Your search keyword '"Shokirbek Shermukhamedov"' showing total 5 results

1. Complex single‐molecule and molecular scale entities in electrochemical environments: Mechanisms and challenges

Author

Christian Engelbrekt, Renat R. Nazmutdinov, Shokirbek Shermukhamedov, Jens Ulstrup, Tamara T. Zinkicheva, and Xinxin Xiao

Subjects

Industrial electrochemistry, TP250-261, Chemistry, QD1-999

Abstract

Abstract Following a renaissance from the 1980s, electrochemistry has developed into sophisticated interdisciplinary science integrating solid‐state and surface science and further, biological sciences. Most remarkably, even the single‐molecule can now be addressed. Single‐molecule electrochemistry covers transition metal complexes, organic redox molecules, fragile biomolecules, and molecular‐scale hybrids between metallic nanoparticles and complex molecules, supported by new theoretical frames. We overview here selected areas of molecular scale electrochemistry. After a theoretical minimum, we address complex molecules in electron transfer, enzyme catalysis, and nanoparticle catalysis. Our focus is on issues not so much previously highlighted, such as competition between superexchange and sequential conduction, and resonance features in the transition between the two limits. Another aspect is coherent multi‐electron transfer for large bias voltages often needed to drive enough current through solute molecular junctions. We note finally some single‐molecule perspectives relating to DNA‐based molecules and to spin transitions via chiral molecules.

Published

2022

2. Structure to Property: Chemical Element Embeddings for Predicting Electronic Properties of Crystals.

Author

Shokirbek Shermukhamedov, Dilorom Mamurjonova, Thana Maihom, and Michael Probst

Published

2024

3. Structure to Property: Chemical Element Embeddings and a Deep Learning Approach for Accurate Prediction of Chemical Properties.

Author

Shokirbek Shermukhamedov, Dilorom Mamurjonova, and Michael Probst

Published

2023

4. Neural Network Based Molecular Dynamics Simulations of Sputtering Processes.

Author

Shokirbek Shermukhamedov, Michael Probst, and Lei Chen

Published

2021

5. Modelling the impact of argon atoms on a tungsten surface

Author

Shokirbek Shermukhamedov and Michael Probst

Subjects

Atomic and Molecular Physics, and Optics

Abstract

Sputtering from plasma-facing surfaces upon particle impact is an important process in material science. It is especially relevant in the diverter region of fusion devices, which nearly always consist of tungsten. Besides the main plasma components, argon is used in fusion devices to improve energy confinement. As a consequence, hot Ar atoms interact with W surfaces and can cause sputtering and other material degrading events. Atomistic simulations of the plasma-wall interactions make it possible to carry out a detailed analysis of sputtering, reflection, and retention processes. We report the results of molecular dynamics simulations with neural network potential energy expressions modelling the bombardment of tungsten samples by argon atoms in the energy range from 100 to 800 eV. The obtained sputtering results are in good agreement with available literature data. Furthermore, our data provide additional insight into atomic details of the processes involved in sputtering. We also investigate the effect of surface temperature on sputtering and reflection probabilities, which significantly affects the irradiation process at higher impact energies. Graphical abstract

Published

2022