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Quantum Control by Few-Cycles Pulses: The Two-Level Problem.

François Peyraut1, Frédéric Holweck1,2, Stéphane Guérin3

  • 1ICB, UMR 6303, CNRS, University Bourgogne Franche-Comté, UTBM, 90010 Belfort, France.

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Summary
This summary is machine-generated.

We demonstrate ultrahigh-fidelity population transfer in two-state systems using few-cycle electromagnetic pulses. Strategies overcome limitations of the rotating wave approximation for rapid quantum state control.

Keywords:
adiabatic Floquet theoryadiabatic passagequantum controlquantum system driven by an external field

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Area of Science:

  • Quantum dynamics
  • Atomic and molecular physics
  • Nonlinear optics

Background:

  • Population transfer is crucial for quantum control.
  • Short electromagnetic pulses (few-cycle) present challenges due to non-adiabatic effects.
  • The rotating wave approximation often fails for such short pulses.

Purpose of the Study:

  • To achieve ultrahigh-fidelity population transfer in two-state systems using minimal electromagnetic field cycles.
  • To develop strategies effective even when the rotating wave approximation breaks down.
  • To explore both adiabatic and non-adiabatic approaches for rapid quantum state manipulation.

Main Methods:

  • Adiabatic passage based on adiabatic Floquet theory for 2.5 cycles.
  • Implementing dynamics along an adiabatic trajectory.
  • Deriving non-adiabatic strategies using shaped or chirped pulses.
  • Extending the pi-pulse regime to two- or single-cycle pulses.
  • Considering the physical constraint of a zero-area total field.

Main Results:

  • Ultrahigh-fidelity population transfer achieved with as few as 2.5 cycles.
  • Successful implementation of adiabatic passage dynamics.
  • Development of novel non-adiabatic strategies for single- and two-cycle pulses.
  • Demonstration of quantum control beyond the limits of the rotating wave approximation.

Conclusions:

  • Effective population transfer is possible with very short electromagnetic pulses.
  • Adiabatic Floquet theory provides a robust framework for few-cycle pulse dynamics.
  • Novel pulse shaping and chirping techniques enable rapid quantum state control.