Observation of vacuum induced birefringence induced by a transverse magnetic field

The PVLAS experiment operates an ellipsometer based on a Fabry-Perot optical cavity that embraces a superconducting dipole magnet and can measure ellipticity and rotation induced by the magnetic field onto linearly polarized laser light. With a residual pressure less than 10^-7 mbar the apparatus gives ellipticity signals at the level of 10^-11 rad per light passage through 1 m of 5 Tesla transverse magnetic field of 532 nm wavelength green laser light. These signals can be interpreted as being generated largely by vacuum birefringence. If this interpretation of the observed signals is valid, a tool has become available to characterize physical properties of vacuum as if it were an ordinary transparent medium. The main source of the induced ellipticity could be the existence of ultralight bosons with mass of the order of 10^-3 eV that would couple to two photons and would be created in the experiment by interactions of photons of the laser beam with virtual photons of the magnetic field. The apparatus is calibrated in amplitude and in phase by measuring Cotton-Mouton ellipticity in gases. The ellipticity induced in vacuum has phase opposite to that of the CME ellipticity induced with noble gases in the interaction region. If the ellipticity signals observed in vacuum are due to authentic quantum vacuum birefringence and not to the apparatus, and a microscopic interpretation of the effect in terms of existence of spin zero ultralight bosons is valid, the observed phase of the ellipticity implies a positive parity of the bosons. The ultralight bosons would then be scalars.