P
Petr Král
Researcher at University of Illinois at Chicago
Publications - 242
Citations - 10817
Petr Král is an academic researcher from University of Illinois at Chicago. The author has contributed to research in topics: Creep & Graphene. The author has an hindex of 45, co-authored 222 publications receiving 8648 citations. Previous affiliations of Petr Král include University of British Columbia & Harvard University.
Papers
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Journal ArticleDOI
Robust carbon dioxide reduction on molybdenum disulphide edges
Mohammad Asadi,Bijandra Kumar,Amirhossein Behranginia,Brian A. Rosen,Artem Baskin,Nikita Repnin,Davide Pisasale,Patrick J. Phillips,Wei Zhu,Richard T. Haasch,Robert F. Klie,Petr Král,Jeremiah T. Abiade,Amin Salehi-Khojin +13 more
TL;DR: Molybdenum disulphide is identified as a promising cost-effective substitute for noble metal catalysts and shows superior carbon dioxide reduction performance compared with the noble metals with a high current density and low overpotential in an ionic liquid.
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Selective ion passage through functionalized graphene nanopores.
Kyaw Sint,Boyang Wang,Petr Král +2 more
TL;DR: Functionalized nanopores in graphene monolayers are designed and shown by molecular dynamics simulations that they provide highly selective passage of hydrated ions and have potential applications in molecular separation, desalination, and energy storage systems.
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Self-assembly of magnetite nanocubes into helical superstructures
TL;DR: It is found that under carefully controlled conditions, cubic nanocrystals of magnetite self-assemble into arrays of helical superstructures in a template-free manner with >99% yield.
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Colloquium: Coherently controlled adiabatic passage
TL;DR: In this article, the merging of coherent control and adiabatic passage (AP) is discussed and the type of problems that can be solved using the resulting coherently controlled AP method are discussed.
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Dipole-dipole interactions in nanoparticle superlattices.
TL;DR: A surprisingly rich phase diagram of monodisperse semiconducting nanoparticles is explained by considering the interactions between nonlocal dipoles of individual nanoparticles and predicts antiferroelectric ordering in dipolar nanoparticle superlattices.