0000000001256893

AUTHOR

Oleg O. Kit

showing 5 related works from this author

Twisting graphene nanoribbons into carbon nanotubes

2011

Although carbon nanotubes consist of honeycomb carbon, they have never been fabricated from graphene directly. Here, it is shown by quantum molecular-dynamics simulations and classical continuum-elasticity modeling, that graphene nanoribbons can, indeed, be transformed into carbon nanotubes by means of twisting. The chiralities of the tubes thus fabricated can be not only predicted but also externally controlled. This twisting route is an opportunity for nanofabrication, and is easily generalizable to ribbons made of other planar nanomaterials.

Condensed Matter - Materials ScienceMaterials scienceCondensed Matter - Mesoscale and Nanoscale Physicsta114Grapheneta221Selective chemistry of single-walled nanotubeschemistry.chemical_elementPhysics::OpticsMaterials Science (cond-mat.mtrl-sci)FOS: Physical sciencesMechanical properties of carbon nanotubesNanotechnologyCarbon nanotubeCondensed Matter PhysicsElectronic Optical and Magnetic MaterialsNanomaterialslaw.inventionOptical properties of carbon nanotubeschemistrylawMesoscale and Nanoscale Physics (cond-mat.mes-hall)CarbonGraphene nanoribbonsPhysical Review B
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Efficient Approach for Simulating Distorted Materials

2010

The operation principles of nanoscale devices are based upon both electronic and mechanical properties of materials. Because these properties can be coupled, they need to be investigated simultaneously. At this moment, however, the electronic structure calculations with custom-made long-range mechanical distortions are impossible, or expensive at best. Here we present a unified formalism to solve exactly the electronic structures of nanomaterials with versatile distortions. We illustrate the formalism by investigating twisted armchair graphene nanoribbons with the least possible number of atoms. Apart from enabling versatile material distortions, the formalism is capable of reducing computa…

Condensed Matter - Materials ScienceComputer scienceScience and engineeringMaterials Science (cond-mat.mtrl-sci)FOS: Physical sciencesGeneral Physics and AstronomyMechanical engineeringNanotechnology02 engineering and technologyElectronic structure021001 nanoscience & nanotechnology01 natural sciencesCondensed Matter - Other Condensed MatterFormalism (philosophy of mathematics)0103 physical sciences010306 general physics0210 nano-technologyMaterial propertiesGraphene nanoribbonsOther Condensed Matter (cond-mat.other)Physical Review Letters
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Approximate Modeling of Spherical Membrane

2010

Spherical symmetry is ubiquitous in nature. It's therefore unfortunate that spherical system simulations are so hard, and require complete spheres with millions of interacting particles. Here we introduce an approach to model spherical systems, using revised periodic boundary conditions adapted to spherical symmetry. Method reduces computational costs by orders of magnitude, and is applicable for both solid and liquid membranes, provided the curvature is sufficiently small. We demonstrate the method by calculating the bending and Gaussian curvature moduli of single- and multi-layer graphene. Method works with any interaction (ab initio, classical interactions), with any approach (molecular …

PhysicsCondensed Matter - Materials ScienceMonte Carlo methodMaterials Science (cond-mat.mtrl-sci)FOS: Physical sciencesCondensed Matter PhysicsCurvatureElectronic Optical and Magnetic MaterialsMolecular dynamicssymbols.namesakeClassical mechanicsMembraneGaussian curvaturesymbolsPeriodic boundary conditionsSPHERESCircular symmetry
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Revised periodic boundary conditions: Fundamentals, electrostatics, and the tight-binding approximation

2011

Many nanostructures today are low-dimensional and flimsy, and therefore get easily distorted. Distortion-induced symmetry-breaking makes conventional, translation-periodic simulations invalid, which has triggered developments for new methods. Revised periodic boundary conditions (RPBC) is a simple method that enables simulations of complex material distortions, either classically or quantum-mechanically. The mathematical details of this easy-to-implement approach, however, have not been discussed before. Therefore, in this paper we summarize the underlying theory, present the practical details of RPBC, especially related to a non-orthogonal tight-binding formulation, discuss selected featur…

PhysicsCondensed Matter - Materials Scienceta114Materials Science (cond-mat.mtrl-sci)FOS: Physical sciences02 engineering and technologyComputational Physics (physics.comp-ph)021001 nanoscience & nanotechnologyCondensed Matter PhysicsElectrostatics01 natural sciencesSoftware implementation3. Good healthElectronic Optical and Magnetic MaterialsTheoretical physicsTight bindingSimple (abstract algebra)0103 physical sciencesPeriodic boundary conditions010306 general physics0210 nano-technologyPhysics - Computational PhysicsPhysical Review B
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Generalized symmetries in nanostructure simulations

2009

symmetriaBloch's Theorematomic simulation environment (ASE)density-functional theory (DFT)simulation cellsimulointidensity-functional tight-binding (DFTB)nanotieteet
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