Yenni P. Ortiz scite author profile

International audienceA novel approach to investigate the electron transport of cis-and trans-polyacetylene chains in the single-electron approximation is presented by using microwave emulation measurements and tight-binding calculations. In the emulation we take into account the different electronic couplings due to the double bonds leading to coupled dimer chains. The relative coupling constants are adjusted by DFT calculations. For sufficiently long chains a transport band gap is observed if the double bonds are present, whereas for identical couplings no band gap opens. The band gap can be observed also in relatively short chains, if additional edge atoms are absent, which cause strong resonance peaks within the band gap. The experimental results are in agreement with our tight-binding calculations using the nonequilibrium Green's function method. The tight-binding calculations show that it is crucial to include third nearest neighbor couplings to obtain the gap in the cis-polyacetylene

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Spontaneous symmetry breaking and strong deformations in metal adsorbed graphene sheets

Jalbout

Ortiz

Seligman

2013

Chemical Physics Letters

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We study the adsorption of Li to graphene flakes described as aromatic molecules.Surprisingly the out of plane deformation is much stronger for the double adsorption from both sides to the same ring than for a single adsorption, although a symmetric solution seems possible. We thus have an interesting case of spontaneous symmetry breaking. While we cannot rule out a Jahn Teller deformation with certainty, this explanation seems unlikely and other options are discussed. We find a similar behavior for Boron-Nitrogen sheets, and also for other light alkalines.3

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Current Vortices in Aromatic Carbon Molecules

Stegmann¹,

Franco-Villafañe²,

Ortiz³

et al. 2019

Preprint

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The local current flow through three small aromatic carbon molecules, namely benzene, naphthalene and anthracene, is studied. Applying density functional theory and the non-equilibrium Green's function method for transport, we demonstrate that pronounced current vortices exist at certain electron energies for these molecules. The intensity of these circular currents, which appear not only at the anti-resonances of the transmission but also in vicinity of its maxima, can exceed the total current flowing through the molecular junction and generate considerable magnetic fields. The π electron system of the molecular junctions is emulated experimentally by a network of macroscopic microwave resonators. The local current flows in these experiments confirm the existence of current vortices as a robust property of ring structures. The circular currents can be understood in terms of a simple nearest-neighbor tight-binding Hückel model. Current vortices are caused by the interplay of the complex eigenstates of the open system which have energies close-by the considered electron energy. Degeneracies, as observed in benzene and anthracene, can thus generate strong circular currents, but also non-degenerate systems like naphthalene exhibit current vortices. Small imperfections and perturbations can couple otherwise uncoupled states and induce circular currents. arXiv:2001.07796v1 [cond-mat.mes-hall]

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Energies for cyclic and acyclic aggregations of adamantane and diamantane units sharing vertices, edges, or six‐membered rings

Balaban

Bhattacharya

Klein

et al. 2015

Int J of Quantum Chemistry

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Diamondoids are hydrocarbons having a carbon scaffold comprised from polymer‐like composites of adamantane cages. This article describes computed total energies and “SWB‐tension” energies (often referred to as “strain” energies) for species having n adamantane or diamantane units sharing pairwise: one carbon atom (spiro‐[n]adamantane or spiro‐[n]diamantane); one CC bond (one‐bond‐sharing‐[n]adamantane or one‐bond‐sharing‐[n]diamantane); or one chair‐shaped hexagon of carbon atoms (1234‐helical‐cata‐[n]diamantanes). Each of the five investigated polymer‐like types is considered either as an acyclic or a cyclic chain of adamantane‐ or diamantane‐unit cages. With increasing n values, SWB‐tension energies for acyclic aggregates are found to increase linearly, while the net SWB‐tension energies of cyclic aggregates often go thru a minimum at a suitable value of n. In all five cases, a limiting common energy per unit ( E/n) is found to be approached by both cyclic and acyclic chains as n→∞, as revealed from plots of E/n versus 1/n for acyclic chains and of E/n versus 1/n2 for cyclic chains. © 2015 Wiley Periodicals, Inc.

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Current vortices in aromatic carbon molecules

et al. 2020

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Yenni P. Ortiz

Microwave emulations and tight-binding calculations of transport in polyacetylene

Spontaneous symmetry breaking and strong deformations in metal adsorbed graphene sheets

Current Vortices in Aromatic Carbon Molecules

Energies for cyclic and acyclic aggregations of adamantane and diamantane units sharing vertices, edges, or six‐membered rings

Current vortices in aromatic carbon molecules

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