Abstract

In theories in which different regions of the universe can have different values of certain physical parameters, we would naturally find ourselves in a region where they take values favorable for life. We explore the range of such viable values of the mass parameter in the Higgs potential, ${\ensuremath{\mu}}^{2}$. For ${\ensuremath{\mu}}^{2}<0$, the requirement that complex elements be formed suggests that the Higgs vacuum expectation value $v$ must have a magnitude less than 5 times its observed value. For ${\ensuremath{\mu}}^{2}>0$, baryon stability requires that $|\ensuremath{\mu}|\ensuremath{\ll}{M}_{P}$, the Planck mass. Smaller values of $|{\ensuremath{\mu}}^{2}|$ may or may not be allowed depending on issues of element synthesis and stellar evolution. We conclude that the observed value of ${\ensuremath{\mu}}^{2}$ appears reasonably typical of the viable range, and a multiple-domain scenario may provide a plausible explanation for the closeness of the QCD scale and the weak scale.