中文

Electroweak Symmetry Breaking and Large Extra Dimensions

高能物理 - 唯象学 2009-10-31 v1

摘要

If spacetime contains large compact extra dimensions, the fundamental mass scale of nature, LambdaLambda, may be close to the weak scale, allowing gravitational physics to significantly modify electroweak symmetry breaking. Operators of the form (1/Lambda2)phiDphi2(1/Lambda^2) |phi^* D phi|^2 and (1/Lambda2)phiWBphi(1/Lambda^2) phi^* W B phi, where WW and BB are the SU(2) and U(1) field strengths and phiphi is the Higgs field, remove the precision electroweak bound on the Higgs boson mass for values of LambdaLambda in a wide range: 4TeV<Lambda<11TeV4 TeV < Lambda < 11 TeV. Within this framework, there is no preference between a light Higgs boson, a heavy Higgs boson, or a non-linearly realized SU(2)xU(1) symmetry beneath LambdaLambda. If there is a Higgs doublet, then operators of the form (1/Lambda2)phiphi(G2,F2)(1/Lambda^2) phi^* phi (G^2, F^2), where GG and FF are the QCD and electromagnetic field strengths, modify the production of the Higgs boson by gluon-gluon fusion, and the decay of the Higgs boson to 2 photons, respectively. At Run II of the Tevatron collider, a 2-photon signal for extra dimensions will be discovered if LambdaLambda is below 2.5 (1) TeV for a Higgs boson of mass 100 (300) GeV. Furthermore, such a signal would point to gravitational physics, rather than to new conventional gauge theories at LambdaLambda. The discovery potential of the LHC depends sensitively on whether the gravitational amplitudes interfere constructively or destructively with the standard model amplitudes, and ranges from LambdaLambda = 3 - 10 (2 - 4) TeV for a light (heavy) Higgs boson.

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引用

@article{arxiv.hep-ph/9904236,
  title  = {Electroweak Symmetry Breaking and Large Extra Dimensions},
  author = {Lawrence Hall and Christopher Kolda},
  journal= {arXiv preprint arXiv:hep-ph/9904236},
  year   = {2009}
}

备注

14 pages LaTeX, 3 figures