Your search keyword '"Korytar, R."' showing total 2 results

1. Chiral Light Emission from a Hybrid Magnetic Molecule-Monolayer Transition Metal Dichalcogenide Heterostructure.

Author

Varade V, Haider G, Slobodeniuk A, Korytar R, Novotny T, Holy V, Miksatko J, Plsek J, Sykora J, Basova M, Zacek M, Hof M, Kalbac M, and Vejpravova J

Abstract

Hybrid layered materials assembled from atomically thin crystals and small molecules bring great promises in pushing the current information and quantum technologies beyond the frontiers. We demonstrate here a class of layered valley-spin hybrid (VSH) materials composed of a monolayer two-dimensional (2D) semiconductor and double-decker single molecule magnets (SMMs). We have materialized a VSH prototype by thermal evaporation of terbium bis-phthalocyanine onto a MoS 2 monolayer and revealed its composition and stability by both microscopic and spectroscopic probes. The interaction of the VSH components gives rise to the intersystem crossing of the photogenerated carriers and moderate p-doping of the MoS 2 monolayer, as corroborated by the density functional theory calculations. We further explored the valley contrast by helicity-resolved photoluminescence (PL) microspectroscopy carried out down to liquid helium temperatures and in the presence of the external magnetic field. The most striking feature of the VSH is the enhanced A exciton-related valley emission observed at the out-of-resonance condition at room temperature, which we elucidated by the proposed nonradiative energy drain transfer mechanism. Our study thus demonstrates the experimental feasibility and great promises of the ultrathin VSH materials with chiral light emission, operable by physical fields for emerging opto-spintronic, valleytronic, and quantum information concepts.

Published

2023

2. Density functional theory based screening of ternary alkali-transition metal borohydrides: a computational material design project.

Author

Hummelshøj JS, Landis DD, Voss J, Jiang T, Tekin A, Bork N, Dułak M, Mortensen JJ, Adamska L, Andersin J, Baran JD, Barmparis GD, Bell F, Bezanilla AL, Bjork J, Björketun ME, Bleken F, Buchter F, Bürkle M, Burton PD, Buus BB, Calborean A, Calle-Vallejo F, Casolo S, Chandler BD, Chi DH, Czekaj I, Datta S, Datye A, DeLaRiva A, Despoja V, Dobrin S, Engelund M, Ferrighi L, Frondelius P, Fu Q, Fuentes A, Fürst J, García-Fuente A, Gavnholt J, Goeke R, Gudmundsdottir S, Hammond KD, Hansen HA, Hibbitts D, Hobi E Jr, Howalt JG, Hruby SL, Huth A, Isaeva L, Jelic J, Jensen IJ, Kacprzak KA, Kelkkanen A, Kelsey D, Kesanakurthi DS, Kleis J, Klüpfel PJ, Konstantinov I, Korytar R, Koskinen P, Krishna C, Kunkes E, Larsen AH, Lastra JM, Lin H, Lopez-Acevedo O, Mantega M, Martínez JI, Mesa IN, Mowbray DJ, Mýrdal JS, Natanzon Y, Nistor A, Olsen T, Park H, Pedroza LS, Petzold V, Plaisance C, Rasmussen JA, Ren H, Rizzi M, Ronco AS, Rostgaard C, Saadi S, Salguero LA, Santos EJ, Schoenhalz AL, Shen J, Smedemand M, Stausholm-Møller OJ, Stibius M, Strange M, Su HB, Temel B, Toftelund A, Tripkovic V, Vanin M, Viswanathan V, Vojvodic A, Wang S, Wellendorff J, Thygesen KS, Rossmeisl J, Bligaard T, Jacobsen KW, Nørskov JK, and Vegge T

Abstract

We present a computational screening study of ternary metal borohydrides for reversible hydrogen storage based on density functional theory. We investigate the stability and decomposition of alloys containing 1 alkali metal atom, Li, Na, or K (M(1)); and 1 alkali, alkaline earth or 3d/4d transition metal atom (M(2)) plus two to five (BH(4))(-) groups, i.e., M(1)M(2)(BH(4))(2-5), using a number of model structures with trigonal, tetrahedral, octahedral, and free coordination of the metal borohydride complexes. Of the over 700 investigated structures, about 20 were predicted to form potentially stable alloys with promising decomposition energies. The M(1)(Al/Mn/Fe)(BH(4))(4), (Li/Na)Zn(BH(4))(3), and (Na/K)(Ni/Co)(BH(4))(3) alloys are found to be the most promising, followed by selected M(1)(Nb/Rh)(BH(4))(4) alloys.

Published

2009