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established. We will take advantage of lattice vibrations, nuclear quantum, and electrochemical effects, and consequently reformulate classical diffusion theory to consider these game changers. As a result, we
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random and deterministic systems and point configurations. Potential applications include lattices, point processes, random matrices, and random walks on groups. During the project you will work
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model that explains lattice distortions and branching mechanisms. (4) Analyze experimental data using advanced computational tools and present results in research meetings and scientific publications
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clocks and laser links between Earth and the international space station ISS. The concrete task is to optimize our strontium lattice clock (DOI: 10.1103/PhysRevA.98.053443), transfer it to the Geodetic
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combs that require large and complex setups, we aim to realize them directly on chip, using liquid-like light and schemes of lattices in synthetic frequency dimensions to achieve unprecedented stability
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defects induced by the connection of two crystal lattices of different geometry and orientation. We will then study the interaction of these defects with hydrogen, and their impact on hydrogen diffusion
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(GeV), tin-vacancy (SnV), etc.). A G4V center is a point defect in the diamond lattice, consisting of a Group-IV atom (e.g., Si) and two adjacent vacancies [2]. This defect introduces energy levels
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of systems such as heterostructures of two-dimensional van der Waals materials, atomically well-defined graphene nanoribbons, and artificial lattices on surfaces. The position of the Doctoral
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Condensed Matter Physics , Hard Condensed Matter Theory , hep , HEP-Experiment (hep-ex) , hep-lat , HEP-Lattice (hep-lat) , hep-ph , HEP-Phenomenology (hep-ph) , hep-th , HEP-Theory (hep-th) , High energy
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der Waals materials, atomically well-defined graphene nanoribbons, and artificial lattices on surfaces. The position of the Doctoral Researcher is initially filled for 2 years. The contract is continued