English

How Long Could We Live?

High Energy Physics - Phenomenology 2008-11-26 v4 High Energy Physics - Experiment High Energy Physics - Theory

Abstract

We investigate model independent upper bounds on total proton lifetime in the context of Grand Unified Theories with the Standard Model matter content. We find them to be τp1.50.3+0.5×1039 (MX/1016GeV)4αGUT2(0.003GeV3/α)2years\tau_p \leq 1.5^{+0.5}_{-0.3} \times 10^{39} \ \frac{(M_X/10^{16} \textrm{GeV})^4}{\alpha_{GUT}^2} (0.003 \textrm{GeV}^3 / \alpha)^2 \textrm{years} and τp7.10.0+0.0×1036 (MX/1016GeV)4αGUT2(0.003GeV3/α)2years\tau_p \leq 7.1^{+0.0}_{-0.0} \times 10^{36} \ \frac{(M_X/10^{16} \textrm{GeV})^4}{\alpha_{GUT}^2} (0.003 \textrm{GeV}^3 / \alpha)^2 \textrm{years} in the Majorana and Dirac neutrino case, respectively. These bounds, in conjunction with experimental limits, put lower limit on the mass MXM_X of gauge bosons responsible for the proton and bound-neutron decay processes. For central values of relevant input parameters we obtain MX4.3×1014αGUTGeVM_X \geq 4.3 \times 10^{14} \sqrt{\alpha_{GUT}} \textrm{GeV}. Our result implies that a large class of non-supersymmetric Grand Unified models, with typical values αGUT1/39\alpha_{GUT} \sim 1/39, still satisfies experimental constraints on proton lifetime. Our result is independent on any CP violating phase and the only significant source of uncertainty is associated with imprecise knowledge of α\alpha--the nucleon decay matrix element.

Keywords

Cite

@article{arxiv.hep-ph/0410198,
  title  = {How Long Could We Live?},
  author = {Ilja Dorsner and Pavel Fileviez Perez},
  journal= {arXiv preprint arXiv:hep-ph/0410198},
  year   = {2008}
}

Comments

13 pages, 2 figures. Few corrections, new references