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6,500 people supporting the three main missions of the institution: education, research and innovation. The EPFL campus offers an exceptional working environment at the heart of a community of more
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-generation battery technologies and CO2 capture/utilization methods. Our research group designs: (1) new energy materials and (2) electrochemical processes by precisely controlling the chemical environment
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responsibilities will include setting up laser systems for coherent Rydberg state manipulation, designing optical and electronic systems for precise control, and calibrating the dynamical process with the appearence
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calculations of the spin dynamics. Based on recent theoretical developments in our group (publication 1 , publication 2 ), we plan to use numerical optimization of effective Hamiltonians to generate new and more
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calculations of the spin dynamics. Based on recent theoretical developments in our group (publication 1 , publication 2 ), we plan to use numerical optimization of effective Hamiltonians to generate new and more
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designs: (1) new energy materials and (2) electrochemical processes by precisely controlling the chemical environment at the solid-electrolyte interface. This involves molecular engineering of electrolytes
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manipulation, designing optical and electronic systems for precise control, and calibrating the dynamical process with the appearence of Rydberg interactions. Scientific objectives include searching for optimal
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(publication 1 , publication 2 ), we plan to use numerical optimization of effective Hamiltonians to generate new and more efficient pulse sequences in a way similar to the analytical approach used so far
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, publication 2 ), we plan to use numerical optimization of effective Hamiltonians to generate new and more efficient pulse sequences in a way similar to the analytical approach used so far. Job description The
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on nanostructured semiconductors are promising for this challenge. They feature high miniaturization potential, low fabrication cost and can be integrated readily into handheld devices due to their compact design