DØ conducted its scientific studies within six physics groups: Higgs, Top, Electroweak, New Phenomena, QCD, and B Physics. Significant advances were made in each of them.
Top quark One of the early goals of the DØ experiment was to discover the top quark, the last of the six constituents of matter predicted by the Standard Model of particle physics. The DØ and CDF experiments both collected data for the search, but they used different observation and analysis techniques that allowed independent confirmation of one another's findings. On February 24, 1995, DØ and CDF submitted research papers to
Physical Review Letters describing the observation of top and antitop quark pairs produced via the
strong interaction. On March 2, 1995, the two collaborations jointly reported the discovery of the top quark at a mass of about (nearly that of a gold nucleus). On March 4, 2009, the DØ and CDF collaborations both announced the discovery of the production of single
top quarks via the
weak interaction. This process occurs at about half the rate as the production of top quark pairs but is much more difficult to observe since it is more difficult to distinguish from background processes that can create false signals. The single top quark studies were used to measure the top quark lifetime of about 5 × 10−25 seconds, measure the last unknown element of the
CKM matrix of quark inter-generational mixing, and to search for new
physics beyond the Standard Model. Precision measurements of top quark properties such as mass, charge, decay modes, production characteristics, and polarization were reported in over one hundred publications. The
European Physical Society awarded the 2019
High Energy and Particle Physics Prize to the DØ and CDF collaborations "for the discovery of the top quark and the detailed measurement of its properties." • DØ's top-quark physics group's home page
Higgs boson In later years, one of the main physics goals of the DØ experiment was the search for the
Higgs boson, which was predicted to exist by the
Standard Model, but with an unknown mass. Before they concluded in 2000, the
LEP experiments at
CERN had ruled out the existence of such a Higgs boson with a mass smaller than . In 2010 DØ and CDF extended the forbidden region to include a window around . On July 2, 2012, anticipating an announcement from CERN of the discovery of the Higgs boson, the DØ and CDF collaborations announced their evidence (at about three standard deviations) for Higgs bosons decaying into the dominant b quark final states, which indicated that the particle had a mass between 115 and 135 GeV/c2. On July 4, 2012, CERN's
ATLAS and
CMS experiments announced their discovery of the Higgs boson with a mass of 125 GeV/c2. The techniques developed at the Tevatron for the Higgs boson searches served as a springboard for subsequent LHC analyses.
W and Z bosons The properties of the
W and Z bosons that transmit the weak nuclear force are sensitive indicators of the internal consistency of the Standard Model. In 2012, DØ measured the W boson mass to a relative precision of better than 0.03%, ruling out many potential models of new physics. The DØ and CDF experiments combined to measure the forward-backward asymmetry in the decays of Z bosons (the tendency of positive decay leptons to emerge closer to the incoming proton direction more often than negative decay leptons). From these asymmetry measurements, the weak mixing angle governing the breaking of the electroweak symmetry into distinct electromagnetic and weak forces was measured to a precision of better than 0.15%. This result has comparable precision to electron positron collider experiments at CERN and
SLAC and helps to resolve a long-standing tension between those measurements.
Bottom and charm quarks Although the
B-factory experiments at
KEK,
SLAC and
IHEP in Beijing and the
LHCb experiment at CERN have dominated many aspects of the study of
hadrons containing b- or c-quarks, DØ has made notable contributions using large samples containing all heavy flavor hadrons that can be seen through their decays to muons. In July 2006, the DØ collaboration published the first evidence for the transformation of the Bs meson (containing an anti-b quark and a strange quark) into its antiparticle. The transition occurs about 20 trillion times per second. If there were new particles beyond those in the Standard Model, this rate would have been modified. On May 14, 2010, the DØ collaboration announced a tendency for b and anti-b quarks produced in proton-antiproton collisions to lead to a pair of positively charged muons more frequently than a negatively charged pair. This tendency, together with measurements of single muon asymmetries, could help explain the
matter-antimatter asymmetry responsible for the dominance of matter in the universe. Experimental results from physicists at the
Large Hadron Collider, however, have suggested that "the difference from the
Standard Model is insignificant." On June 12, 2007, the DØ collaboration submitted a paper to
Physical Review Letters announcing the discovery of a new particle called the
Ξb (pronounced "zigh sub b") with a mass of , approximately six times the mass of a proton. The
Ξb baryon is made of a
down, a
strange and a
bottom quark, making it the first observed baryon formed of quarks from all three generations of matter. The original quark hypotheses by
Murray Gell-Mann and
George Zweig noted that exotic mesons containing two quarks and two antiquarks (instead of just a quark and antiquark) are possible. Examples were finally observed 40 years later in cases where the
exotic meson contains the more distinctive heavy b- and c-quarks. DØ has contributed new understanding of these heavy flavor exotic states.
Strong force Quantum chromodynamics (QCD) is the theory of the strong interaction, in which quarks and gluons interact through a quantum property, analogous to electric charge for electromagnetism, called "color." QCD makes quantitative predictions for the production of jets (collimated sprays of particles evolved from scattered quarks or gluons), photons and W or Z bosons. In 1999 – 2001, DØ published a series of papers investigating jet production as a function of beam energy, jet energy, and jet production angle. The measurement of the central inclusive jet cross section was followed by the measurement of the pseudorapidity and transverse-energy dependence of the inclusive jet production cross section, the measurement of the ratio of central inclusive jet cross sections at two center-of-mass energies, and a review article covering additionally the measurements of the dijet mass spectrum and the dijet angular distributions. A result in 2012 from DØ was the measurement of very high energy jets produced at large scattering angles. This occurs when single quarks carry more than half of the energy of their parent proton or antiproton, despite the fact that the proton and antiproton are typically built from dozens of quarks and gluons. The measurement was in excellent agreement with predictions. In a series of publications in which two pairs of jets or photons stemming from two independent scatterings of quarks and gluons within a single proton-antiproton encounter were observed, the pattern of these rates indicated that the spatial extent of gluons within the proton is smaller than that for quarks. == Detector ==