Scientists at EPFL have analyzed data from the Large Hadron Collider that offer a first-time observation of an unexpected photon polarization. When emitted in a bottom-quark particle decay, photons behave unlike the predictions of the Standard Model.
Elementary particles, like photons, have a property called spin. If the particle is imagined as a spinning top, its spin refers to its angular momentum – the measure of how much rotation the particle has. For photons, this rotation can be either clockwise or counter-clockwise, and the photons are said to be either “left-” or “right-handed”. The measure of how much it is left-handed or right-handed is called “polarization”. The Standard Model, which also predicted the existence of the Higgs boson, includes this phenomenon. However, a recent observation by EPFL scientists at CERN’s Large Hadron Collider (LHC) implies a new type of photon polarization that goes beyond the predictions of the Standard Model. The implications of photons’ new behavior casts light on a dark corner of particle physics.
The Standard Model is a theory that, so far, can successfully describe all known phenomena between elementary particles, including the Higgs boson discovered in 2012 at the LHC. According to the Standard Model, the elementary constituents of matter are either leptons (such as the electron or the neutrino) or quarks. There are six types (or “flavors”) of quarks: down, up, strange, charm, bottom, and top.
Quarks can transform from one flavor to another, e.g. through the ‘beta decay’ of some unstable atoms. Another example is the transformation of a bottom quark into a strange quark through the emission of a very energetic photon. In this case, the Standard Model predicts that the photon should be almost always left-handed. However, such a photon polarization has never before been observed directly.
Now, the group of Olivier Schneider at EPFL has analyzed data recorded in 2011 and 2012 with the LHC “beauty” detector. By measuring a mathematical “effect” proportional to photon polarization, the team found that when a bottom quark decays into a strange quark and emits a photon, that photon is polarized. This is what the particle physics community refers to as an "observation": the chances of it being the result of statistical error is less than one in three million.
“Our observation opens the way to a future measurement of the photon polarization, which will be a test of the Standard Model or, equivalently, a search for entirely new physics effects”, says Olivier Schneider. “Indeed, if new particles or new forces exist and interfere with the Standard Model process, the photon may not be almost purely left-handed.”
This data analysis was performed within the Laboratory of High Energy physics (EPFL/SB/IPEP/LPHE), by Giovanni Veneziano and Albert Puig, and has been vetted by their LHCb collaborators. The LHCb collaboration (of which the EPFL group of Aurelio Bay, Tatsuya Nakada and Olivier Schneider is an active member) has designed, constructed, calibrated and operated the LHCb detector, as well as developed the software needed to process the data. The EPFL team is now preparing to publish their finding in an LHCb paper to be submitted to Physical Review Letters.