Abstract
Besides the string scale, string theory has no parameter except some quantized flux values; and the string theory Landscape is generated by scanning over discrete values of all the flux parameters present. We propose that a typical (normalized) probability distribution $P({\cal Q})$ of a physical quantity $\cal Q$ (with nonnegative dimension) tends to peak (diverge) at ${\cal Q}=0$ as a signature of string theory. In the Racetrack K\"ahler uplift model, where $P(\Lambda)$ of the cosmological constant $\Lambda$ peaks sharply at $\Lambda=0$, the electroweak scale (not the electroweak model) naturally emerges when the median $\Lambda$ is matched to the observed value. We check the robustness of this scenario. In a bottom-up approach, we find that the observed quark and charged lepton masses are consistent with the same probabilistic philosophy, with distribution $P(m)$ that diverges at $m=0$, with the same (or almost the same) degree of divergence. This suggests that the Standard Model has an underlying string theory description, and yields relations among the fermion masses, albeit in a probabilistic approach (very different from the usual sense). Along this line of reasoning, the normal hierarchy of neutrino masses is clearly preferred over the inverted hierarchy, and the sum of the neutrino masses is predicted to be $\sum m_{\nu} \simeq 0.0592$ eV, with an upper bound $\sum m_{\nu} <0.066$ eV. This illustrates a novel way string theory can be applied to particle physics phenomenology.
Highlights
In science, a simple criterion on the success of a model/ idea is the number of parameters needed to explain/predict the observable phenomena
We show that the distribution of fermion masses reveals a distribution PðmÞ that peaks at m 1⁄4 0, which we interpret as evidence that the Standard Model (SM) has an underlying string theory description
II, we state the string theory constraints that lead to our proposal that the probability distributions of some physical quantities with positive dimensions should tend to peak at zero value. (More discussions on this proposal can be found in the last section.) As examples, we review and extend some basic observations given in [3] regarding the peaking behavior of PðΛÞ for some toy models
Summary
A simple criterion on the success of a model/ idea is the number of parameters needed to explain/predict the observable phenomena. We show that the distribution of fermion masses reveals a distribution PðmÞ that peaks (diverges) at m 1⁄4 0, which we interpret as evidence that the SM has an underlying string theory description Applying this observation to the neutrinos allows us to see that the normal hierarchy is strongly preferred over the inverted hierarchy and obtain a prediction on the sum of neutrino masses, m1 ≃ 10−8 eV;. We like to believe that this is an improvement, since nine fermion masses appear natural using three parameters for the two probability distributions We consider this peaked probability distribution as evidence that the SM has an underlying string theory description.
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