Miami Miami 2012 Tirtho Biswas Stringy Nonlocal Theories

My Collaborators N. Barnaby (University of Minnesota) N. Barnaby (University of Minnesota) R. Brandenberger (McGill) R. Brandenberger (McGill) J. Cembranos (Madrid) J. Cembranos (Madrid) J. Cline (McGill) J. Cline (McGill) M. Grisaru (McGill) M. Grisaru (McGill) J. Kapusta (U of M) J. Kapusta (U of M) T. Koivisto (Utrecht) T. Koivisto (Utrecht) A. Kosheylev (Brussels) A. Kosheylev (Brussels) A. Mazumdar (Lancaster) A. Mazumdar (Lancaster) A. Reddy (U of M) A. Reddy (U of M) W. Siegel (Stony Brook) W. Siegel (Stony Brook) S. Vernov (Moscow) S. Vernov (Moscow) TB, J. Cembranos and J. Kapusta, PRL 104, (2010) [arXiv: [hep-th]] TB, E. Gerwick, T. Koivisto and A. Mazumdar, PRL 108, (2012) [arXiv: [gr-qc]]

Outline Nonlocal Scalar Field Theory  Stringy Motivations  Ghostfree higher derivative theories  Finite Loops & some results Nonlocal Gravity  The problem of Ghosts  Nonsingular Black Holes?  Nonsingular Cosmology?

String Field Theory Tachyons [Witten, Kostelecky & Samuel, Sen] Mass square has the wrong sign p-adic string theory [Volovich, Brekke, Freund, Olson, Witten, Frampton]   An inifinte series of higher derivative kinetic operators, mildly nonlocal Open string coupling string tension Nonlocal Actions in String Theory

Interesting Properties Ghostfree  But SFT/padic type theories have no extra states! Quantum loops are finite   UV under better control, like usual HD theories   Linear Regge Trajectories [TB, Grisaru & Siegel]   Thermal duality [TB, Cembranos & Kapusta, 2010 PRL]   Can there be any phenomenological implications for LHC? [Moffat et al]

Applications Insights into string theory  Brane Physics & Tachyon condensation [Zwiebach & Moeller; Forini, Gambini & Nardelli; Colleti, Sigalov & Taylor; Calcagni…]  Hagedorn physics [Blum; TB, Cembranos & Kapusta]  Spectrum [TB, Grisaru & Siegel, Minahan] Applications to Cosmology  Novel kinetic energy dominated non-slow-roll inflationary mechanisms  Novel kinetic energy dominated non-slow-roll inflationary mechanisms [TB, Barnaby & Cline; Lidsey…]  Large nongaussianities  Large nongaussianities [Barnaby & Cline]  Dark Energy [Arefeva, Joukovskaya, Dragovich,...] Applications to Particle Physics [Moffat et.al.]

Nonlocal Gravity  Can Nonlocal higher derivative terms be free from ghosts?  Can they address the singularity problems in GR ?  What about quantum loops? Stelle demonstrated 4 th order gravity to be renormalizable (1977), but it has ghosts Stelle demonstrated 4 th order gravity to be renormalizable (1977), but it has ghosts

Ghosts From Scalars to Gravity  The metric has 6 degrees (graviton, vector, and two scalars)  Gauge symmetry is subtle, some ghosts are allowed  Several Classical (time dependent) backgrounds.

Linearized Gravity Free from ghosts in Minkowski vacuum  Only interested in quadratic action  Only interested in quadratic action [with Mazumdar, Koivisto, Gerwick, 2012 PRL]  Only 6 linearly independent combinations using BI  Covariant derivatives must be Minkowski, most general form

 Covariant to Minkowski  We noticed rather curious relations They in fact follow from Bianchi identity! They in fact follow from Bianchi identity!  By inverting Field equations we obtain the propagators  Decouple the different multiplets using projection operators: [van Nieuwenhuizen]  Precisely because of the above relations, the dangerous w-scalar ghost and the Vector ghost vanishes  Precisely because of the above relations, the dangerous w-scalar ghost and the Vector ghost vanishes

 General Covariance dictates the propagator is of the form  At low energies, p  0, we automatically recover GR  In GR a = c = 1, scalar ghost cancels the longitudinal mode  a has to be an entire function, otherwise Weyl ghosts  a-3c can have a single zero -> f(R)/Brans-Dicke theory  Exponential non-local Gravity,

Newtonian Potentials  Large r, reproduces gravity; small r, asymptotic freedom  No small mass black holes, no horizon and no singularity! Gravity Waves   Similar arguments imply nonsingular Green’s functions for quadrupole moments

Exact Solutions Bouncing Solutions  deSitter completions, a(t) ~ cosh(Mt)  Stable attractors, but there are singular attractors.  Can provide a geodesically complete models of inflation.  Perturbations can be studied numerically and analytically, reproduces GR at late times… can provide geodesic completion to inflation

Conclusions   Nonlocal gravity is a promising direction in QG   It can probably solve the classical singularities   How to constrain higher curvatures?   New symmetries   Look at ghost constraints on (A)dS – relevant for DE   Can we implement Stelle’s methods?

Emergent Cosmology  Space-time begins with pure vacuum  You cannot find a consistent solution for GR  There must be a scalar degree of freedom

t’ Hooft dual to string theory t’ Hooft dual to string theory Polyakov action: Polyakov action: Strings on Random lattice [Douglas,Shenker] Strings on Random lattice [Douglas,Shenker] Dual Field theory action Dual Field theory action

Motivation   Standard Models of Particle Physics & Cosmology have been remarkably successful   Too successful, no experimental puzzles   Hints at new meV physics (Dark energy & Neutrinos)   Fall back on theoretical prejudices Hierarchy problem, Unification - GUT, SUSY, String Theory Nonsingularity – can we use this to guide us?