of change (or lack thereof) of a single dimensional physical constant in isolation. The reason for this is that the choice of a system of units may arbitrarily select any physical constant as its basis, making the question of which constant is undergoing change an artefact of the choice of units.

For example, in SI units, the speed of light has been given a defined value in 1983. Thus, it was meaningful to experimentally measure the speed of light in SI units prior to 1983, but it is not so now. Tests on the immutability of physical constants look at dimensionless quantities, i.e. ratios between quantities of like dimensions, in order to escape this problem. Changes in physical constants are not meaningful if they result in an observationally indistinguishable universe. For example, a "change" in the speed of light c would be meaningless if accompanied by a corresponding "change" in the elementary charge e so that the ratio e²:c (the fine-structure constant) remained unchanged.

Natural units are systems of units entirely based in fundamental constants. In such systems, it is meaningful to measure any quantity which is not used in the definition of units. For example, in Stoney units, the elementary charge is set to e=1 while the reduced Planck constant is subject to measurement, ħ≈137.03, and in Planck units, the reduced Planck constant is set to ħ=1 while the elementary charge is subject to measurement, e≈ (137.03)^1/2. The proposed redefinition of SI base units, scheduled for 2018, seeks to express all SI base units in terms of fundamental physical constants, effectively transforming the SI system into a system of natural units.

Fine-structure constant

For the fine-structure constant, an upper bound on time variation of 10⁻¹⁷ per year has been published in 2008.

In 1999, evidence for time variability of the fine structure constant based on observation of quasars was announced.

Proton-to-electron mass ratio

An upper bound of the change in the proton-to-electron mass ratio has been placed at 10⁻⁷ over a period of 7 billion years (or 10⁻¹⁶ per year) in a 2012 study based on the observation of methanol in a distant galaxy.

Gravitational constant

The gravitational constant G is difficult to measure with precision, and conflicting measurements in the 2000s have inspired the controversial suggestions of a periodic variation of its value in a 2015 paper. However, while its value isn't known to great precision, the possibility of observing type Ia supernovae which happened in the universe's remote past, paired with the assumption that the physics involved in these events is universal, allows for an upper bound of less than 10⁻¹⁰ per year for the gravitational constant over the last nine billion years.

As a dimensional quantity, the value of the gravitational constant and its possible variation will depend on the choice of units; in Planck units, for example, its value is G=1 by definition. A meaningful test on the time-variation of G is equivalent to the test on the time-variation of the gravitational coupling constant, the ratio of gravitational attraction and electrostatic repulsion between two electrons (or, equivalently, the square of the electron mass in Planck units).

Cosmological constant

The cosmological constant is a measure of the energy density of the vacuum. It was first measured, and found to have a positive value, in the 1990s. It is currently (as of 2015) estimated at 10⁻¹²² in Planck units. Possible variations of the cosmological constant over time or space are not amenable to observation, but it has been noted that, in Planck units, its measured value is suggestively close to the reciprocal of the Age of the Universe squared, Λ ≈ T⁻². Barrow and Shaw (2011) proposed a modified theory in which Λ is a field evolving in such a way that its value remains Λ ~ T⁻² throughout the history of the universe.