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Outline The goal The Hamiltonian The superfast cooling concept Results Lessons learned (time allowing)

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Presentation on theme: "Outline The goal The Hamiltonian The superfast cooling concept Results Lessons learned (time allowing)"— Presentation transcript:

1

2 Outline

3 The goal The Hamiltonian The superfast cooling concept Results Lessons learned (time allowing)

4 Goal

5 The Hamiltonian Sidebands are resolved Standing wave ( * ) Lamb-Dicke regime ( ** )

6 Assume we can implement both and pulses We could implement the red-SB operator with and taking Cooling at the impulsive limit and do so impulsively, using infinitely short pulses, via the Suzuki-Trotter approx.

7 Solution: use a pulse sequence to emulate o pulse o Wait (free evolution) o reverse-pulse [Retzker, Cirac, Reznik, PRL 94, 050504 (2005)] Intuition We have, we want

8

9 The above argument isn’t realizable: We cannot do infinite number of infinitely short pulses Laser / coupling strength is finite  Cannot ignore free evolution while pulsing  Quantum optimal control But …

10 How we cool Apply the pulse and the pseudo-pulse Repeat Reinitialize the ion’s internal d.o.f. Repeat Sequence Cycle

11 Numeric work done with Qlib A Matlab package for QI, QO, QOC calculations http://qlib.info

12 Cycle ACycle BCycle C Initial phonon count357 Final phonon count0.41.271.95 after 100 cycles0.020.100.22 Cycle duration4.42.70.8 No. of X,P pulses633 No. of sequences10

13 How does a cooling sequence look like?

14 Dependence on initial phonon count 1 application of the cooling cycle

15 Effect of repeated applications of the cooling cycles

16 Dependence on initial phonon count 25 application of the cooling cycle

17 Robustness

18 Cycles used were optimized for the impulsive limit Stronger coupling means faster cooling We can do even better

19

20 Lessons learned (1) Exponentiating matrices is tricky o For infinite matrices (HO), even more so o Inaccuracies enough to break BCH relations for P-w-P Analytically, BCH relations of multiple pulses become unmanageably long Do as much as possible analytically Use mechanized algebra (e.g. Mathematica)

21 Lessons learned (2) Sometimes it is easier to start with a science-fiction technique, and push it down to realizable domain than to push a low-end technique up Optimal Control can change performance of quantum systems by orders of magnitude See Qlib / Dynamo, to be published soon

22 Superfast cooling A novel way of cooling trapped particles Upper limit on speed Applicable to a wide variety of systems We will help adapt superfast cooling to your system

23 Thank you ! PRL 104, 183001 (2010) http://qlib.info

24

25 The unitary transformation

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