Presentation is loading. Please wait.

Presentation is loading. Please wait.

Gravitational Experiments and Lorentz Violation Jay D. Tasson V. Alan Kostelecký Indiana University TexPoint fonts used in EMF. Read the TexPoint manual.

Published byChristian Greene Modified over 8 years ago

Similar presentations

Presentation on theme: "Gravitational Experiments and Lorentz Violation Jay D. Tasson V. Alan Kostelecký Indiana University TexPoint fonts used in EMF. Read the TexPoint manual."— Presentation transcript:

1 Gravitational Experiments and Lorentz Violation Jay D. Tasson V. Alan Kostelecký Indiana University TexPoint fonts used in EMF. Read the TexPoint manual before you delete this box.: AAAA A AAA A AA A AA A

2 outline introduction –motivation –Standard-Model Extension (SME) recent gravitational tests Lorentz violation in matter-gravity couplings 1,2 –theoretical analysis –new sensitivities in gravitational experiments 1)Kostelecký, Tasson PRL ’09 2)Kostelecký, Tasson in preparation

3 motivation General Relativity and the Standard Model describe known physics. new physics at the Planck scale ( ) options for probing such high energies –galaxy-sized accelerator –suppressed effects in sensitive experiments Lorentz violation can arise in theories of new physics difficult to mimic with conventional effects

4 effective field theory which contains: General Relativity (GR) Standard Model (SM) arbitrary coordinate-independent Lorentz violation as a subset, other test frameworks Lorentz-violating terms constructed from GR and SM fields parameterized by coefficients for Lorentz violation samples Standard-Model Extension (SME) Colladay & Kostelecký PRD ’97, ’98 Kostelecký PRD ’04

5 consider the flat spacetime example under an observer Lorentz transformation (rotation) What is Lorentz violation? physics is unchanged

6 consider the flat spacetime example under a particle Lorentz transformation (rotation) What is Lorentz violation? Lorentz violation!

7 ongoing searches with...

8 Tests based on

9 ongoing searches with... Tests based on Results to date

10 ongoing searches with... Tests based on Results to date Many more tests proposed.

11 ongoing searches with... Tests based on Results to date Many more tests proposed. See Mike Seifert’s talk.

12 Ongoing searches with... spin-polarized solids (Adelberger, Heckel, …) clock comparisons (Gibble, Hunter, Romalis, Walsworth, …) CMB analysis astrophysical photon decay cosmological birefringence pulsar-timing observations particle traps (Dehmelt,Gabrielse, …) resonant cavities (Lipa, Mueller, Peters, Schiller, Wolf, …) neutrino oscillations (LSND, MINOS, Super K, …) muons (Hughes, BNL g-2) meson oscillations (BABAR, BELLE, DELPHI, FOCUS, KTeV, OPAL, …)

13 Ongoing searches with... spin-polarized solids (Adelberger, Heckel, …) clock comparisons (Gibble, Hunter, Romalis, Walsworth, …) CMB analysis astrophysical photon decay cosmological birefringence pulsar-timing observations particle traps (Dehmelt,Gabrielse, …) resonant cavities (Lipa, Mueller, Peters, Schiller, Wolf, …) neutrino oscillations (LSND, MINOS, Super K, …) muons (Hughes, BNL g-2) meson oscillations (BABAR, BELLE, DELPHI, FOCUS, KTeV, OPAL, …)

14 Ongoing searches with... spin-polarized solids (Adelberger, Heckel, …) clock comparisons (Gibble, Hunter, Romalis, Walsworth, …) CMB analysis astrophysical photon decay cosmological birefringence pulsar-timing observations particle traps (Dehmelt,Gabrielse, …) resonant cavities (Lipa, Mueller, Peters, Schiller, Wolf, …) neutrino oscillations (LSND, MINOS, Super K, …) muons (Hughes, BNL g-2) meson oscillations (BABAR, BELLE, DELPHI, FOCUS, KTeV, OPAL, …)

15 Ongoing searches with... spin-polarized solids (Adelberger, Heckel, …) clock-comparisons (Gibble, Hunter, Romalis, Walsworth, …) CMB analysis astrophysical photon decay cosmological birefringence pulsar-timing observations particle traps (Dehmelt,Gabrielse, …) resonant cavities (Lipa, Mueller, Peters, Schiller, Wolf, …) neutrino oscillations (LSND, MINOS, Super K, …) muons (Hughes, BNL g-2) meson oscillations (BABAR, BELLE, DELPHI, FOCUS, KTeV, OPAL, …) only ~1/2 of lowest order couplings explored use gravitational couplings and experiments to get more!

16 covariant derivative for spacetime as well as U(1) coefficients for Lorentz violation particle-species dependent gravitationally coupled fermions 1 additional coefficients for LV, non-minimal torsion, … Idea : new gravitational couplings provide new LV sensitivity explore coefficient unobservable in flat spacetime Kostelecký, Tasson PRL ’09 1) Kostelecký PRD ’04 vierbein

17 covariant derivative for spacetime as well as U(1) coefficients for Lorentz violation particle-species dependent gravitationally coupled fermions 1 additional coefficients for LV, non-minimal torsion, … Idea : new gravitational couplings provide new LV sensitivity explore coefficient unobservable in flat spacetime Kostelecký, Tasson PRL ’09 1) Kostelecký PRD ’04 What is the form of ? Where does it come from? vierbein

18 Lorentz-symmetry breaking explicit –Lorentz violation is a predetermined property of the spacetime –inconsistent with Riemannian geometry spontaneous –LV arises dynamically –consistent with geometry –possible in numerous underlying theories: string theory, quantum gravity … upon investigating spontaneous breaking we find Minkowski-spacetime coefficients characterize couplings in dynamical theories

19 countershaded Lorentz violation for matter is unobservable in flat-spacetime tests observable effects are suppressed by the gravitational field could be large (~ 1eV) relative to existing matter-sector bounds c.f. GeV unobservable shift in fermion phase observable effects via gravity coupling

20 L fermion expand to desired order in LV and gravity L’ fermion H Relativistic H NonRel L Classical relativistic quantum experiments non-relativistic quantum experiments classical experiments field redefinition Euler-Lagrange eq. Foldy-Wouthuysen expansion inspection path to experimental analysis

21 relativistic hamiltonian H rel =

22 gravimeter tests tests of Weak Equivalence –laboratory –space based Lunar laser ranging experimental implications exotic tests –charged matter –antimatter –higher generation matter light-travel tests … S and T denote composite coefficients for source and test respectively

23 gravimeter tests tests of Weak Equivalence –laboratory –space based Lunar laser ranging experimental implications exotic tests –charged matter –antimatter –higher generation matter light-travel experiments … S and T denote composite coefficients for source and test respectively

24 standard frame for reporting SME bounds boost and rotation of test annual & sidereal variations Sun-centered frame

25 lab tests differential acceleration for test-particles A and B monitor acceleration of one particle over time gravimeter monitor relative behavior of particles - EP test frequency and phase distinguish from other effects monitor acceleration of one particle over time gravimeter monitor relative behavior of particles - EP test frequency and phase distinguish from other effects

26 experimental sensitivities one bound 1 based on torsion-pendulum data 2 excellent prospects for remaining 11 coefficients in current and future experiments 1) Kostelecký, Tasson PRL ’09 2) Schlamminger et al. PRL ’08 [] = crude estimate for existing experiment {} = crude estimate for future experiment

27 experimental sensitivities one bound 1 based on torsion-pendulum data 2 excellent prospects for remaining 11 coefficients in current and future experiments 1) Kostelecký, Tasson PRL ’09 2) Schlamminger et al. PRL ’08 3) Kostelecký, Tasson in prep. [] = crude estimate for existing experiment {} = crude estimate for future experiment multiple experiments needed for maximum number of sensitivities other coefficients yield additional effects 1,3 multiple experiments needed for maximum number of sensitivities other coefficients yield additional effects 1,3

28 Lorentz violation introduces qualitatively new signals in gravitational experiments – several experiments performed – much remains unexplored – comparatively large – detectable in current and planned tests – multiple tests needed for maximum independent sensitivities Summary

Download ppt "Gravitational Experiments and Lorentz Violation Jay D. Tasson V. Alan Kostelecký Indiana University TexPoint fonts used in EMF. Read the TexPoint manual."

Similar presentations

Excited State Spectroscopy from Lattice QCD

Excited State Spectroscopy from Lattice QCD
INCLINED DIMENSIONS Daniel Hernández The Abdus Salam International Center for Theoretical Physics D.H, M. Sher; 1101.5695 Phys. Let. B.

INCLINED DIMENSIONS Daniel Hernández The Abdus Salam International Center for Theoretical Physics D.H, M. Sher; Phys. Let. B.
Teppei Katori, Indiana University1 PRD74(2006)105009 Global 3 parameter Lorentz Violation model for neutrino oscillation with MiniBooNE Teppei Katori,

Teppei Katori, Indiana University1 PRD74(2006) Global 3 parameter Lorentz Violation model for neutrino oscillation with MiniBooNE Teppei Katori,
Massive Gravity and the Galileon Claudia de Rham Université de Genève Work with Gregory Gabadadze, Lavinia Heisenberg, David Pirtskhalava and Andrew Tolley.

Massive Gravity and the Galileon Claudia de Rham Université de Genève Work with Gregory Gabadadze, Lavinia Heisenberg, David Pirtskhalava and Andrew Tolley.
String theoretic QCD axions in the light of PLANCK and BICEP2 (QCD axion after BICEP2) Kiwoon KIAS, May 1, 2014 KC, K.S. Jeong and M.S. Seo, arXiv:1404.3880.

String theoretic QCD axions in the light of PLANCK and BICEP2 (QCD axion after BICEP2) Kiwoon KIAS, May 1, 2014 KC, K.S. Jeong and M.S. Seo, arXiv:
Covariant Formulation of the Generalized Lorentz Invariance and Modified Dispersion Relations Alex E. Bernardini Departamento de Física – UFSCAR Financial.

Covariant Formulation of the Generalized Lorentz Invariance and Modified Dispersion Relations Alex E. Bernardini Departamento de Física – UFSCAR Financial.
Test CPT with CMB Mingzhe Li Department of Physics, Nanjing University May 10, 2011 IHEP Beijing.

Test CPT with CMB Mingzhe Li Department of Physics, Nanjing University May 10, 2011 IHEP Beijing.
Fundamental Physics Research in Space International Workshop Washington DC 22-24 May 2006 Probing Relativity using Space-Based Experiments Neil Russell.

Fundamental Physics Research in Space International Workshop Washington DC May 2006 Probing Relativity using Space-Based Experiments Neil Russell.
Lorentz Violation and an Experimental Limit Ben Rybolt 12/10/2012.

Lorentz Violation and an Experimental Limit Ben Rybolt 12/10/2012.
Bruce Kennedy, RAL PPD Particle Physics 2 Bruce Kennedy RAL PPD.

Bruce Kennedy, RAL PPD Particle Physics 2 Bruce Kennedy RAL PPD.
Standard Model Requires Treatment of Particles as Fields Hamiltonian, H=E, is not Lorentz invariant. QM not a relativistic theory. Lagrangian, T-V, used.

Standard Model Requires Treatment of Particles as Fields Hamiltonian, H=E, is not Lorentz invariant. QM not a relativistic theory. Lagrangian, T-V, used.
The Science Case for STEP

The Science Case for STEP
EPPT M2 INTRODUCTION TO RELATIVITY K Young, Physics Department, CUHK  The Chinese University of Hong Kong.

EPPT M2 INTRODUCTION TO RELATIVITY K Young, Physics Department, CUHK  The Chinese University of Hong Kong.
K. Kumar, W. Marciano, Y. Li Electroweak physics at EIC - Summary of week 7 INT Workshop on Pertubative and Non-Pertubative Aspects of QCD at Collider.

K. Kumar, W. Marciano, Y. Li Electroweak physics at EIC - Summary of week 7 INT Workshop on Pertubative and Non-Pertubative Aspects of QCD at Collider.
The Ideas of Unified Theories of Physics Tareq Ahmed Mokhiemer PHYS441 Student.

The Ideas of Unified Theories of Physics Tareq Ahmed Mokhiemer PHYS441 Student.
Gravitational experiments testing Lorentz symmetry Quentin G. Bailey Physics Department Embry-Riddle Aeronautical University Prescott, AZ From Quantum.

Gravitational experiments testing Lorentz symmetry Quentin G. Bailey Physics Department Embry-Riddle Aeronautical University Prescott, AZ From Quantum.
Coupled Dark Energy and Dark Matter from dilatation symmetry.

Coupled Dark Energy and Dark Matter from dilatation symmetry.
A New Theory of Neutrino Oscillations Netta Engelhardt 8.19.2009.

A New Theory of Neutrino Oscillations Netta Engelhardt
Gravitational Tests of Lorentz Symmetry

Gravitational Tests of Lorentz Symmetry
WAG 2013, Bern, Nov. 14, 2013 True Tests of the Weak Equivalence Principle for Antiparticles Unnikrishnan. C. S. Gravitation Group & Fundamental Interactions.

WAG 2013, Bern, Nov. 14, 2013 True Tests of the Weak Equivalence Principle for Antiparticles Unnikrishnan. C. S. Gravitation Group & Fundamental Interactions.

Similar presentations

Ads by Google