Although quantum mechanics (QM) and quantum ̄eld theory (QFT) are highly successful, the seemingly simplest state — vacuum — remains mysterious. While the LHC experiments are expected to clarify basic questions on the structure of QFT vacuum, much can still be done at lower energies as well. For instance, experiments like PVLAS try to reach extremely high sensitivities, in their attempt to observe the effects of the interaction of visible or near-visible photons with intense magnetic fields — a process which becomes possible in quantum electro- dynamics (QED) thanks to the vacuum fluctuations of the electronic field, and which is akin to photonphoton scattering. PVLAS is now close to data-taking and if it reaches the required sensitivity, it could provide important information on QED vacuum. PVLAS and other similar experiments face great challenges as they try to measure an extremely minute effect. However, raising the photon energy greatly increases the photonphoton cross section, and gamma rays could help extract much more information from the observed lightlight scattering. Here we discuss an experimental design to measure photonphoton scattering close to the peak of the photonphoton cross section, that could fit in the proposed construction of an FEL facility at the Cabibbo Lab near Frascati (Rome, Italy).
EXPLORING QUANTUM VACUUM WITH LOW-ENERGY PHOTONS
ZAVATTINI, Guido;
2012
Abstract
Although quantum mechanics (QM) and quantum ̄eld theory (QFT) are highly successful, the seemingly simplest state — vacuum — remains mysterious. While the LHC experiments are expected to clarify basic questions on the structure of QFT vacuum, much can still be done at lower energies as well. For instance, experiments like PVLAS try to reach extremely high sensitivities, in their attempt to observe the effects of the interaction of visible or near-visible photons with intense magnetic fields — a process which becomes possible in quantum electro- dynamics (QED) thanks to the vacuum fluctuations of the electronic field, and which is akin to photonphoton scattering. PVLAS is now close to data-taking and if it reaches the required sensitivity, it could provide important information on QED vacuum. PVLAS and other similar experiments face great challenges as they try to measure an extremely minute effect. However, raising the photon energy greatly increases the photonphoton cross section, and gamma rays could help extract much more information from the observed lightlight scattering. Here we discuss an experimental design to measure photonphoton scattering close to the peak of the photonphoton cross section, that could fit in the proposed construction of an FEL facility at the Cabibbo Lab near Frascati (Rome, Italy).I documenti in SFERA sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.