Title :
Temporal and spatial variation of fundamental constants: theory and observations
Author_Institution :
New South Wales Univ., Sydney
fDate :
May 29 2007-June 1 2007
Abstract :
Space-time variation of the fundamental constants is suggested by theories unifying gravity with other interactions. It also can explain fine tuning of the fundamental constants which is needed for life to appear. Review of recent works devoted to the variation of the fine structure constant a, strong interaction and fundamental masses (Higgs vacuum) is presented. The results from Big Bang nucleosynthesis, quasar absorption spectra, and Oklo natural nuclear reactor data give us the space-time variation on the Universe lifetime scale. Comparison of different atomic clocks gives us the present time variation. Assuming linear variation with time we can compare different results. The best limit on the variation of the electron-to-proton mass ratio mu = me/Mp and Xe = me/LambdaQCD follows from the quasar absorption spectra [1]: mu dot/mu = X dote/Xe = (1plusmn3) times 10-16 yr-1. A combination of this result and the atomic clock results [2, 3] gives the best Unit on variation of alpha: alpha dot/alpha = (-0.8 plusmn 0.8) times 10-16 yr-1. The Oklo natural reactor gives the best limit on the variation of Xs = ms/LambdaQCD where ms is the strange quark mass [4, 5]: |X dots/Xs| < 10-18 yr-1. Note that the Oklo data can not give us any limit on the variation of alpha since the effect of alpha there is much smaller than the effect of Xs and should be neglected. Huge enhancement of the relative variation effects happens in transitions between close atomic, molecular and nuclear energy levels. We suggest several new cases where the levels are very narrow. Large enhancement of the variation effects is also possible in cold atomic and molecular collisions near Feshbach resonance. How changing physical constants and violation of local position invariance may oc- cur? Light scalar fields very naturally appear in modern cosmological models, affecting parameters of the standard model (e.g. alpha). Cosmological variations of these scalar fields should occur because of drastic changes of matter composition in Universe: the latest such event is rather recent (about 5 billion years ago), from matter to dark energy domination. Massive bodies (stars or galaxies) can also affect physical constants. They have large scalar charge S proportional to number of particles which produces a Coulomb-like scalar field U = S/r. This leads to a variation of the fundamental constants proportional to the gravitational potential, e.g. deltaalpha/alpha = kalphadelta(GM/rc2). We compare different manifestations of this effect. The strongest limits [6] kalpha + 0.17ke = (-3.5 plusmn 6) times 10-7 and kalpha + 0.13kq = (-1 plusmn 17) times 10-7 are obtained from the measurements of dependence of atomic frequencies on the distance from Sun [2, 7] (the distance varies due to the ellipticity of the Earth´s orbit).
Keywords :
atomic clocks; celestial mechanics; constants; cosmology; gravity; Big Bang nucleosynthesis; Coulomb-like scalar field; Feshbach resonance; Higgs vacuum; Oklo natural nuclear reactor data; Universe lifetime scale; atomic clocks; cold atomic collisions; cosmological models; electron-to-proton mass ratio; fine structure constant; fundamental constants; fundamental masses; gravitational potential; light scalar fields; linear variation; molecular collisions; quasar absorption spectra; space-time variation; spatial variation; strange quark mass; temporal variation; Absorption; Atomic clocks; Atomic measurements; Dark energy; Elementary particle vacuum; Energy states; Gravity; Inductors; Q measurement; Resonance;
Conference_Titel :
Frequency Control Symposium, 2007 Joint with the 21st European Frequency and Time Forum. IEEE International
Conference_Location :
Geneva
Print_ISBN :
978-1-4244-0646-3
Electronic_ISBN :
1075-6787
DOI :
10.1109/FREQ.2007.4319094