Ghassen Dridi scite author profile

We present a general and versatile technique of population transfer based on parallel adiabatic passage by femtosecond shaped pulses. Their amplitude and phase are specifically designed to optimize the adiabatic passage corresponding to parallel eigenvalues at all times. We show that this technique allows the robust adiabatic population transfer in a Raman system with the total pulse area as low as 3 π, corresponding to a fluence of one order of magnitude below the conventional stimulated Raman adiabatic passage process. This process of short duration, typically pico-and subpicosecond, is easily implementable with the modern pulse shaper technology and opens the possibility of ultrafast robust population transfer with interesting applications in quantum information processing.

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Realization of a quantum Hamiltonian Boolean logic gate on the Si(001):H surface

Kolmer

Zuzak

Dridi

et al. 2015

Nanoscale

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The design and construction of the first prototypical QHC (Quantum Hamiltonian Computing) atomic scale Boolean logic gate is reported using scanning tunnelling microscope (STM) tip-induced atom manipulation on an Si(001):H surface. The NOR/OR gate truth table was confirmed by dI/dU STS (Scanning Tunnelling Spectroscopy) tracking how the surface states of the QHC quantum circuit on the Si(001):H surface are shifted according to the input logical status.

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Adiabatic approximation for quantum dissipative systems: Formulation, topology, and superadiabatic tracking

Dridi¹,

Guérin²,

Jauslin³

et al. 2010

Phys. Rev. A

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A generalized adiabatic approximation is formulated for a two-state dissipative Hamiltonian which is valid beyond weak dissipation regimes. The history of the adiabatic passage is described by superadiabatic bases as in the nondissipative regime. The topology of the eigenvalue surfaces shows that the population transfer requires, in general, a strong coupling with respect to the dissipation rate. We present, furthermore, an extension of the Davis-Dykhne-Pechukas formula to the dissipative regime using the formalism of Stokes lines. Processes of population transfer by an external frequency-chirped pulse-shaped field are given as examples.

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Optimal Robust Quantum Control by Inverse Geometric Optimization

2020

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We develop an inverse geometric optimization technique that allows the derivation of optimal and robust exact solutions of low-dimension quantum control problems driven by external fields: we determine in the dynamical variable space optimal trajectories constrained to robust solutions by Euler-Lagrange optimization; the control fields are then derived from the obtained robust geodesics and the inverted dynamical equations. We apply this method, referred to as robust inverse optimization (RIO), to design optimal control fields producing a complete or half population transfer and a NOT quantum gate robust with respect to the pulse inhomogeneities. The method is versatile and can be applied to numerous quantum control problems, e.g. other gates, other types of imperfections, Raman processes, or dynamical decoupling of undesirable e↵ects.

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The mathematics of a quantum Hamiltonian computing half adder Boolean logic gate

et al. 2015

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The mathematics behind the quantum Hamiltonian computing (QHC) approach of designing Boolean logic gates with a quantum system are given. Using the quantum eigenvalue repulsion effect, the QHC AND, NAND, OR, NOR, XOR, and NXOR Hamiltonian Boolean matrices are constructed. This is applied to the construction of a QHC half adder Hamiltonian matrix requiring only six quantum states to fullfil a half Boolean logical truth table. The QHC design rules open a nano-architectronic way of constructing Boolean logic gates inside a single molecule or atom by atom at the surface of a passivated semi-conductor.

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Robust control of a not gate by composite pulses

2020

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Optimal robust stimulated Raman exact passage by inverse optimization

2022

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Adiabatic passage for a lossy two-level quantum system by a complex time method

Dridi¹,

Guérin²

2012

J. Phys. A: Math. Theor.

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Using a complex time method with the formalism of Stokes lines, we establish a generalization of the Davis–Dykhne–Pechukas formula which gives in the adiabatic limit the transition probability of a lossy two-state system driven by an external frequency-chirped pulse-shaped field. The conditions that allow this generalization are derived. We illustrate the result with the dissipative Allen–Eberly and Rosen–Zener models.

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Ghassen Dridi

Ultrafast stimulated Raman parallel adiabatic passage by shaped pulses

Realization of a quantum Hamiltonian Boolean logic gate on the Si(001):H surface

Adiabatic approximation for quantum dissipative systems: Formulation, topology, and superadiabatic tracking

Optimal Robust Quantum Control by Inverse Geometric Optimization

The mathematics of a quantum Hamiltonian computing half adder Boolean logic gate

Robust control of a not gate by composite pulses

Optimal robust stimulated Raman exact passage by inverse optimization

Adiabatic passage for a lossy two-level quantum system by a complex time method

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