H1 (particle detector)

The construction of an lepton-proton collider was recommended strongly by ECFA on May 9, 1980 . The first proposals for the H1 detector have been made in 1981 and the letter of intent for the H1 experiment was published on June 28, 1985 . The technical proposal for the H1 detector was finalized on March 25, 1986 .

The H1 detector was operational with the first collisions of HERA in 1992. It was upgraded during the HERA luminosity upgrade for the HERA-II running period from 2000 to 2003. The H1 detector then took data until the shutdown of HERA in June 2007 and was mostly dismantled afterwards.

Several subdetector components are now exhibited in the HERA Hall West at DESY. The HERA North Hall, where the H1 detector was located, is now used for other particle physics and gravitational experiments by DESY.

The data taken with the H1 detector are preserved for future analyses within the DPHEP (Data Preservation and Long Term Analysis in High Energy Physics) initiative .

The "sister experiment" of H1 at the HERA accelerator is the ZEUS experiment, which is also a multi-purpose detector with similar physics goals as H1.

The H1 experiment was designed and operated by an international collaboration of about 400 physicists and technicians from 43 institutes in 18 countries (List of currently participating institutes).

Leptons (electrons or positrons) are collided with protons by HERA in the interaction point of H1 and the particles produced in these collisions were detected by the H1 detector components. The reaction products, often including the proton remnant and the scattered lepton, are detected by several subdetectors. Combination of their information allows the identification of particles from the reaction, or at least the reconstruction of the overall reaction kinematics. This in turn allows the classification of the reaction. From the center outwards, H1's most important systems are:

• Silicon trackers for the determination of primary and secondary vertices.
• Jet chambers for the measurement of charged particle tracks.
• Liquid Argon (LAr) calorimeter for the measurement of electromagnetic and hadronic showers.
• Lead/scintillating fibre calorimeter (SpaCal) in the backward direction for the measurement of the scattered lepton.
• The superconducting solenoidal magnet to bend the charged particles trajectories.
• Muon detectors in the iron magnet yoke surrounding H1 and in the forward direction.

In addition to these systems, H1 has several helper systems, such as a luminosity system, ToF (time of flight) detectors and radiation monitors. Also in the course of time additional detector systems have been added as the focus on special physics processes has become bigger. For example, forward instrumentation for diffractive physics has been added far down the HERA tunnel.

While H1 is a general purpose detector its main design feature is an asymmetric construction to cope with the boosted center of mass in the laboratory frame due to the large energy imbalance of the colliding beams. In the forward (incident proton) direction the instrumentation has higher granularity to give a better resolution for refined measurement of the proton remnant left after the collision with the incident lepton. In the backward direction, where the lepton is mostly scattered into the detectors were optimized for the reconstruction of the scattered lepton trajectory.

The most interesting physics topics treated at H1 include

• Cross section measurements of reactions with charged and neutral electroweak currents
• Studies of proton structure and determination of quark and gluon parton distribution functions
• Tests of QCD in jet and particle production
• Production of heavy quarks (charm and bottom)
• Tests of Electroweak theory
• Diffraction (physics with the exchange of a pomeron)
• Search for physics beyond the Standard Model (For example, the substructure of quarks / contact interactions, Leptoquarks, magnetic monopole)

• H1 public homepage
• H1 public and collaboration homepage
• List of Publications