Marc Vanderhaeghen 1 Introduction LEPP16 Marc Vanderhaeghen LEPP16 Workshop Kupferberg, Mainz, April 4-7, 2016 New Vistas in Low-Energy Precision Physics LEPP16: Introduction
Marc Vanderhaeghen 2 Introduction LEPP16 Frontiers of the Standard Model Fra Mauro(1459)
Marc Vanderhaeghen 3 Introduction LEPP16 Frontiers of the Standard Model LHC Higgs discovery Production of new physics particles Later: ILC New Physics Englert, Higgs Nobel prize 2013 Higgs discovery
Marc Vanderhaeghen 4 Introduction LEPP16 Frontiers of the Standard Model Testing SM at low energies, quantum loop corrections sin 2 θ W (g-2)μ EDM Flavor physics Atomic physics H. Bethe(1947) New Physics
Marc Vanderhaeghen 5 Introduction LEPP16 Frontiers of the Standard Model Terra incognita New Physics Hadron physics: Strong interactions, Complex systems How do quarks/gluons merge into hadrons (mass, spin,…) ? How does hadron structure emerge from basic constituents? from quarks to stars: looking outward vs looking inward Hans Bethe: Nobel prize 1967
Marc Vanderhaeghen 6 Introduction LEPP16 Central concept of CRC 1044 Hadron physics (= The Low-Energy Frontier of the Standard Model) plays a central and connecting role in interpretation of measurements at the precision frontier of the Standard Model Particle physics Atomic physics Astro(particle) physics Strong interactions Hadron structure Hadron spectroscopy sin 2 W (g-2) μ R E Proton charge radius polarizabilities Neutron skin, nuclear EOS Low-Energy Precision Physics Few-body nuclei dark photons, dark matter
Marc Vanderhaeghen 7 Introduction LEPP16 R E = ± fm R E = ± fm ep-data : H data : 7 difference Pohl et al.(2010) CODATA(2012) Antognini et al.(2013) Lepton scattering experiments: global analysis, new experiments, e / μ universality, … Theory: hadronic corrections to atomic spectroscopy and electron scattering Hadron physics input: polarizability program on nucleons / few-body systems New avenues Proton radius puzzle
Marc Vanderhaeghen 8 Introduction LEPP16 SM: universal quantum corrections leads to a scale dependent, „running“ sin 2 θ W (Q) Marciano Sensitivity to new beyond SM physics: new fermions extra Z mixing with dark Z contact interactions 0.13% measurement of sin 2 θ W Λ new ≈ 49 TeV contact int: Λ new ≈ 17 TeV Proton parity program: exceeding scale accessible in direct LHC searches, complementarity with precision LHC Nuclear parity program: use parity violation tool in a complementary way to extract the neutron skin of nuclei -> relevance to nuclear astrophysics Precision parity violation program
Marc Vanderhaeghen 9 Introduction LEPP16 0.9% total systematic uncertainty achieved hadronic vacuum polarization hadronic light-by-light scattering Dominant region covered by BESIII Interplay exp – theory (dispersion, lattice) e + e - -> π + π - : most relevant channel for (g-2) μ a μ exp – a μ SM = (28.7 ± 8.0) · (3.6 σ) New FNAL (g-2) μ expt. (2016): δ a μ exp = 1.6 x P5 panel (2014): flagship expt. Muon magnetic moment: (g-2) µ
Marc Vanderhaeghen 10 Introduction LEPP16 Year 2015 Dark Photon as explanation for (g-2) µ (almost) ruled out ! … at least in most straight-forward model Low-mass/low-coupling range will be covered by JLab, MESA,… expts. Standard Model Sector U(1) Dark Sector U(1) d γ γ Heavy Charged Leptons L (carry U(1) d charge) Dark Photon (aka A, U, Z d,...) DM e+e+ e-e- light dark sector: could explain astrophysical anomalies: e + excess in cosmic ray flux possible explanation for (g-2) μ Holdom (1986),... red band: (g-2) μ Bjorken et al.(2009) Dark photon / dark matter searches
Marc Vanderhaeghen 11 Introduction LEPP16 Outlook Precision Low Energy expts. New tools: MESA,... Identify key expts. Impact new physics: determine required precision Complementarity: precision hadron structure Goal: “Physics Book”
Marc Vanderhaeghen 12 Introduction LEPP16 Have a productive time in Mainz !