Black Holes and Large N Species Solution to the Hierarchy Problem
Gia Dvali
TL;DR
This paper argues that theories with many quantum species imply a lower bound on the Planck scale, providing a new perspective on the hierarchy problem through black hole physics and large N species effects.
Contribution
It introduces a novel argument linking large N species to the hierarchy problem and derives bounds on the Planck scale using black hole physics, including implications for quantum charges and symmetries.
Findings
Large N species set a lower bound on the Planck mass proportional to N and the species mass squared.
Quantum charges not associated with long-range fields are bounded by N, affecting global and gauge symmetries.
The N-species sector addressing the hierarchy problem can be tested at the LHC.
Abstract
We provide the perturbative and non-perturbative arguments showing that theories with large number of species of the quantum fields, imply an inevitable hierarchy between the masses of the species and the Planck scale, shedding a different light on the hierarchy problem. In particular, using the black hole physics, we prove that any consistent theory that includes N number of the Z_2-conserved species of the quantum fields of mass \Lambda, puts a lower bound on the Planck mass, which in large N limit is given by N\Lambda^2. An useful byproduct of this proof is that any exactly conserved quantum charge, not associated with a long-range classical field, must be defined maximum modulo N, bounded by the the ratio of the Planck to the unit charge masses squared. For example, a continuous global U(1) `baryon number' symmetry, must be explicitly broken by gravity, at least down to a Z_N…
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