Presentation is loading. Please wait.

Presentation is loading. Please wait.

Jason Hogan May 22, 2014 LISA Symposium X Single-arm gravitational wave detectors based on atom interferometry.

Published byRoy Hensley Modified over 8 years ago

Similar presentations

Presentation on theme: "Jason Hogan May 22, 2014 LISA Symposium X Single-arm gravitational wave detectors based on atom interferometry."— Presentation transcript:

1 Jason Hogan May 22, 2014 LISA Symposium X Single-arm gravitational wave detectors based on atom interferometry

2 Are multiple baselines required? L (1 + h sin(ωt )) strain frequency Single Baseline Gravitational Wave Detection Motivation Formation flying: 2 vs. 3 spacecraft Reduce complexity, potentially cost Laser interferometer GW detector

3 Atom interference Light interferometer Atom interferometer Atom http://scienceblogs.com/principles/2013/10/22/quantum-erasure/ http://www.cobolt.se/interferometry.html Light fringes Beamsplitter Mirror Atom fringes

4 Measurement Concept Essential Features 1.Atoms are good clocks 2.Light propagates across the baseline at a constant speed Atom Clock Atom Clock L (1 + h sin(ωt ))

5 Simple Example: Two Atomic Clocks Time Phase evolved by atom after time T

6 Simple Example: Two Atomic Clocks Time GW changes light travel time Phase difference

7 Phase Noise from the Laser The phase of the laser is imprinted onto the atom. Laser phase noise, mechanical platform noise, etc. Laser phase is common to both atoms – rejected in a differential measurement.

8 Single Photon Accelerometer Three pulse accelerometer Long-lived single photon transition (e.g. clock transition in Sr, Yb, Ca, Hg, etc.) Graham, et al., PRD 78, 042003, (2008). Yu, et al., GRG 43, 1943, (2011).

9 Two-photon vs. single photon configurations 2 photon transitions 1 photon transitions Rb Sr How to incorporate LMT enhancement? Graham, et al., PRD 78, 042003, (2008). Yu, et al., GRG 43, 1943, (2011).

10 Laser frequency noise insensitive detector Graham, et al., arXiv:1206.0818, PRL (2013) Laser noise is common Excited state Pulses from alternating sides allow for sensitivity enhancement (LMT atom optics)

11 LMT enhancement with single photon transition Graham, et al., arXiv:1206.0818, PRL (2013) Example LMT beamsplitter (N = 3) Each pair of pulses measures the light travel time across the baseline. Excited state

12 Reduced Noise Sensitivity Differential phase shifts (kinematic noise) suppressed by  v/c < 3×10 -11 1. Platform acceleration noise  a 2. Pulse timing jitter  T 3. Finite duration  of laser pulses 4. Laser frequency jitter  k Leading order kinematic noise sources:

13 Satellite GW Antenna Common interferometer laser L ~ 100 - 1000 km Atoms JMAPS bus/ESPA deployed

14 Potential Strain Sensitivity J. Hogan, et al., GRG 43, 7 (2011).

15 Technology development for GW detectors 1)Laser frequency noise mitigation strategies 2)Large wavepacket separation (meter scale) 3)Ultra-cold atom temperatures (picokelvin) 4)Very long time interferometry (> 10 seconds)

16 Ground-based GW technology development 4 cm Long duration Large wavepacket separation

17 10 m Drop Tower Apparatus

18 Interference at long interrogation time 2T = 2.3 sec Near full contrast 6.7×10 -12 g/shot (inferred) Interference (3 nK cloud) Wavepacket separation at apex (this data 50 nK) Dickerson, et al., PRL 111, 083001 (2013). Demonstrated statistical resolution: ~5 ×10 -13 g in 1 hr ( 87 Rb)

19 Preliminary LMT in 10 m apparatus 7 cm wavepacket separation 10 ħk 4 cm wavepacket separation 6 ħk LMT using sequential Raman transitions with long interrogation time. LMT demonstration at 2T = 2.3 s (unpublished)

20 Atom Lens position time Geometric Optics: Atom Lens:

21 Atom Lens Cooling Optical Collimation: Atom Cooling: position time

22 Radial Lens Beam “point source” AC Stark Lens Apply transient optical potential (“Lens beam”) to collimate atom cloud in 2D Time

23 2D Atom Refocusing Without Lens With Lens Lens

24 Record Low Temperature North West Vary Focal Length

25 Extended free-fall on Earth Lens Launch  Lens  Relaunch  Detect Launched to 9.375 meters Relaunched to 6 meters Image of cloud after 5 seconds total free-fall time Towards T > 10 s interferometry (?)

26 Future GW work Single photon AI gradiometer proof of concept Ground based detector prototype work MIGA; ~1 km baseline (Bouyer, France) 10 m tower studies

27 27 AOSense 408-735-9500 AOSense.com Sunnyvale, CA 6 liter physics package As built view with front panel removed in order to view interior. Sr compact optical clock

28 Collaborators NASA GSFC Babak Saif Bernard D. Seery Lee Feinberg Ritva Keski-Kuha Stanford Mark Kasevich (PI) Susannah Dickerson Alex Sugarbaker Tim Kovachy Christine Donnelly Chris Overstreet Theory: Peter Graham Savas Dimopoulos Surjeet Rajendran Former members: David Johnson Sheng-wey Chiow Visitors: Philippe Bouyer (CNRS) Jan Rudolph (Hannover) AOSense Brent Young (CEO)

Download ppt "Jason Hogan May 22, 2014 LISA Symposium X Single-arm gravitational wave detectors based on atom interferometry."

Similar presentations

Beyond The Standard Quantum Limit B. W. Barr Institute for Gravitational Research University of Glasgow.

Beyond The Standard Quantum Limit B. W. Barr Institute for Gravitational Research University of Glasgow.
Gravitational Wave Astronomy Dr. Giles Hammond Institute for Gravitational Research SUPA, University of Glasgow Universität Jena, August 2010.

Gravitational Wave Astronomy Dr. Giles Hammond Institute for Gravitational Research SUPA, University of Glasgow Universität Jena, August 2010.
POC: Nan Yu Phone: Jet Propulsion Laboratory

POC: Nan Yu Phone: Jet Propulsion Laboratory
Gravitational Wave Astronomy Dr. Giles Hammond Institute for Gravitational Research SUPA, University of Glasgow Universität Jena, August 2010.

Gravitational Wave Astronomy Dr. Giles Hammond Institute for Gravitational Research SUPA, University of Glasgow Universität Jena, August 2010.
Dennis Ugolini, Trinity University Bite of Science Session, TEP 2014 February 13, 2014 Catching the Gravitational Waves.

Dennis Ugolini, Trinity University Bite of Science Session, TEP 2014 February 13, 2014 Catching the Gravitational Waves.
Comparison of LISA and Atom Interferometry for Gravitational Wave Astronomy in Space Peter L. Bender JILA, University of Colorado and NIST 46 th RENCONTRES.

Comparison of LISA and Atom Interferometry for Gravitational Wave Astronomy in Space Peter L. Bender JILA, University of Colorado and NIST 46 th RENCONTRES.
Towards a Laser System for Atom Interferometry Andrew Chew.

Towards a Laser System for Atom Interferometry Andrew Chew.
Laser System for Atom Interferometry Andrew Chew.

Laser System for Atom Interferometry Andrew Chew.
Measurements using Atom Free Fall

Measurements using Atom Free Fall
Prospects for gravitational wave detection with atom interferometry

Prospects for gravitational wave detection with atom interferometry
Gravitational Physics using Atom Interferometry

Gravitational Physics using Atom Interferometry
Laser Interferometer Space Antenna Satellite Description  Three spacecrafts forming a triangle flying 5 million km apart  Placed in an elliptical plain.

Laser Interferometer Space Antenna Satellite Description  Three spacecrafts forming a triangle flying 5 million km apart  Placed in an elliptical plain.
Louis J. Rubbo Neil Cornish and Olivier Poujade. The LISA Simulator Capabilities –Valid for an arbitrary gravitational wave at any frequency in the LISA.

Louis J. Rubbo Neil Cornish and Olivier Poujade. The LISA Simulator Capabilities –Valid for an arbitrary gravitational wave at any frequency in the LISA.
Louis J. Rubbo, Neil J. Cornish, and Olivier Poujade Support for this project was provided by the NASA EPSCoR program.

Louis J. Rubbo, Neil J. Cornish, and Olivier Poujade Support for this project was provided by the NASA EPSCoR program.
LIGO -- Studying the Fabric of the Universe LIGO-GOxxxx Barry C. Barish National Science Board LIGO Livingston, LA 4-Feb-04.

LIGO -- Studying the Fabric of the Universe LIGO-GOxxxx Barry C. Barish National Science Board LIGO Livingston, LA 4-Feb-04.
What are Gravity Waves?. According to Einstein's theory of gravity, an accelerating mass causes the fabric of space-time to ripple like a pond disturbed.

What are Gravity Waves?. According to Einstein's theory of gravity, an accelerating mass causes the fabric of space-time to ripple like a pond disturbed.
Laser System for Atom Interferometry Andrew Chew.

Laser System for Atom Interferometry Andrew Chew.
Introduction to HYPER Measuring Lense-Thirring with Atom Interferometry P. BOUYER Laboratoire Charles Fabry de l’Institut d’Optique Orsay, France.

Introduction to HYPER Measuring Lense-Thirring with Atom Interferometry P. BOUYER Laboratoire Charles Fabry de l’Institut d’Optique Orsay, France.
Lecture 3 Atom Interferometry: from navigation to cosmology Les Houches, 26 Sept. 2014 E.A. Hinds Centre for Cold Matter Imperial College London.

Lecture 3 Atom Interferometry: from navigation to cosmology Les Houches, 26 Sept E.A. Hinds Centre for Cold Matter Imperial College London.
Light Pulse Atom Interferometry for Precision Measurement

Light Pulse Atom Interferometry for Precision Measurement

Similar presentations

Ads by Google