Higgs Physics and Cosmology

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Higgs Physics and Cosmology Koichi Funakubo Department of Physics, Saga University 1 This year will be the year of Higgs particle. The discovery of Higgs-like boson will be reported with higher statistics in this March. To cofirm it is the Higgs boson, we must check relation between the couplings and the particle masses W, Z bosons, quarks, leptons 3- and 4-body self-interaction of the boson 2 The Higgs field in the Standard Model provides the masses of all the weak gauge boson and fermions. Yukawa coupling matrix Higgs field No mass scale in the gauge and fermion sector. 3

The only mass scale arises from the Higgs sector. where Similarly for the fermions, 4 setting unitary gauge Higgs boson The couplings of the Higgs boson to the gauge bosons and fermions are proportional to their masses. The effect of the unitary transformation resides only in the quark charged-current interaction. CKM matrix 5 masses of the SM particles except for the higgs boson electric charge 1st gen. 2nd gen. 3rd gen. 2 3MeV 1.27GeV 174GeV 80.4GeV 91.2GeV 4 6MeV 101MeV 4.2GeV 0.51MeV 106MeV 1.8GeV N.B. 90% of the nucleon mass comes from QCD dynamics. --- confirmed by lattice MC calculation 6

decay branching rate f h f W, Z h W, Z off-shell vector 3- or 4-body decay h W, Z f f W, Z h W, Z W, Z f f f f one-loop processes h f f f γ γ h q q q g g 7 200 Made from the data generated by H-Decay package 8 What determines the value of the Higgs VEV v0? 4-Fermi effective theory vs W-exchange interaction e.g. weak decay (V A)-type current-current interaction 9

Theoretically, it is the location of the minimum of the scalar potential of the Standard Model. including quantum corrections at the classical (tree) level gauge-invariant renormalizable Coleman-Weinberg mechanism quantum correction to the potential takes min. at renormalization scale 10 A part of the gauge symmetry of the SM is spontaneously broken by A symmetry of the lagrangian is broken by the ground state. Picking up a point from the degenerate states breaks the symmetry. classically degenerate ground state 11 Similarity to magnetism Hamiltonian of the spin model invariant under the spatial rotation the lowest E degenerate ground state breaks the rotational symmetry 12

Heating up a magnet looses its magnetism. Symmetry restoring phase transition Fe: 1043K One may expect a similar symmetry restoring Phase Transition to occur in the Higgs sector. maybe at 100GeV=10 15 K It s impossible to reach such a high-t on the Earth, but is though to be realized in the early Universe. 13 Brief Review of the Big Bang Cosmology Evolution of the space is described by Einstein equation: curvature cosmological constant (vacuum energy) energy-momentum tensor spatially uniform and isotropic Universe = Friedmann-Robertson-Walker spacetime so large scale as 10 8 ly at present scale factor relative to the present curvature parameter Einstein eq. diff. eq. for 14 uniform and isotropic energy density pressure satisfies the conservation law 3 types of Equation Of State EM conservation Matter (nonrelativistic) Radiation (relativistic) Vacuum (or Dark Energy) Which species behaves as radiation depends on temperature. 15

Friedmann equation =Einstein equation for FRW metric observation : The early Universe of is dominated by radiation. 16 At present, only the photons (and maybe the neutrinos) have the equilibrium distribution. [Cosmic Microwave Background] In the radiation-dominated Universe species tightly coupled to the plasma can be regarded as in equilib., even though the Universe was expanding. criterion for coupling to the plasma Expansion rate < interaction rate determined by the cross section and number density Then we can define the temperature T and apply the equilibrium statistical mechanics. 17 interaction rate for relativistic species total cross section of that species mean free path for the weak interaction, number density effective degrees of freedom λ σ 18

expansion rate when all the SM particles are relativistic EW QCD At temperatures of the weak scale, we can safely regard all the SM particles are in thermal equilibrium. 19 comments If the Universe has been in equilibrium throughout its history, there would be no stars, galaxies, structures and creatures including ourselves. nonequilibrium events due to decoupling of photons (T=1eV) nucleosynthesis (T=1MeV) decoupling of the Dark Matter GUTs Baryogenesis/Leptogenesis We need to treat time-dependent distribution functions. 20 We apply the equilibrium statistical mechanics to study static features of the phase transition of the EW symmetry breaking. Quantum Field Theory at finite temperatures Kapusta and Gale, Finite-temperature field theory (2006) 2nd ed. Le Bellac, Thermal Field Theory (2000) Landsman and van Weert, Phys. Rep. 145 (1987) 141 Dolan and Jackiw, Phys. Rev. D9 (1974) 3320 free energy density as a function of the order parameters =effective potential at finite temperatures euclidean path integral 21

free energy vs order parameter (Higgs VEV) at finite T V eff (v;t) V eff (0;T) T > T C > 0 T > T C > 0 order parameter v C v 0 v v 0 v v(t) v(t) v 0 T C 2nd order PT T v 0 v C T C 1st order PT T 1st order phase transition 22 Standard Model 1-loop corrections High-T expansion IR nonanalyticity symmetry restoration at high-t 23 Assuming 1st order PT 24

In most cases, the perturbative expansion at high temperatures is not a good approximation. Dolan and Jackiw, Phys. Rev. D9 (1974) corrections to 2-point function 25 loop expansion is invalidated resummation in the propagator thermal mass weakens the PT 26 A nonperturbative analysis: Lattice MC calculation link variable [Csikor, hep-lat/9910354] 1st order Phase Transition for End point of the Phase Transition at Cross Over 27

As expected, we have seen that the broken gauge symmetry was restored at high temperatures. free energy EWPT (Electroweak PT) Higgs field no dramatic event Recall If the EWPT is 1st order, some events might occur which affect the present Universe. 28 Why 1st order PT? e.g. evaporation of water PT proceeds through nucleation and growth of bubbles Veff nucleation temp. broken phase O v vc = symmetric phase latent heat non-equilibrium state near expanding bubble walls release of the latent heat 29 If the EWPT is 1st order, Gravitational wave might be generated by bubble collisions and/or by turbulence of the plasma ϕ z r t = 30 t=0 t = 45 EM tensor of the scalar field The energy density of GW may be marginally observed by LISA. Laser Interferometer Space Antenna http://lisa.nasa.gov/ For a review, see M. Maggiore, Phys. Rep. 331 (2000) 283 30

the Baryon Asymmetry of the Universe might be generated at PT = scenario of the Electroweak Baryogenesis (EWBG) Both the baryon and lepton numbers are conserved in the SM at the classicl level (=symmetry of the Lagrangian). However, (B+L) is not conserved at quantum level. Chern-Simons number 31 sphaleron energy If the interaction of the plasma particles with the bubble wall violates CP-symmetry, some chiral charge is injected in the symmetric phase. v v C v w chiral charge v co broken phase 32 symmetric phase The chiral charge biases the (B+L)-changing process. Generated (B+L) is frozen in the broken phase. CP-violating bubble walls are transparent to the vectorlike quantum numbers such as B and L. z Review articles on EWBG KF, Prog. Theor. Phys. 96 (1996) 475 Rubakov and Shaposhnikov, Phys. Usp. 39 (1996) 461 Riotto and Trodden, Ann. Rev. Nucl. Part. Sci. 49 (1999) 35 Bernreuther, Lect. Notes Phys. 591 (2002) 237 Even if the EWPT in the SM is of first order, the KM phase is insufficient to generate the BAU. For the EWPT to be of fist order, we must extend the SM. Which extension makes the EWPT of first order? 33

bosonic loop correction bosons interacting with the Higgs whose mass behaves as e.g. extra scalars in the two-higgs-double Model (2HDM), Supersymmetric SM s 2HDM with the discrete symmetry to avoid FCNC vast allowed region of parameters KF, Kakuto, Takenaga, Prog. Theor. Phys. 91(1994) 34 MSSM Minimal Supersymmetric Standard Model order parameters: 8 3 = 5 physical Higgs particles 3 neutral, 1 charged radiative corr. from top/stop loops small Higgs mass extra Higgs bosons SM with relatively light Higgs 35 EWPT becomes SM-like the stop mass matrix smaller eigenvalue 150 makes the EWPT of first order 100 v 2 With mh=125gev, it s difficult to leave the BAU. KF and Senaha, Phys. Rev. D79 (2009) 36 50 0 0 5 10 15 20 25 v 1

new class of PT s in the model with a gauge singlet e.g. Next-to-MSSM (NMSSM) = MSSM with a singlet superfield Higgs fields new self-coupling heavy Higgs reduced to MSSM 37 GeV 700 type-b λ=0.85, κ=-0.1 600 500 400 v n 300 200 100 0 0 50 100 150 200 250 300 GeV v 1.0x10 8 5.0x10 7 0.0x10 0-5.0x10 7-1.0x10 8-1.5x10 8 strong 1st order PT without a light stop KF, Tao and Toyoda, Prog. Theor. Phys. 114 (2005) CP violating complex parameters: some combinations of them do not affect EDM of n and μ, which are viable for the baryogenesis 38 Summary The Higgs mechanism explains the masses of the weak gauge bosons and fermions in the Standard Model, without spoiling renormalizability and unitarity of the theory. Although existence of the Higgs boson has not yet been established, various observations seem to support it. success of the electroweak theory Even if discovery of a CP-even scalar of 125GeV is established, we must do many to check whether it is the SM Higgs boson. decay branching ratios of various modes self-coupling of the scalar boson 39

If the present vacuum is the result of the Higgs mechanism, the state at very high temperatures is different from it and the broken gauge symmetries are restored. As the Universe cooled down to weak-scale temperature, the gauge symmetry of the EW theory was spontaneously broken by the expectation value of the Higgs fields. Electroweak Phase Transition (EWPT) Properties of the EWPT depends on the EW model. Standard Model with mh=125gev Cross Over MSSM NMSSM 2HDM open possibility of 1st order EWPT extra bosons, another order parameter 40 So far, the SM has been tested in experiments and found to be consistent with their results. We, however, know that some extension of the SM is needed to explain the obvious facts, Neutrino mass Dark Matter Baryon Asymmetry of the Universe Some of the extended models contain extra scalar fields, which may lead to the 1st order EWPT. In particular, extended Higgs sectors predict charged Higgs bosons and extra neutral Higgs bosons, which combine with each other to make mass eigenstates. decay BR s deviate from the SM prediction CP violation in the Higgs sector,... etc. mission of ILC 41 Thanks for your attention! 42

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