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Fine Tuning, Sequestering, and the Swampland

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arxiv 1905.06342 v3 pith:GF3CZ27W submitted 2019-05-15 hep-th hep-ph

Fine Tuning, Sequestering, and the Swampland

classification hep-th hep-ph
keywords finecoupledgravitycftsconjectureeffectivefieldfinite
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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We conjecture and present evidence that any effective field theory coupled to gravity in flat space admits at most a finite number of fine tunings, depending on the amount of supersymmetry and spacetime dimension. In particular, this means that there are infinitely many non-trivial correlations between the allowed deformations of a given effective field theory in the gravitational context. Fine tuning of parameters allows us to obtain some consistent CFTs in the IR limit of gravitational theories. Related to finiteness of fine tunings, we conjecture that except for a finite number of CFTs, the rest cannot be consistently coupled to gravity and belong to the swampland. Moreover, we argue that even though matter sectors coupled to gravity may sometimes be partially sequestered, there is an irreducible level of mixing between them, correlating and coupling infinitely many operators between these sectors.

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