Presentation is loading. Please wait.

Presentation is loading. Please wait.

Single-ion Quantum Lock-in Amplifier

Published by Modified over 9 years ago

Similar presentations

Presentation on theme: "Single-ion Quantum Lock-in Amplifier"— Presentation transcript:

1 Single-ion Quantum Lock-in Amplifier
FRISNO2011 Single-ion Quantum Lock-in Amplifier Shlomi Kotler Nitzan Akerman Yinnon Glickman Anna Kesselman Roee Ozeri The Weizmann Institute of Science

2 Information is Physical
Information getters Measurement probe Couples to its environment Information carriers Physical memory transmission channels Weak coupling to the environment measurement coherence Noise as a common enemy.

3 Radio transmission Transfer an audio-frequency electro-magnetic signal, f(t), over a noisy medium. AM: modulate f(t) with a frequency wm , outside the noise bandwidth: At the receiver, mix the recieved signal with and low-pass filter Recover at base-band frequencies the signal

4 Lock-in amplifier and measurement
Invented in the 50’s by Princeton physicist, Robert Dicke Want to measure a (noisy) physical quantity Y Modulate Y at a frequency wm outside the noise bandwidth: Electronically mix the detected Y signal with: and low-pass filter

5 “Quantum Radio”: Dynamic de-coupling
Protect coherence in a quantum system (e.g. qubit) which is subject to a noisy environment or coupled to a non-Markovian bath Engineer a time dependent system Hamiltonian: H(t) Decoherence rate is proportional to the spectral overlap of the system time evolution with the noise/bath spectrum. Gordon, Erez and Kurizki, J. of Phys. B, 40, S75 (2007) Sagi, Almog and Davidson, Phys. Rev. Lett., 104, (2010)

6 Quantum two-level probe
|­ñ w 0 = w0(B) w L -w 0 = d(B) The Bloch sphere Z X |¯ñ Y |Z+ñ = |­ñ |Z-ñ = |¯ñ |X-ñ = (|­ñ + |¯ñ) /Ö2 |X-ñ = (|­ñ - |¯ñ)/Ö2 |Y+ñ = (|­ñ + i |¯ñ)/Ö2 |Y-ñ = (|­ñ - i |¯ñ)/Ö2

7 Quantum phase estimation
q = p/2 j = 0 1st Ramsey pulse 2nd Ramsey pulse Bloch sphere q = p/2 |­ñ j = 0→p |­ñ - |¯ñ f T |­ñ + i |¯ñ |­ñ - i |¯ñ |­ñ + |¯ñ f |¯ñ Noise reduces fringe contrast Repeat the experiment many times Reduced contrast = more experiments

8 Quantum Lock-in T q = p f = 0 2techo techo N Echo-pulses q = p/2 f = 0
f = 0,p 1st Ramsey pulse 2nd Ramsey pulse T S. Kotler et. al. arXiv: [quant-ph] (2011); accepted in Nature J. R. Mae et. al. Nature, 455, 644, (2008)

9 A single trapped ion

10 Electronic levels in 88Sr+
5 2P3/2 Fine structure 5 2P 1033 nm 5 2P1/2 4 2D5/2 1092 nm 4 2D 408 nm 4 2D3/2 422 nm 674 nm 5 2S1/2 Turn on small B field 2.8 MHz/G

11 Probe initialization Optical pumping Fidelity > 0.9999 5S1/2 s+
 5S1/2 2.8 MHz/G 

12 Coherent probe rotations
Pulse time RF phase Bloch sphere |­ñ |­ñ - |¯ñ |­ñ + i |¯ñ |­ñ - i |¯ñ |­ñ + |¯ñ |¯ñ

13 Qubit Detection 2S1/2 Fidelity = 0.9989 Detection Shelving  
2P3/2 dark bright 2P1/2 Detection 1092nm 2D5/2 g = 0.4 Hz 2D3/2 422nm 674nm Shelving   2.8 MHz/G 2S1/2

14 Echo Pulse Train q = p f = 0 2techo techo N Echo-pulses q = p/2 f = 0
f = 0,p 1st Ramsey pulse 2nd Ramsey pulse

15 Long Coherence time and Measurement Sensitivity
17 Echo-pulses 2.6 mG 3.9 mG 5.4 mG A = contrast

16 Long Coherence time and Measurement Sensitivity
A=1; Standard Quantum Limit

17 Fast Lock-in Modulation
q = p f = p/2 f = 0 N Echo-pulses q = p/2 f = 0 f = 0,p 1st Ramsey pulse 2nd Ramsey pulse Modulation at Hz Sensitivity= 0.4 Hz/Hz1/2 =0.15 mG/Hz1/2 Coherence time = 1.4 Sec

18 Allen deviation analysis
Minimum uncertainty: 9 mHz (3 nG) after 3720 sec

19 Magnetometer Performance
1/(resolution)3/2

20 Light shift Detection 5 2S1/2   Echo pulses q = p/2 f = 0
f = 0,p 1st Ramsey pulse 2nd Ramsey pulse q = p f = p/2 f = 0 Off-resonance 674 nm beam (Line-width ≤ 80 Hz) 4 2D5/2 17 kHz 674 nm   5 2S1/2

21 Small Signal Lock-in Detection
Measured light shift: 9.7(4) Hz Calculated: 9.9(4) Hz

22 Light shift Spectroscopy
4 2D5/2 Scan the laser frequency across the S →D transition 674 nm   5 2S1/2

23 Light shift Spectroscopy

24 With a single trapped ion coupled to a magnetically noisy environment:
Summary Quantum Lock-in amplifier: Dynamic coupling/de-coupling can improve on measurement SNR With a single trapped ion coupled to a magnetically noisy environment: A long coherence time: 1.4 sec. Frequency shift measurement sensitivity : 0.4 Hz/Hz1/2 (15 pT/Hz1/2) Frequency shift measurement uncertainty: 9 mHz (300 fT) after 1 hour integration time Applications: magnetometery; direct magnetic spin-spin coupling Applications: Precision measurements; frequency metrology. S. Kotler et. al. arXiv: [quant-ph] (2011); accepted in Nature.

25 Yinnon Roee Shlomi Nitzan Anna Thank you Yoni Ziv Elad

Download ppt "Single-ion Quantum Lock-in Amplifier"

Similar presentations

High-resolution spectroscopy with a femtosecond laser frequency comb Vladislav Gerginov 1, Scott Diddams 2, Albrecht Bartels 2, Carol E. Tanner 1 and Leo.

High-resolution spectroscopy with a femtosecond laser frequency comb Vladislav Gerginov 1, Scott Diddams 2, Albrecht Bartels 2, Carol E. Tanner 1 and Leo.
In Search of the “Absolute” Optical Phase

In Search of the “Absolute” Optical Phase
Tunable Laser Spectroscopy Referenced with Dual Frequency Combs International Symposium on Molecular Spectroscopy 2010 Fabrizio Giorgetta, Ian Coddington,

Tunable Laser Spectroscopy Referenced with Dual Frequency Combs International Symposium on Molecular Spectroscopy 2010 Fabrizio Giorgetta, Ian Coddington,
Results The optical frequencies of the D 1 and D 2 components were measured using a single FLFC component. Typical spectra are shown in the Figure below.

Results The optical frequencies of the D 1 and D 2 components were measured using a single FLFC component. Typical spectra are shown in the Figure below.
Space-time positioning at the quantum limit with optical frequency combs Workshop OHP September 2013 Valérian THIEL, Pu JIAN, Jonathan ROSLUND, Roman SCHMEISSNER,

Space-time positioning at the quantum limit with optical frequency combs Workshop OHP September 2013 Valérian THIEL, Pu JIAN, Jonathan ROSLUND, Roman SCHMEISSNER,
Samansa Maneshi, Jalani Kanem, Chao Zhuang, Matthew Partlow Aephraim Steinberg Department of Physics, Center for Quantum Information and Quantum Control,

Samansa Maneshi, Jalani Kanem, Chao Zhuang, Matthew Partlow Aephraim Steinberg Department of Physics, Center for Quantum Information and Quantum Control,
LPS Quantum computing lunchtime seminar Friday Oct. 22, 1999.

LPS Quantum computing lunchtime seminar Friday Oct. 22, 1999.
Graham Lochead 07/09/09 Pulsed laser spectroscopy in strontium.

Graham Lochead 07/09/09 Pulsed laser spectroscopy in strontium.
Coherent State Preparation of a Single Molecule

Coherent State Preparation of a Single Molecule
Preventing Disentanglement by Symmetry Manipulations G. Gordon, A. Kofman, G. Kurizki Weizmann Institute of Science, Rehovot 76100, Israel Sponsors: EU,

Preventing Disentanglement by Symmetry Manipulations G. Gordon, A. Kofman, G. Kurizki Weizmann Institute of Science, Rehovot 76100, Israel Sponsors: EU,
Danielle Boddy Durham University – Atomic & Molecular Physics group Laser locking to hot atoms.

Danielle Boddy Durham University – Atomic & Molecular Physics group Laser locking to hot atoms.
Universal Optical Operations in Quantum Information Processing Wei-Min Zhang ( Physics Dept, NCKU )

Universal Optical Operations in Quantum Information Processing Wei-Min Zhang ( Physics Dept, NCKU )
Danielle Boddy Durham University – Atomic & Molecular Physics group Red MOT is on its way to save the day!

Danielle Boddy Durham University – Atomic & Molecular Physics group Red MOT is on its way to save the day!
Rydberg excitation laser locking for spatial distribution measurement Graham Lochead 24/01/11.

Rydberg excitation laser locking for spatial distribution measurement Graham Lochead 24/01/11.
Niels Bohr Institute Copenhagen University Eugene PolzikLECTURE 5.

Niels Bohr Institute Copenhagen University Eugene PolzikLECTURE 5.
Long coherence times with dense trapped atoms collisional narrowing and dynamical decoupling Nir Davidson Yoav Sagi, Ido Almog, Rami Pugatch, Miri Brook.

Long coherence times with dense trapped atoms collisional narrowing and dynamical decoupling Nir Davidson Yoav Sagi, Ido Almog, Rami Pugatch, Miri Brook.
Quantum dynamics with ultra cold atoms Nir Davidson Weizmann Institute of Science Billiards BEC I. Grunzweig, Y. Hertzberg, A. Ridinger (M. Andersen, A.

Quantum dynamics with ultra cold atoms Nir Davidson Weizmann Institute of Science Billiards BEC I. Grunzweig, Y. Hertzberg, A. Ridinger (M. Andersen, A.
References Acknowledgements This work is funded by EPSRC 1.R. P. Abel, U. Krohn, P. Siddons, I. G. Hughes & C. S. Adams, Opt Lett. 34 3071 (2009). 2.A.

References Acknowledgements This work is funded by EPSRC 1.R. P. Abel, U. Krohn, P. Siddons, I. G. Hughes & C. S. Adams, Opt Lett (2009). 2.A.
Coherence and decay within Bose-Einstein condensates – beyond Bogoliubov N. Katz 1, E. Rowen 1, R. Pugatch 1, N. Bar-gill 1 and N. Davidson 1, I. Mazets.

Coherence and decay within Bose-Einstein condensates – beyond Bogoliubov N. Katz 1, E. Rowen 1, R. Pugatch 1, N. Bar-gill 1 and N. Davidson 1, I. Mazets.
A strontium detective story James Millen Strontium detective – Group meeting 19/10/09 Ions‽

A strontium detective story James Millen Strontium detective – Group meeting 19/10/09 Ions‽

Similar presentations

Ads by Google