Post-Doctoral Research Visit F/M Adiabatic control of quantum systems in presence of decoherence
The postdoc, of the duration of 24 months, will take place in the framework of the Défi Inria EQIP (Engineering for quantum information processors). It will be supervised by two Inria teams CAGE (Inria center of Paris), McTAO (Inria center of Sophia-Antipolis).
The postodc is expected to spend one year in Paris working as a member of the team CAGE and one in Sophia-Antipolis as a member of the team McTAO. Frequent travels of the postdoc between the two teams are expected (and will be convered by the two teams).
The postdoc is expected to collaborate with several members of the two teams: Ugo Boscain (CAGE), Jean-Baptiste Pomet (McTAO), Ludovic Sacchelli (McTAO), Mario Sigalotti (CAGE).
Adiabatic theory is a powerful tool in quantum control, yielding robust control strategies. The adiabatic theorem establishes that for a slowly varying self-adjoint Hamiltonian without eigenvalue intersections a trajectory starting from an eigenvector follows approximately the instantaneous eigenvector. Extensions of the adiabatic theorem permit to treat also the case with eigenvalue intersections; these allow the creation and control of population transfers between energy levels of the Hamiltonian. When the Hamiltonian is driven by two real-valued controls, the eigenvalue intersections of the Hamiltonian are generically conical. The efficiency and robustness of adiabatic strategies, demonstrated so far for closed quantum systems, make it very tempting to apply them to the case of open quantum systems. In this respect there are two different types of models describing the loss of coherence, to which adiabatic techniques can be applied: either one uses the Lindblad formalism and describes the evolution of the density matrix, or one studies a simpler model, on which this project will focus (at least in a first phase), where the decoherence is described by non-self-adjoint terms in the controlled Hamiltonian. Extensions of the adiabatic approach to the case of non-self-adjoint Hamiltonians exist [1,2], but their applicability to control of quantum mechanical systems is still not fully analyzed. The objective of the postdoc is to develop a systematic analysis of adiabatic control protocols for dispersive systems with and without parametric distribution, based on spectral properties of non-self adjoint controlled Hamiltonians.
 Nenciu, G., Rasche, G., On the adiabatic theorem for non self-adjoint Hamiltonians, J. Phys. A, 25, pp. 5741–5751, 1992.
 A. Joye, General Adiabatic Evolution with a Gap Condition, Communications in Mathematical Physics, volume 275, pp. 139–162, 2007.
The postdoc will contribute to the development of adiabatic control strategies for dispersive systems. He/she will pursue different research lines proposed by the two teams, expanding if necessary her/his background in singularity theory and averaging of dynamical systems.
The candidate should have a strong mathematical background, incuding in particular nonlinear control theory. Previous knowledge of the basics of quantum physics will be highly appriciated.
The candidate should also be willing to participate to a collaborative project between two team in different cities, accepting travel and bi-localization constraints.
- Subsidized meals
- Partial reimbursement of public transport costs
- Leave: 7 weeks of annual leave + 10 extra days off due to RTT (statutory reduction in working hours) + possibility of exceptional leave (sick children, moving home, etc.)
- Possibility of teleworking and flexible organization of working hours
- Professional equipment available (videoconferencing, loan of computer equipment, etc.)
- Social, cultural and sports events and activities
- Access to vocational training
- Theme/Domain : Optimization and control of dynamic systems
- Town/city : Paris
- Inria Center : CRI de Paris
- Starting date : 2022-10-01
- Duration of contract : 2 years
- Deadline to apply : 2022-07-31