Introduction to Teleparallel and fT Gravity and Cosmology

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Introduction to Teleparallel and f(T) Gravity and Cosmology Emmanuel N. Saridakis Physics Department, National

Introduction to Teleparallel and f(T) Gravity and Cosmology Emmanuel N. Saridakis Physics Department, National and Technical University of Athens, Greece Physics Department, Baylor University, Texas, USA E. N. Saridakis – IAP, Sept 2014

Goal We investigate cosmological scenarios in a universe governed by torsional modified gravity Note:

Goal We investigate cosmological scenarios in a universe governed by torsional modified gravity Note: A consistent or interesting cosmology is not a proof for the consistency of the underlying gravitational theory 2 E. N. Saridakis – IAP, Sept 2014

Talk Plan 1) Introduction: Gravity as a gauge theory, modified Gravity 2) Teleparallel Equivalent

Talk Plan 1) Introduction: Gravity as a gauge theory, modified Gravity 2) Teleparallel Equivalent of General Relativity and f(T) modification 3) Perturbations and growth evolution 4) Bounce in f(T) cosmology 5) Non-minimal scalar-torsion theory 6) Teleparallel Equivalent of Gauss-Bonnet and f(T, T_G) modification 7) Black-hole solutions 8) Solar system and growth-index constraints 9) Conclusions-Prospects 3 E. N. Saridakis – IAP, Sept 2014

Introduction Einstein 1916: General Relativity: energy-momentum source of spacetime Curvature Levi-Civita connection: Zero Torsion

Introduction Einstein 1916: General Relativity: energy-momentum source of spacetime Curvature Levi-Civita connection: Zero Torsion Einstein 1928: Teleparallel Equivalent of GR: Weitzenbock connection: Zero Curvature Einstein-Cartan theory: energy-momentum source of Curvature, spin source of Torsion [Hehl, Von Der Heyde, Kerlick, Nester Rev. Mod. Phys. 48] 4 E. N. Saridakis – IAP, Sept 2014

Introduction Gauge Principle: global symmetries replaced by local ones: The group generators give rise

Introduction Gauge Principle: global symmetries replaced by local ones: The group generators give rise to the compensating fields It works perfect for the standard model of strong, weak and E/M interactions Can we apply this to gravity? 5 E. N. Saridakis – IAP, Sept 2014

Introduction Formulating the gauge theory of gravity (mainly after 1960): Start from Special Relativity

Introduction Formulating the gauge theory of gravity (mainly after 1960): Start from Special Relativity Apply (Weyl-Yang-Mills) gauge principle to its Poincarégroup symmetries Get Poinaré gauge theory: Both curvature and torsion appear as field strengths Torsion is the field strength of the translational group (Teleparallel and Einstein-Cartan theories are subcases of Poincaré theory) [Blagojevic, Hehl, Imperial College Press, 2013] 6 E. N. Saridakis – IAP, Sept 2014

Introduction One could extend the gravity gauge group (SUSY, conformal, scale, metric affine transformations)

Introduction One could extend the gravity gauge group (SUSY, conformal, scale, metric affine transformations) obtaining SUGRA, conformal, Weyl, metric affine gauge theories of gravity In all of them torsion is always related to the gauge structure. Thus, a possible way towards gravity quantization would need to bring torsion into gravity description. 7 E. N. Saridakis – IAP, Sept 2014

Introduction 1998: Universe acceleration Thousands of work in Modified Gravity (f(R), Gauss-Bonnet, Lovelock, nonminimal

Introduction 1998: Universe acceleration Thousands of work in Modified Gravity (f(R), Gauss-Bonnet, Lovelock, nonminimal scalar coupling, nonminimal derivative coupling, Galileons, Hordenski, massive etc) [Copeland, Sami, Tsujikawa Int. J. Mod. Phys. D 15], [Nojiri, Odintsov Int. J. Geom. Meth. Mod. Phys. 4] Almost all in the curvature-based formulation of gravity 8 E. N. Saridakis – IAP, Sept 2014

Introduction 1998: Universe acceleration Thousands of work in Modified Gravity (f(R), Gauss-Bonnet, Lovelock, nonminimal

Introduction 1998: Universe acceleration Thousands of work in Modified Gravity (f(R), Gauss-Bonnet, Lovelock, nonminimal scalar coupling, nonminimal derivative coupling, Galileons, Hordenski, massive etc) [Copeland, Sami, Tsujikawa Int. J. Mod. Phys. D 15], [Nojiri, Odintsov Int. J. Geom. Meth. Mod. Phys. 4] Almost all in the curvature-based formulation of gravity So question: Can we modify gravity starting from its torsion-based formulation? torsion gauge quantization modification full theory quantization 9 E. N. Saridakis – IAP, Sept 2014

Teleparallel Equivalent of General Relativity (TEGR) Let’s start from the simplest tosion-based gravity formulation,

Teleparallel Equivalent of General Relativity (TEGR) Let’s start from the simplest tosion-based gravity formulation, namely TEGR: Vierbeins : four linearly independent fields in the tangent space Use curvature-less Weitzenböck connection instead of torsion-less Levi-Civita one: Torsion tensor: [Einstein 1928], [Pereira: Introduction to TG] 10 E. N. Saridakis – IAP, Sept 2014

Teleparallel Equivalent of General Relativity (TEGR) Let’s start from the simplest tosion-based gravity formulation,

Teleparallel Equivalent of General Relativity (TEGR) Let’s start from the simplest tosion-based gravity formulation, namely TEGR: Vierbeins : four linearly independent fields in the tangent space Use curvature-less Weitzenböck connection instead of torsion-less Levi-Civita one: Torsion tensor: Lagrangian (imposing coordinate, Lorentz, parity invariance, and up to 2 nd order in torsion tensor) Completely equivalent with GR at the level of equations [Einstein 1928], [Hayaski, Shirafuji PRD 19], [Pereira: Introduction to TG] 11 E. N. Saridakis – IAP, Sept 2014

f(T) Gravity and f(T) Cosmology f(T) Gravity: Simplest torsion-based modified gravity Generalize T to

f(T) Gravity and f(T) Cosmology f(T) Gravity: Simplest torsion-based modified gravity Generalize T to f(T) (inspired by f(R)) [Ferraro, Fiorini PRD 78], [Bengochea, Ferraro PRD 79] Equations of motion: [Linder PRD 82] 12 E. N. Saridakis – IAP, Sept 2014

f(T) Gravity and f(T) Cosmology f(T) Gravity: Simplest torsion-based modified gravity Generalize T to

f(T) Gravity and f(T) Cosmology f(T) Gravity: Simplest torsion-based modified gravity Generalize T to f(T) (inspired by f(R)) [Ferraro, Fiorini PRD 78], [Bengochea, Ferraro PRD 79] [Linder PRD 82] Equations of motion: f(T) Cosmology: Apply in FRW geometry: (not unique choice) Friedmann equations: Find easily 13 E. N. Saridakis – IAP, Sept 2014

f(T) Cosmology: Background Effective Dark Energy sector: [Linder PRD 82] Interesting cosmological behavior: Acceleration,

f(T) Cosmology: Background Effective Dark Energy sector: [Linder PRD 82] Interesting cosmological behavior: Acceleration, Inflation etc At the background level indistinguishable from other dynamical DE models 14 E. N. Saridakis – IAP, Sept 2014

f(T) Cosmology: Perturbations Can I find imprints of f(T) gravity? Yes, but need to

f(T) Cosmology: Perturbations Can I find imprints of f(T) gravity? Yes, but need to go to perturbation level Obtain Perturbation Equations: [Chen, Dent, Dutta, Saridakis PRD 83], [Dent, Dutta, Saridakis JCAP 1101] Focus on growth of matter overdensity go to Fourier modes: [Chen, Dent, Dutta, Saridakis PRD 83] 15 E. N. Saridakis – IAP, Sept 2014

f(T) Cosmology: Perturbations Application: Distinguish f(T) from quintessence 1) Reconstruct f(T) to coincide with

f(T) Cosmology: Perturbations Application: Distinguish f(T) from quintessence 1) Reconstruct f(T) to coincide with a given quintessence scenario: with and [Dent, Dutta, Saridakis JCAP 1101] 16 E. N. Saridakis – IAP, Sept 2014

f(T) Cosmology: Perturbations Application: Distinguish f(T) from quintessence 2) Examine evolution of matter overdensity

f(T) Cosmology: Perturbations Application: Distinguish f(T) from quintessence 2) Examine evolution of matter overdensity [Dent, Dutta, Saridakis JCAP 1101] 17 E. N. Saridakis – IAP, Sept 2014

Bounce and Cyclic behavior Contracting ( ), bounce ( ), expanding ( near and

Bounce and Cyclic behavior Contracting ( ), bounce ( ), expanding ( near and at the bounce ) Expanding ( ), turnaround ( ), contracting near and at the turnaround 18 E. N. Saridakis – IAP, Sept 2014

Bounce and Cyclic behavior in f(T) cosmology Contracting ( ), bounce ( ), expanding

Bounce and Cyclic behavior in f(T) cosmology Contracting ( ), bounce ( ), expanding ( near and at the bounce ) Expanding ( ), turnaround ( ), contracting near and at the turnaround Bounce and cyclicity can be easily obtained [Cai, Chen, Dent, Dutta, Saridakis CQG 28] 19 E. N. Saridakis – IAP, Sept 2014

Bounce in f(T) cosmology Start with a bounching scale factor: 20 E. N. Saridakis

Bounce in f(T) cosmology Start with a bounching scale factor: 20 E. N. Saridakis – IAP, Sept 2014

Bounce in f(T) cosmology Start with a bounching scale factor: Examine the full perturbations:

Bounce in f(T) cosmology Start with a bounching scale factor: Examine the full perturbations: with known in terms of and matter Primordial power spectrum: Tensor-to-scalar ratio: [Cai, Chen, Dent, Dutta, Saridakis CQG 28] 21 E. N. Saridakis – IAP, Sept 2014

Non-minimally coupled scalar-torsion theory In curvature-based gravity, apart from Let’s do the same in

Non-minimally coupled scalar-torsion theory In curvature-based gravity, apart from Let’s do the same in torsion-based gravity: one can use [Geng, Lee, Saridakis, Wu PLB 704] 22 E. N. Saridakis – IAP, Sept 2014

Non-minimally coupled scalar-torsion theory In curvature-based gravity, apart from Let’s do the same in

Non-minimally coupled scalar-torsion theory In curvature-based gravity, apart from Let’s do the same in torsion-based gravity: one can use [Geng, Lee, Saridakis, Wu PLB 704] Friedmann equations in FRW universe: with effective Dark Energy sector: Different than non-minimal quintessence! (no conformal transformation in the present case) [Geng, Lee, Saridakis, Wu PLB 704] 23 E. N. Saridakis – IAP, Sept 2014

Non-minimally coupled scalar-torsion theory Main advantage: Dark Energy may lie in the phantom regime

Non-minimally coupled scalar-torsion theory Main advantage: Dark Energy may lie in the phantom regime or/and experience the phantom-divide crossing Teleparallel Dark Energy: [Geng, Lee, Saridakis, Wu PLB 704] 24 E. N. Saridakis – IAP, Sept 2014

Observational constraints on Teleparallel Dark Energy Use observational data (SNIa, BAO, CMB) to constrain

Observational constraints on Teleparallel Dark Energy Use observational data (SNIa, BAO, CMB) to constrain the parameters of theory Include matter and standard radiation: We fit for various 25 E. N. Saridakis – IAP, Sept 2014

Observational constraints on Teleparallel Dark Energy Exponential potential Quartic potential [Geng, Lee, Saridkis JCAP

Observational constraints on Teleparallel Dark Energy Exponential potential Quartic potential [Geng, Lee, Saridkis JCAP 1201] 26 E. N. Saridakis – IAP, Sept 2014

Phase-space analysis of Teleparallel Dark Energy Transform cosmological system to its autonomous form: [Xu,

Phase-space analysis of Teleparallel Dark Energy Transform cosmological system to its autonomous form: [Xu, Saridakis, Leon, JCAP 1207] Linear Perturbations: Eigenvalues of determine type and stability of C. P 27 E. N. Saridakis – IAP, Sept 2014

Phase-space analysis of Teleparallel Dark Energy Apart from usual quintessence points, there exists an

Phase-space analysis of Teleparallel Dark Energy Apart from usual quintessence points, there exists an extra stable one for corresponding to At the critical points however during the evolution it can lie in quintessence or phantom regimes, or experience the phantomdivide crossing! [Xu, Saridakis, Leon, JCAP 1207] 28 E. N. Saridakis – IAP, Sept 2014

Non-minimally matter-torsion coupled theory In curvature-based gravity, one can use Let’s do the same

Non-minimally matter-torsion coupled theory In curvature-based gravity, one can use Let’s do the same in torsion-based gravity: coupling [Harko, Lobo, Otalora, Saridakis, PRD 89] 29 E. N. Saridakis – IAP, Sept 2014

Non-minimally matter-torsion coupled theory In curvature-based gravity, one can use Let’s do the same

Non-minimally matter-torsion coupled theory In curvature-based gravity, one can use Let’s do the same in torsion-based gravity: Friedmann equations in FRW universe: coupling with effective Dark Energy sector: Different than non-minimal matter-curvature coupled theory [Harko, Lobo, Otalora, Saridakis, PRD 89] 30 E. N. Saridakis – IAP, Sept 2014

Non-minimally matter-torsion coupled theory Interesting phenomenology [Harko, Lobo, Otalora, Saridakis, PRD 89] 31 E.

Non-minimally matter-torsion coupled theory Interesting phenomenology [Harko, Lobo, Otalora, Saridakis, PRD 89] 31 E. N. Saridakis – IAP, Sept 2014

Non-minimally matter-torsion coupled theory In curvature-based gravity, one can use Let’s do the same

Non-minimally matter-torsion coupled theory In curvature-based gravity, one can use Let’s do the same in torsion-based gravity: coupling [Harko, Lobo, Otalora, Saridakis, 1405. 0519, to appear in JCAP] 32 E. N. Saridakis – IAP, Sept 2014

Non-minimally matter-torsion coupled theory In curvature-based gravity, one can use Let’s do the same

Non-minimally matter-torsion coupled theory In curvature-based gravity, one can use Let’s do the same in torsion-based gravity: Friedmann equations in FRW universe ( coupling ): with effective Dark Energy sector: Different from gravity [Harko, Lobo, Otalora, Saridakis, 1405. 0519, to appear in JCAP] 33 E. N. Saridakis – IAP, Sept 2014

Non-minimally matter-torsion coupled theory Interesting phenomenology [Harko, Lobo, Otalora, Saridakis, 1405. 0519, to appear

Non-minimally matter-torsion coupled theory Interesting phenomenology [Harko, Lobo, Otalora, Saridakis, 1405. 0519, to appear in JCAP] 34 E. N. Saridakis – IAP, Sept 2014

Teleparallel Equivalent of Gauss-Bonnet and f(T, T_G) gravity In curvature-based gravity, one can use

Teleparallel Equivalent of Gauss-Bonnet and f(T, T_G) gravity In curvature-based gravity, one can use higher-order invariants like the Gauss-Bonnet one Let’s do the same in torsion-based gravity: Similar to we construct with 35 E. N. Saridakis – IAP, Sept 2014

Teleparallel Equivalent of Gauss-Bonnet and f(T, T_G) gravity In curvature-based gravity, one can use

Teleparallel Equivalent of Gauss-Bonnet and f(T, T_G) gravity In curvature-based gravity, one can use higher-order invariants like the Gauss-Bonnet one Let’s do the same in torsion-based gravity: Similar to we construct with gravity: [Kofinas, Saridakis, 1404. 2249 to appear in PRD] [Kofinas, Saridakis, 1408. 0107 to appear in PRD] [Kofinas, Leon, Saridakis, CQG 31] Different from and gravities 36 E. N. Saridakis – IAP, Sept 2014

Teleparallel Equivalent of Gauss-Bonnet and f(T, T_G) gravity Cosmological application: [Kofinas, Saridakis, 1404. 2249

Teleparallel Equivalent of Gauss-Bonnet and f(T, T_G) gravity Cosmological application: [Kofinas, Saridakis, 1404. 2249 to appear in PRD] [Kofinas, Saridakis, 1408. 0107 to appear in PRD] [Kofinas, Leon, Saridakis, CQG 31] 37 E. N. Saridakis – IAP, Sept 2014

Exact charged black hole solutions Extend f(T) gravity in D-dimensions (focus on D=3, D=4):

Exact charged black hole solutions Extend f(T) gravity in D-dimensions (focus on D=3, D=4): Add E/M sector: Extract field equations: with [Gonzalez, Saridakis, Vasquez, JHEP 1207] [Capozzielo, Gonzalez, Saridakis, Vasquez, JHEP 1302] 38 E. N. Saridakis – IAP, Sept 2014

Exact charged black hole solutions Extend f(T) gravity in D-dimensions (focus on D=3, D=4):

Exact charged black hole solutions Extend f(T) gravity in D-dimensions (focus on D=3, D=4): Add E/M sector: Extract field equations: Look for spherically symmetric solutions: Radial Electric field: with known [Gonzalez, Saridakis, Vasquez, JHEP 1207], [Capozzielo, Gonzalez, Saridakis, Vasquez, JHEP 1302] 39 E. N. Saridakis – IAP, Sept 2014

Exact charged black hole solutions Horizon and singularity analysis: 1) Vierbeins, Weitzenböck connection, Torsion

Exact charged black hole solutions Horizon and singularity analysis: 1) Vierbeins, Weitzenböck connection, Torsion invariants: T(r) known obtain horizons and singularities 2) Metric, Levi-Civita connection, Curvature invariants: R(r) and Kretschmann known obtain horizons and singularities [Gonzalez, Saridakis, Vasquez, JHEP 1207], [Capozzielo, Gonzalez, Saridakis, Vasquez, JHEP 1302] 40 E. N. Saridakis – IAP, Sept 2014

Exact charged black hole solutions [Capozzielo, Gonzalez, Saridakis, Vasquez, JHEP 1302] 41 E. N.

Exact charged black hole solutions [Capozzielo, Gonzalez, Saridakis, Vasquez, JHEP 1302] 41 E. N. Saridakis – IAP, Sept 2014

Exact charged black hole solutions More singularities in the curvature analysis than in torsion

Exact charged black hole solutions More singularities in the curvature analysis than in torsion analysis! (some are naked) The differences disappear in the f(T)=0 case, or in the uncharged case. Going to quartic torsion invariants solves the problem. f(T) brings novel features. E/M in torsion formulation was known to be nontrivial (E/M in Einstein. Cartan and Poinaré theories) 42 E. N. Saridakis – IAP, Sept 2014

Solar System constraints on f(T) gravity Apply the black hole solutions in Solar System:

Solar System constraints on f(T) gravity Apply the black hole solutions in Solar System: Assume corrections to TEGR of the form 43 E. N. Saridakis – IAP, Sept 2014

Solar System constraints on f(T) gravity Apply the black hole solutions in Solar System:

Solar System constraints on f(T) gravity Apply the black hole solutions in Solar System: Assume corrections to TEGR of the form Use data from Solar System orbital motions: T<<1 so consistent [Iorio, Saridakis, Mon. Not. Roy. Astron. Soc 427) f(T) divergence from TEGR is very small This was already known from cosmological observation constraints up to [Wu, Yu, PLB 693], [Bengochea PLB 695] With Solar System constraints, much more stringent bound. 44 E. N. Saridakis – IAP, Sept 2014

Growth-index constraints on f(T) gravity Perturbations: , clustering growth rate: γ(z): Growth index. 45

Growth-index constraints on f(T) gravity Perturbations: , clustering growth rate: γ(z): Growth index. 45 E. N. Saridakis – IAP, Sept 2014

Growth-index constraints on f(T) gravity Perturbations: , clustering growth rate: γ(z): Growth index. Viable

Growth-index constraints on f(T) gravity Perturbations: , clustering growth rate: γ(z): Growth index. Viable f(T) models are practically indistinguishable from ΛCDM. [Nesseris, Basilakos, Saridakis, Perivolaropoulos, PRD 88] 46 E. N. Saridakis – IAP, Sept 2014

Open issues of f(T) gravity f(T) cosmology is very interesting. But f(T) gravity and

Open issues of f(T) gravity f(T) cosmology is very interesting. But f(T) gravity and nonminially coupled [Li, Sotiriou, Barrow PRD 83 a], teleparallel gravity has many open issues [Geng, Lee, Saridakis, Wu PLB 704] For nonlinear f(T), Lorentz invariance is not satisfied Equivalently, the vierbein choices corresponding to the same metric are not equivalent (extra degrees of freedom) [Li, Sotiriou, Barrow PRD 83 c], [Li, Miao JHEP 1107] 47 E. N. Saridakis – IAP, Sept 2014

Open issues of f(T) gravity f(T) cosmology is very interesting. But f(T) gravity and

Open issues of f(T) gravity f(T) cosmology is very interesting. But f(T) gravity and nonminially coupled [Li, Sotiriou, Barrow PRD 83 a], teleparallel gravity has many open issues [Geng, Lee, Saridakis, Wu PLB 704] For nonlinear f(T), Lorentz invariance is not satisfied Equivalently, the vierbein choices corresponding to the same metric are not equivalent (extra degrees of freedom) [Li, Miao JHEP 1107] Black holes are found to have different behavior through curvature and torsion analysis [Capozzielo, Gonzalez, Saridakis, Vasquez JHEP 1302] Thermodynamics also raises issues [Bamba, Capozziello, Nojiri, Odintsov ASS 342], [Miao, Li, Miao JCAP 1111] Cosmological, Solar System and Growth Index observations constraint f(T) very close to linear-in-T form [Iorio, Saridakis, Mon. Not. Roy. Astron. Soc 427) [Nesseris, Basilakos, Saridakis, Perivolaropoulos, PRD 88] 48 E. N. Saridakis – IAP, Sept 2014

Gravity modification in terms of torsion? So can we modify gravity starting from its

Gravity modification in terms of torsion? So can we modify gravity starting from its torsion formulation? The simplest, a bit naïve approach, through f(T) gravity is interesting, but has open issues Additionally, f(T) gravity is not in correspondence with f(R) Even if we find a way to modify gravity in terms of torsion, will it be still in 1 -1 correspondence with curvature-based modification? What about higher-order corrections, but using torsion invariants (similar to Lovelock, Hordenski modifications)? Can we modify gauge theories of gravity themselves? E. g. can we modify Poincaré gauge theory? 49 E. N. Saridakis – IAP, Sept 2014

Conclusions i) Torsion appears in all approaches to gauge gravity, i. e to the

Conclusions i) Torsion appears in all approaches to gauge gravity, i. e to the first step of quantization. ii) Can we modify gravity based in its torsion formulation? iii) Simplest choice: f(T) gravity, i. e extension of TEGR iv) f(T) cosmology: Interesting phenomenology. Signatures in growth structure. v) We can obtain bouncing solutions vi) Non-minimal coupled scalar-torsion theory : Quintessence, phantom or crossing behavior. Similarly in torsion-matter coupling and TEGB. vii) Exact black hole solutions. Curvature vs torsion analysis. viii) Solar system constraints: f(T) divergence from T less than ix) Growth Index constraints: Viable f(T) models are practically indistinguishable from ΛCDM. x) Many open issues. Need to search for other torsion-based modifications too. 50 E. N. Saridakis – IAP, Sept 2014

Outlook Many subjects are open. Amongst them: i) Examine thermodynamics thoroughly. ii) Understand the

Outlook Many subjects are open. Amongst them: i) Examine thermodynamics thoroughly. ii) Understand the extra degrees of freedom and the extension to non-diagonal vierbeins. iii) Try to modify TEGR using higher-order torsion invariants. iv) Try to modify Poincaré gauge theory (extremely hard!) v) What to quantize? Metric, vierbeins, or connection? vi) Convince people to work on the subject! 51 E. N. Saridakis – IAP, Sept 2014

THANK YOU! 52 E. N. Saridakis – IAP, Sept 2014

THANK YOU! 52 E. N. Saridakis – IAP, Sept 2014

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