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NEWS

Prof. Wim Ubachs

Department of Physics and Astronomy, LaserLaB, VU University (Amsterdam)

Friday, October 19th, 2012 at 11:00:00 AM  

Conference room Querzoli - LENS - via Nello Carrara 1 - Sesto Fiorentino (Florence)

Enrico Fermi Colloquium

Published on-line at 04:33:05 PM on Thursday, August 2nd, 2012

Search for drifting constants in a dynamical Universe

Laws of nature and fundamental constants may be subject to change in time or space?

Since the days of Dirac scientists have speculated about the possibility that the laws of nature, and the fundamental constants appearing in those laws, are not rock-solid and eternal but may be subject to change in time or space. Such a scenario of evolving constants might provide an answer to the deepest puzzle of contemporary science, namely why the conditions in our local Universe allow for extreme complexity: the fine-tuning problem.

Laser setup used to measure highly accurate spectra of H2 molecules in the laboratory. In the main picture there is a view on the Very Large Telescope(s) used to detect H2 at high redshift. Here is a picture of the Effelsberg radiotelescope in operation.

In the past decade it has been established that spectral lines of atoms and molecules, which can currently be measured at ever-higher accuracies, form an ideal test ground for probing drifting constants. This has brought this subject from the realm of metaphysics to that of experimental science. In particular the spectra of molecules are sensitive for probing a variation of the proton-electron mass ratio μ, either on a cosmological time scale, or on a laboratory time scale. A comparison can be made between spectra of molecular hydrogen observed in the laboratory and at a high redshift (z = 2 or 3), using the Very Large Telescope (Paranal, Chile) and the Keck telescope (Hawaii). This puts a constraint on a varying mass ratio Δμ/μ at the 10-5 level. The optical work can also be extended to include CO molecules.

Further a novel direction will be discussed: it was discovered that molecules exhibiting hindered internal rotation have spectral lines in the radio-spectrum that are extremely sensitive to a varying proton-electron mass ratio. Such lines in the spectrum of methanol were recently observed with the radio-telescope in Effelsberg (Germany).

[video=720 540]a20121019_ubachs[/video]

Klein colloquium by Dr. Francesco Cappelli: "Narrow-linewidth Quantum Cascade Lasers for precise measurements in molecular physics".

[video=720 540]b20121019_cappelli[/video]