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Using Randomness for Coherent Quantum Control

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Presentation on theme: "Using Randomness for Coherent Quantum Control"— Presentation transcript:

1 Using Randomness for Coherent Quantum Control
Lea F. Santos and Lorenza Viola Department of Physics and Astronomy Dartmouth College Viola & Knill, PRL 94, (2005) Randomization may be more advantageous when i) large control groups/ long time intervals and/or ii) rapidly fluctuating interactions Deterministic vs. RANDOM dynamical decoupling Santos & Viola, forthcoming Single qubit: decoherence suppression Identify situations where a random protocol is more suitable combining protocols leads to a better performance

2 Decoherence from a Quantum Bosonic Environment
Model is exactly solvable Interaction picture: Decoherence function in the absence of control, Ohmic bath: bath correlation time system-bath interaction strength bath temperature High T Low T

3 Deterministic Dynamical Decoupling
Goal: Average out the interaction with the environment Bang-Bang: Arbitrarily strong and instantaneous control operations drawn from a group Sequences of bang-bang operations + free evolutions Decoupling if High T Low T + - Cyclic dynamical scheme: Viola & Lloyd, PRA 94, (1998) Viola et al, PRL 82, 2417 (1999)

4 Random Dynamical Decoupling
Naïve random protocol: at pulse (PAREC method) Hybrid protocol: combines deterministic and random protocols (embeds a deterministic scheme into a stochastic one) Acyclic. Toggling/logical frame – evolution follows the applied control

5 Deterministic vs. Random Decoupling: Numerical Results
Fixed time interval: i) large number of control pulses: all protocols are equivalent ii) small number of control pulses: hybrid may perform better * * deterministic no control + + hybrid random High T Low T

6 Time-Dependent Coupling
High T * * deterministic no control random Random pulses may be safer

7 Conclusions Comparison between deterministic and RANDOM dynamical decoupling for a single qubit + quantum environment There are situations where combined protocols (deterministic + random) may perform better (hybrid protocol) randomized control is more recommendable [when the coupling is fast oscillating, for example] Further work is necessary to expand the analysis References: L. Viola and S. Lloyd, PRA 94, (1998) L. Viola, E. Knill and S. Lloyd, PRL 82, 2417 (1999) L. Viola and E. Knill, PRL 94, (2005) O. Kern , G. Alber and D. L. Shepelyansky, Eur. Phys. J. D 32, 153 (2005) O. Kern and G. Alber, quant-ph/ L. F. Santos and L. Viola, forthcoming

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