Graphene mechanics: I. Efficient first principles based Morse potential

Costescu, Bogdan I.; Baldus, Ilona B.; Gräter, Frauke

doi:10.1039/c3cp55340j

Cited by 12 publications

(12 citation statements)

References 39 publications

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“…We employed MD simulations to study the deformation of finite graphene sheets of circular shape under spherical AFM indenters in vacuum, during which we recorded load-displacement profiles. The calculations were performed with GROMACS 18 4.5.3 using the truncated Morse potential 12 and LAMMPS 19 version 17Feb2012 using the AIREBO potential. 13 We noticed that the energy conservation was not maintained when the GROMACS calculations were performed in single precision for the larger graphene sheets.…”

Section: Methodsmentioning

confidence: 99%

“…We perform MD simulations closely mimicking the experiment, allowing us to directly compare the results. The indenter is modeled as a sphere built from discrete atoms; we use a first principles based Morse potential as presented in part I 12 and, for a small set of simulations, the AIREBO potential 13 to allow C-C bond breaking in graphene. All molecular systems are simulated at 300 K, unlike most other studies, which only slightly displaced C atoms from their equilibrium positions to add kinetic energy.…”

Section: Introductionmentioning

confidence: 99%

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Graphene mechanics: II. Atomic stress distribution during indentation until rupture

Costescu

Gräter

2014

Phys. Chem. Chem. Phys.

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Previous Atomic Force Microscopy (AFM) experiments found single layers of defect-free graphene to rupture at unexpectedly high loads in the micronewton range. Using molecular dynamics simulations, we modeled an AFM spherical tip pressing on a circular graphene sheet and studied the stress distribution during the indentation process until rupture. We found the graphene rupture force to have no dependency on the sheet size and a very weak dependency on the indenter velocity, allowing a direct comparison to experiment. The deformation showed a non-linear elastic behavior, with a two-dimensional elastic modulus in good agreement with previous experimental and computational studies. In line with theoretical predictions for linearly elastic sheets, rupture forces of non-linearly elastic graphene are proportional to the tip radius. However, as a deviation from the theory, the atomic stress concentrates under the indenter tip more strongly than predicted and causes a high probability of bond breaking only in this area. In turn, stress levels decrease rapidly towards the edge of the sheet, most of which thus only serves the role of mechanical support for the region under the indenter. As a consequence, the high ratio between graphene sheets and sphere radii, hitherto supposed to be necessary for reliable deformation and rupture studies, could be reduced to a factor of only 5-10 without affecting the outcome. Our study suggests time-resolved analysis of forces at the atomic level as a valuable tool to predict and interpret the nano-scale response of stressed materials beyond graphene.

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Graphene mechanics: II. Atomic stress distribution during indentation until rupture

Costescu

Gräter

2014

Phys. Chem. Chem. Phys.

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“…We first consider a periodic graphene sheet with a Stone-Wales defect as a model system to compare the atomic virial and the IK stresses. The system is modeled with the force field described in [36] involving up to four-body interactions and simulated in a NVT ensemble at 300 K [23]. We compute microscopic stresses here and elsewhere in the Letter with a freely available implementation [7,37].F i g u r e1(a) highlights the fundamental features of each stress definition.…”

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confidence: 99%

Examining the Mechanical Equilibrium of Microscopic Stresses in Molecular Simulations

2015

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The microscopic stress field provides a unique connection between atomistic simulations and mechanics at the nanoscale. However, its definition remains ambiguous. Rather than a mere theoretical preoccupation, we show that this fact acutely manifests itself in local stress calculations of defective graphene, lipid bilayers, and fibrous proteins. We find that popular definitions of the microscopic stress violate the continuum statements of mechanical equilibrium, and we propose an unambiguous and physically sound definition.

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“…This problem is similar to that of the particle in a square box, though, because the quantum numbers n, m take on only finitely many values, some solutions may be discarded. For instance (8,1) lie outside of the bound state parameter range and as such should not be included as degenerate contributions.…”

Section: A Case Imentioning

confidence: 99%

“…In physical contexts the two-dimensional Morse product eigenfunctions have been used as a basis for perturbative solutions to a triatomic molecular hamiltonian [2][3][4][5][6]. Throughout physics the Morse potential is used in a variety of applications including the study of graphene [7,8], spectroscopy [9,10], Bose-Einstein condensation [11], theories of interacting electrons [12], nuclear physics [13], supersymmetric quantum mechanics [14], and molecular dynamics [15]. Coherent states for the 1D Morse potential have been studied [16], and while there is literature on defining coherent states for systems with degenerate spectra [17], and coherent states for the 2D square well have been analysed [18], so far coherent states for the 2D Morse potential have not been explicitly defined.…”

Section: Introductionmentioning

confidence: 99%

Degeneracy and coherent states of the two-dimensional Morse potential

Moran

2021

Preprint

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In this paper we construct coherent states for the two-dimensional Morse potential. We find the dependence of the spectrum on the physical parameters and use this to understand the emergence of accidental degeneracies. It is observed that, under certain conditions pertaining to the irrationality of the parameters, accidental degeneracies do not appear and as such energy levels are at most two-fold degenerate. After defining a non-degenerate spectrum and set of states for the 2D Morse potential, we construct generalised coherent states and discuss the spatial distribution of their probability densities and their uncertainty relations.

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Graphene mechanics: I. Efficient first principles based Morse potential

Cited by 12 publications

References 39 publications

Graphene mechanics: II. Atomic stress distribution during indentation until rupture

Graphene mechanics: II. Atomic stress distribution during indentation until rupture

Examining the Mechanical Equilibrium of Microscopic Stresses in Molecular Simulations

Degeneracy and coherent states of the two-dimensional Morse potential

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