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Hadron Structure with Antiprotons

Protons and neutrons - collectively called nucleons - belong to the family of hadrons. They are built of quarks and bound by the strong force that is mediated via gluons. The force is acting between two quarks and demonstrates an unusual behavior. It is very small when the quarks are at close distance and increases as the distance grows and then remains constant even if the quarks are removed further and further from each other. If one attempts to separate a quark-antiquark pair, the energy of the gluon field becomes larger and larger, until a new quark-antiquark pair can be created. As a result, one does not end up with two isolated quarks but with new quark-antiquark pairs instead. This absolute imprisonment of quarks is called confinement.


One of the greatest intellectual challenges of modern physics is to understand confinement not just as a phenomenon but to comprehend it quantitatively from the theory of the strong force. For this, physicists need a better understanding of the behavior of the strong force at medium and larger distances. Experimentally they plan to collide protons and antiprotons. Thereby short-lived new particles, e.g., charmonium particles can be created that consist of a c-quark and a c-antiquark.A detailed and precise spectroscopy of these charmonium states will provide new insights into the behavior of the strong force and the origin of confinement. Another puzzle of hadron physics addresses the origin of the hadron masses, i.e. of the particles composed of quarks. In the nucleon, less than 2% of the mass can be accounted for by the three valence quarks. Obviously, the bulk of the nucleon mass results from the kinetic energy and the interaction energy of the quarks confined in the nucleus. Physicists believe that new experiments exploiting high-energy antiproton and ion beams will also elucidate the generation of hadronic masses. Last but not least, physicists strive to search for new forms of matter that are predicted by the theory of the Strong Force, amongst them: Glueballs that consist of gluons only and so-called hybrids that are composed of two quarks and a gluon.

At the new FAIR facility at GSI, Darmstadt antiproton beams will allow high-precision hadron physics in the upcoming years. A dedicated high-energy storage ring, HESR, will deliver antiproton beams in the momentum range between 1.5 and 15 GeV/c with unprecedented beam qualities. The energy range has been chosen to allow detailed studies of hadronic systems up to charmonium states. The physics will be done with the PANDA multipurpose detector located inside the HESR. The PANDA collaboration consists of ~400 physicists from 48 institutions worldwide.

For the major part of the physics program a general-purpose detector will be used. It allows the detection and identification of neutral and charged particles over the relevant angular and energy range. The inner part of the detector can be modified for the needs of individual physics programs. To achieve the physics aims, the detector needs to cover the full solid angle. Good particle identification and excellent energy and angular resolution for charged particles and photons are mandatory. One important part of the detector is the electromagnetic calorimeter. This calorimeter will likely be an arrangement of PbWO4 (PWO) crystals, read out by avalanche photodiodes.
Last modified:03 May 2017 1.53 p.m.