Phenomenology of Twin Higgs Model

Slides:

Advertisements

Similar presentations

Dark Matter Masaki Asano (Tohoku U.) Collaborators: Keisuke Fujii (KEK) Katsumasa Ikematsu (KEK) Rei Sasaki (Tohoku U.) Taikan Suehara (ICEPP, U. of Tokyo)

Advertisements

Searching for Doubly-Charged Higgs at the LHC Sá Borges, Cieza Montalvo Mauro Tonasse Nelson Cortez Universidade do Estado do Rio de Janeiro - Instituto.

1 Higgs Mechanism Cyril Topfel. 2 What to expect from this Presentation (Table of Contents) Some very limited theory explanation Higgs at.

26th Rencontres de Blois, Particle Physics and Cosmology, 2014 BSM Higgs Searches at the LHC C. H. Shepherd-Themistocleous PPD, Rutherford Appleton Laboratory.

Little Higgs Model Dark Matter and Its Implications at the LHC Chuan-Ren Chen (NTNU) KIAS-NCTS Joint Workshop High-1 2/9 – 2/15 In collaboration.

Little Higgs Dark Matter and Its Implications at the LHC Chuan-Ren Chen (NTNU) XS 2014, 5/6/2014 In collaboration with H-C Tsai, M-C Lee, [hep-ph]

Signatures of a new vector resonance from strongly interacting electroweak symmetry breaking M. Gintner, I. Melo, B. Trpišová University of Žilina Exotics.

Minimal Supersymmetric Standard Model (MSSM) SM: 28 bosonic d.o.f. & 90 (96) fermionic d.o.f. SUSY: # of fermions = # of bosonsN=1 SUSY: There are no particles.

4 th Generation Leptons in Minimal Walking Technicolor Theory Matti Heikinheimo University of Jyväskylä.

Jose E. Garcia presented by: Jose E. Garcia (IFIC-Valencia) on behalf of ATLAS Collaboration XXXIXth Rencontres de Moriond.

Discovery Potential for MSSM Higgs Bosons with ATLAS Johannes Haller (CERN) on behalf of the ATLAS collaboration International Europhysics Conference on.

J.E. Garcia RTN – December 03 PHD Work SCT beam test analysis: Tracking efficiency, noise occupancy, collected charge, S/N but also several studies: tracking.

05/11/2006Prof. dr hab. Elżbieta Richter-Wąs Physics Program of the experiments at L arge H adron C ollider Lecture 5.

Associated production of the Higgs boson and a single top quark in the littlest Higgs model at Large Hadron Collier Shuo Yang.

Center for theoretical Physics at BUE

Little Higgs Dark Matter & Its Collider Signals ・ E. Asakawa, M. Asano, K. Fujii, T. Kusano, S. M., R. Sasaki, Y. Takubo, and H. Yamamoto, PRD 79, 2009.

2. Two Higgs Doublets Model

Takehiro Nabeshima University of Toyama ILC physics general meeting 9 jun Phenomenology at a linear collider in a radiative seesaw model from TeV.

USTROŃ Maria Krawczyk University of Warsaw I. Ginzburg, K. Kanishev (Novosibirsk University), D.Sokołowska (University of Warsaw) 2HDMs.

Twin Higgs Theories Z. Chacko, University of Arizona H.S Goh & R. Harnik; Y. Nomura, M. Papucci & G. Perez.

1 Determination of Dark Matter Properties in the Littlest Higgs Model with T-parity Masaki Asano (SOKENDAI) Collaborator: E. Asakawa (Meiji-gakuin), S.

Report on LHT at the LHC ～ Some results from simulation study ～ Shigeki Matsumoto (Univ. of Toyama) 1.What kinds of LHT signals are expected, and how accurately.

Electroweak Symmetry Breaking without Higgs Bosons in ATLAS Ryuichi Takashima Kyoto University of Education For the ATLAS Collaboration.

Dynamical EWSB and Fourth Generation Michio Hashimoto (KEK) Mt. Tsukuba M.H., Miransky, M.H., Miransky, in preparation.

H. Quarks – “the building blocks of the Universe” The number of quarks increased with discoveries of new particles and have reached 6 For unknown reasons.

Update on the MSSM Interpretation of ATLAS Higgs Searches Markus Schumacher, Bonn University ATLAS Physics Workshop, Athens, May 2003 The Higgs Sector.

Charged Higgs boson at the LHC 이강영 ( 건국대학교 연세대학교

Same-Sign Diletpon Signatures of Vector-like Quarks Chuan-Ren Chen (NTNU) 11/03/2015, CYCU HEP seminar In collaboration with H.-C. Cheng and I. Low, 1511.*****

The two-Higgs-doublet model implementation in MadGraph v4 Michel Herquet In collaboration with Simon de Visscher and the MG/ME development team Center.

Same-Sign Diletpon Signatures of Vector-like Quarks Chuan-Ren Chen (NTNU) 11/20/2015, IoP HEP AS In collaboration with H.-C. Cheng and I. Low,

M. Frank, K. H., S.K. Rai (arXiv: ) Phys.Rev.D77:015006, 2008 D. Demir, M. Frank, K. H., S.K. Rai, I.Turan ( arXiv: ) Phys.Rev.D78:035013,

Measurements of the model parameter in the Littlest Higgs Model with T-parity 1 Masaki Asano (ICRR, Univ. of Tokyo) Collaborator: E. Asakawa ( Meiji-gakuin.

Measurements of the model parameter in the Littlest Higgs model with T-parity 1 Masaki Asano (ICRR, Univ. of Tokyo) Collaborator: E. Asakawa ( Meiji-gakuin.

We have the Higgs!!! Now What?? Nausheen R. Shah Wayne State University Oct 14, 2015 In Collaboration with: M. Carena, H. Haber, I. Low & C. Wagner arXiv:1510.xxxxx.

LHC, Prague, July 2003Filip Moortgat, University of Antwerpen LHC Praha 2003 Detection of MSSM Higgs bosons using supersymmetric decay modes.

New Strong LHC Rogerio Rosenfeld Instituto de Física Teórica UNESP

Determining the CP Properties of a Light Higgs Boson

Using Tau polarization for Charged Higgs boson & SUSY LHC

Nady Bakhet PhD Student – Cairo University PhD Thesis Title

Electroweak Physics Lecture 6

The e+e- collider experiments to search for dark matter

The two-Higgs-doublet model implementation in MadGraph v4

Dark Sectors for and anomalies

Phenomenology of Twin Higgs Model

Lecture 13 Higgs Hunting --- The experimental Perspective

MSSM4G: MOTIVATIONS AND ALLOWED REGIONS

Xinyu Miao Department of Physics Univ. of Arizona 03/30/07

The Flavor of a Little Higgs with T-parity

Some Implications Of The Recent LHC Higgs Search Results Xiao-Gang He (SJTU&NTU) Xiao-Gang He and German Valencia, arXiv: Xiao-Gang He and.

Shufang Su • U. of Arizona

Phenomenology of Twin Higgs Model

Xinyu Miao Department of Physics Univ. of Arizona 03/30/07

The MESSM The Minimal Exceptional Supersymmetric Standard Model

The Graduate University for Advanced Studies Masaki Asano hep-ph/

Louisiana Tech University

Shufang Su • U. of Arizona

mSUGRA SUSY Searches at the LHC

浪漫之都大连欢迎您！. 浪漫之都大连欢迎您！ Pair production of the scalars from the LRTH model Ma Wei Liaoning Normal University, Dalian Wei Ma, Chong-Xing Yue, Yong-Zhi.

Testing the Standard Model and Beyond

Phenomenology of Twin Higgs Model

ttbar Cross-Section Studies leading to ttbar Resonance

Physics beyond the SM in Kaon decays --Theory--

SUSY WIMP and Collider Signatures

SUSY SEARCHES WITH ATLAS

Custodial SU(2) Symmetry

Shuo Yang Associated production of the Higgs boson and

Prospects for TeV Scale New Physics at LHC

Can new Higgs boson be Dark Matter Candidate in the Economical Model

Direct Search and LHC Detection of the Simplest Dark Matter

Search for a New Vector Resonance in the pp WWtt+X Channel at LHC

Presentation transcript:

Phenomenology of Twin Higgs Model Shufang Su • U. of Arizona Hock-Seng Goh, Shufang Su Work in progress

Outline Twin Higgs Model Collider phenomenology Twin Higgs mechanism - Twin Higgs Model Twin Higgs mechanism Left-right Twin Higgs model New particles and model parameters Collider phenomenology Heavy top quark Heavy gauge bosons Higgses Goh’s talk Chacko, Goh, Harnik, hep-ph/0512088 S. Su

SU(2)L  SU(2)R  U(1)B-L  SU(2)LU(1)Y Left-right Twin Higgs model U(4)  U(4), with gauged SU(2)LSU(2)RU(1)B-L + LR symmetry - Couple to gauge boson only SM Higgs doublet EWSB SM neutral Higgs: H SU(2)L Higgs doublet H1, H20 3 eaten by heavy gauge bosons Left 3 Higgses: neutral Higgs 0, charged Higgs  U(4)  U(3) SU(2)L  SU(2)R  U(1)B-L  SU(2)LU(1)Y  U(4)  U(3) 7 GB 7 GB f2  f1 S. Su

Left-right Twin Higgs model Fermion sector: Top quark mass: Top quark mass eigenstates: SM top and tH S. Su

New particles Heavy gauge bosons: WH, ZH m2WH,ZH  g2(f12+f22) - Heavy gauge bosons: WH, ZH m2WH,ZH  g2(f12+f22) Heavy top: tH m2TH  M2+y2f12 Other SU(2)R Higgses:  m2  g4/(162)f22 log(/gf2) 0 m20  B (f2/f1) B: small, (50-100 GeV)2 Other SU(2)L Higgs H1 m2H1, H20   H20 : soft symmetry breaking, O(f1) S. Su

Model parameters Model parameters: f1, (f2, y), , M, B,  - Model parameters: f1, (f2, y), , M, B,  Determine particle masses and interactions fixed by Higgs VEV = 4f1 or 2f1 M=150 GeV B=50 GeV  = f1/2 fixed by top quark mass S. Su

Heavy top tH production - single heavy top production heavy top pair production S. Su

Heavy top tH decay 3 b + 1 j + 1 lepton + missing ET j  l t tH W - j W tH  b t l  3 b + 1 j + 1 lepton + missing ET j tH W b l  1 b + 1 j + 1 lepton + missing ET S. Su

Heavy gauge boson production - Drell-Yan process S. Su

ZH decay - ZH 2 b + 2 j + 1 lepton + missing ET t q b W l  ZH S. Su

WH decay WH tH b: 4b + 1 lepton + missing ET - WH tH b: 4b + 1 lepton + missing ET tH bW : 2b + 1 lepton + missing ET tH tZ: 2b + 3 lepton + missing ET S. Su

Higgses SM Higgs mH  150-170 GeV, depending on f1,  and M Higgs searches: gg  H  ZZ*  llll gg  H  WW*  ll WBF  qqH  qqWW*  qqll SU(2)R Higgs: 0,  0  bb j   tb 2b + 1 lepton + missing ET S. Su

0 Neutral Higgs 0 gg  0  bb, QCD background overwhelming - Neutral Higgs 0 gg  0  bb, QCD background overwhelming no W0, Z0 associated production (no such coupling) bb0 , tb0, tt0 cross section small Produced via the decay of heavy particles WH  b t W 0 l  4 b + 1 lepton + missing ET S. Su

 - Neutral Higgs  no W, Z associated production (no such coupling) bb , tb, tt cross section small Produced via the decay of heavy particles j W tH  b t l  3 b + 1 j + 1 lepton + missing ET S. Su

H1, H20 H20: good dark matter candidates - Higgs that couple to gauge boson only: H1, H20 H1H20, H1H1, H20H20, associated production (small) H20 stable : missing energy H1  H20 + soft jets/leptons if decay fast enough: appears as missing energy if decay slow: track ! H20: good dark matter candidates S. Su

M=0 case Top Yukawa: f1 v tH = (TL, tR), mtH = yf1 - Top Yukawa: f1 v tH = (TL, tR), mtH = yf1 tSM = (tL, TR), mt = yv Gauge coupling Yukawa coupling 0  tH  tH 0  t  t 0  tH  t H  t  t H  tH  tH (small) H  tH  t W  t  b W  tH  b WH  t  b WH  tH  b Z  t  t Z  tH  tH Z  tH  t ZH  t  t ZH  tH  tH ZH  tH  t   tH  b   t  b   t + b (100%) X S. Su

 decay No two body decay Leading decay: 3 body - No two body decay Leading decay: 3 body off-shell 0  bb: bbqq final states huge QCD bg H  ZZ*, WW* small signal S. Su

 discovery Difficult Large QCD bg or small signal small signal S. Su - Difficult Large QCD bg or small signal small signal S. Su

0 discovery - difficult small signal absent S. Su

Heavy top tH discovery single, pair production does not change much. - single, pair production does not change much. decay: only tH  b  (100%) 100% either huge QCD bg Or small signal absent S. Su

Heavy gauge boson discovery - ZH, WH drell-yan cross section does not change ZH: ZH  ll does not change much  Br(ZH  t tH) =0 WH: difficult For M=0 discovery of almost all the particle are difficult except for ZH either huge QCD bg Or small signal absent S. Su

Conclusions - Left-right twin Higgs model: Higgs as pseudo-goldstone boson quadratic divergence forbidden by left-right symmetry New particles Heavy gauge boson: WH, ZH Heavy top quark tH New Higgses: 0, , H1, H20 (DM) M0: rich collider phenomenology M=0: difficult except for ZH Future work Pick certain channel for detailed study: background, cuts,… Identify twin Higgs mechanism Dark matter study Comparison with other models, e.g., little higgs S. Su