You need JavaScript to view this
ETDEWEB   /       /    The electroweak phase transition: a non-perturbative lattice investigation

The electroweak phase transition: a non-perturbative lattice investigation

Journal Article:

SAVE / SHARE

XML RIS EndNote CSV/Excel JSON

Abstract

We present results obtained from a numerical investigation of the electroweak phase transition in the SU(2)-Higgs model. The simulations are performed at two values of the Higgs boson mass, M{sub H}{approx}20GeV and M{sub H}{approx}50GeV. While the phase transition is of strongly first order at the smaller value of the Higgs mass it weakens rapidly when the Higgs mass is increased. This is in qualitative agreement with perturbation theory as the comparison of various physical quantities shows. ((orig.)).
Authors:
Csikor, F; [1]  Fodor, Z; [2]  Hein, J; [2]  Jansen, K; [2]  Jaster, A; [2]  Montvay, I [2] 
  1. Lorand Eoetvoes Univ., Budapest (Hungary). Inst. for Theoretical Physics
  2. Deutsches Elektronen-Synchrotron (DESY), Hamburg (Germany)
Publication Date:
Apr 01, 1995
DOI:
https://doi.org/10.1016/0920-5632(95)00314-Y
Product Type:
Journal Article
Report Number:
CONF-9409269-
Reference Number:
SCA: 662210; PA: AIX-26:064505; EDB-95:132578; SN: 95001458497
Resource Relation:
Journal Name: Nuclear Physics B, Proceedings Supplements; Journal Volume: 42; Conference: Lattice `94, Bielefeld (Germany), 25 Sep - 1 Oct 1994; Other Information: PBD: Apr 1995
Subject:
66 PHYSICS; HIGGS BOSONS; REST MASS; WEINBERG LEPTON MODEL; PHASE TRANSFORMATIONS; ACTION INTEGRAL; COMPUTERIZED SIMULATION; ELECTROMAGNETIC INTERACTIONS; ENERGY GAP; HIGGS MODEL; INTERFACES; LATTICE FIELD THEORY; MONTE CARLO METHOD; ORDER PARAMETERS; RENORMALIZATION; SU-2 GROUPS; SURFACE TENSION; TEMPERATURE DEPENDENCE; TRANSITION HEAT; TRANSITION TEMPERATURE; U-1 GROUPS; WEAK INTERACTIONS
OSTI ID:
101216
Country of Origin:
Netherlands
Language:
English
Other Identifying Numbers:
Journal ID: NPBSE7; ISSN 0920-5632; TRN: NL95FF466064505
Submitting Site:
NLN
Size:
pp. 569-574
Announcement Date:
Oct 05, 1995

Journal Article:

SAVE / SHARE

XML RIS EndNote CSV/Excel JSON

Citation Formats

Csikor, F, Fodor, Z, Hein, J, Jansen, K, Jaster, A, and Montvay, I. The electroweak phase transition: a non-perturbative lattice investigation. Netherlands: N. p., 1995. Web. doi:10.1016/0920-5632(95)00314-Y.
Csikor, F, Fodor, Z, Hein, J, Jansen, K, Jaster, A, & Montvay, I. The electroweak phase transition: a non-perturbative lattice investigation. Netherlands. https://doi.org/10.1016/0920-5632(95)00314-Y
Csikor, F, Fodor, Z, Hein, J, Jansen, K, Jaster, A, and Montvay, I. 1995. "The electroweak phase transition: a non-perturbative lattice investigation." Netherlands. https://doi.org/10.1016/0920-5632(95)00314-Y.
@misc{etde_101216,
title = {The electroweak phase transition: a non-perturbative lattice investigation}
 author = {Csikor, F, Fodor, Z, Hein, J, Jansen, K, Jaster, A, and Montvay, I}
 abstractNote = {We present results obtained from a numerical investigation of the electroweak phase transition in the SU(2)-Higgs model. The simulations are performed at two values of the Higgs boson mass, M{sub H}{approx}20GeV and M{sub H}{approx}50GeV. While the phase transition is of strongly first order at the smaller value of the Higgs mass it weakens rapidly when the Higgs mass is increased. This is in qualitative agreement with perturbation theory as the comparison of various physical quantities shows. ((orig.)).}
 doi = {10.1016/0920-5632(95)00314-Y}
 journal = []
 volume = {42}
 journal type = {AC}
 place = {Netherlands}
 year = {1995}
 month = {Apr}
 }