1
Transferability in interatomic potentials for carbon
2
Machine Learning Interatomic Potentials as Emerging Tools for Materials Science
3
FCHL revisited: Faster and more accurate quantum machine learning.
4
First-principles study of alkali-metal intercalation in disordered carbon anode materials
5
Recent progress on carbon nanomaterials for the electrochemical detection and removal of environmental pollutants.
6
Hard carbons for sodium-ion batteries: Structure, analysis, sustainability, and electrochemistry
7
Data-driven learning and prediction of inorganic crystal structures.
8
Computational Surface Chemistry of Tetrahedral Amorphous Carbon by Combining Machine Learning and Density Functional Theory
9
Reactivity of Amorphous Carbon Surfaces: Rationalizing the Role of Structural Motifs in Functionalization Using Machine Learning
10
A Data-Driven Construction of the Periodic Table of the Elements
11
Graphitization of Glassy Carbon after Compression at Room Temperature.
12
Towards an atomistic understanding of disordered carbon electrode materials
13
Machine Learning a General-Purpose Interatomic Potential for Silicon
14
Growth Mechanism and Origin of High sp^{3} Content in Tetrahedral Amorphous Carbon.
15
Recognizing Local and Global Structural Motifs at the Atomic Scale.
16
Alchemical and structural distribution based representation for universal quantum machine learning.
17
SchNet - A deep learning architecture for molecules and materials.
18
Gaussian approximation potential modeling of lithium intercalation in carbon nanostructures.
19
Carbon Nanotubes as Optical Sensors in Biomedicine.
20
Data-Driven Learning of Total and Local Energies in Elemental Boron.
21
Development of a machine learning potential for graphene
22
A universal strategy for the creation of machine learning-based atomistic force fields
23
Achieving DFT accuracy with a machine-learning interatomic potential: thermomechanics and defects in bcc ferromagnetic iron
25
Extracting Crystal Chemistry from Amorphous Carbon Structures
26
High-Dimensional Atomistic Neural Network Potentials for Molecule-Surface Interactions: HCl Scattering from Au(111).
27
Machine learning based interatomic potential for amorphous carbon
28
Accurate interatomic force fields via machine learning with covariant kernels
29
Graphitization of amorphous carbons: A comparative study of interatomic potentials
30
Perspective: Machine learning potentials for atomistic simulations.
31
Machine learning scheme for fast extraction of chemically interpretable interatomic potentials
32
Homo Citans and Carbon Allotropes: For an Ethics of Citation
33
Reconstruction of low-index graphite surfaces
34
The applications of carbon nanotubes and graphene in advanced rechargeable lithium batteries
35
Inscription of 3D waveguides in diamond using an ultrafast laser
36
Perspective: Role of structure prediction in materials discovery and design
37
Recent development of carbon electrode materials and their bioanalytical and environmental applications.
38
Comparing molecules and solids across structural and alchemical space.
39
On-Chip Diamond Raman Laser
40
First principles phonon calculations in materials science
41
Recent advancement of nanostructured carbon for energy applications.
42
Energetics of atomic scale structure changes in graphene.
43
Carbon nanotube catalysts: recent advances in synthesis, characterization and applications.
44
Optical, Electrical, and Electromechanical Properties of Hybrid Graphene/Carbon Nanotube Films
45
Development of a ReaxFF potential for carbon condensed phases and its application to the thermal fragmentation of a large fullerene.
46
AIREBO-M: a reactive model for hydrocarbons at extreme pressures.
47
Accuracy and transferability of Gaussian approximation potential models for tungsten
48
Next generation interatomic potentials for condensed systems
49
Guide Through the Nanocarbon Jungle
50
Machine-learning approach for one- and two-body corrections to density functional theory: Applications to molecular and condensed water
51
Transport properties for liquid silicon-oxygen-iron mixtures at Earth's core conditions
52
On representing chemical environments
53
Improved description of soft layered materials with van der Waals density functional theory
54
Thermodynamically stable phases of carbon at multiterapascal pressures.
55
Neural network potential-energy surfaces in chemistry: a tool for large-scale simulations.
56
Stone-Wales-type transformations in carbon nanostructures driven by electron irradiation
57
Predicted pressure-induced s-band ferromagnetism in alkali metals.
58
Atom-centered symmetry functions for constructing high-dimensional neural network potentials.
59
Van der Waals density functionals applied to solids
60
Ab initio random structure searching
61
Nucleation mechanism for the direct graphite-to-diamond phase transition.
62
Graphene Photonics and Optoelectroncs
63
Higher-accuracy van der Waals density functional
64
Graphite-diamond phase coexistence study employing a neural-network mapping of the ab initio potential energy surface
65
Gaussian approximation potentials: the accuracy of quantum mechanics, without the electrons.
66
Stone-Wales defects in graphene and other planar sp(2)-bonded materials
67
Graphene: Status and Prospects
68
Self-assembly of sp2-bonded carbon nanostructures from amorphous precursors
69
Describing bond-breaking processes by reactive potentials: Importance of an environment-dependent interaction range
70
Measurement of the Elastic Properties and Intrinsic Strength of Monolayer Graphene
71
Ultrafast transformation of graphite to diamond: an ab initio study of graphite under shock compression.
72
Carbon-based electronics.
73
The electronic properties of graphene
74
Generalized neural-network representation of high-dimensional potential-energy surfaces.
75
Diamond surfaces: familiar and amazing
76
Structural relaxation made simple.
77
Nucleation of diamond from liquid carbon under extreme pressures : Atomistic simulation
78
Density functional study of graphite bulk and surface properties
79
Carbon under extreme conditions: Phase boundaries and electronic properties from first-principles theory
80
Improved long-range reactive bond-order potential for carbon. II. Molecular simulation of liquid carbon
81
Improved long-range reactive bond-order potential for carbon. I. Construction (Correction on vol 72, pg 214102, 2005)
82
Defect energies of graphite: Density-functional calculations
83
New Perspectives on the Structure of Graphitic Carbons
84
Energy Landscapes: With Applications to Clusters, Biomolecules and Glasses
85
Nanostructured materials for advanced energy conversion and storage devices
86
Electric Field Effect in Atomically Thin Carbon Films
87
van der Waals density functional for general geometries.
88
Intrinsic long-range bond-order potential for carbon: Performance in Monte Carlo simulations of graphitization
89
Ab initio study of rearrangements between C60 fullerenes
90
A comparative study of interatomic potentials for copper and aluminum gas phase sputter atom transport simulations
91
Improving the convergence of defect calculations in supercells - an ab initio study of the neutral silicon vacancy
92
Defects in carbon nanotubes.
93
Generalizing the environment-dependent interaction potential for carbon
94
A reactive potential for hydrocarbons with intermolecular interactions
95
Identification of the neutral carbon [100]-split interstitial in diamond
96
Global optimization of clusters, crystals, and biomolecules.
97
From ultrasoft pseudopotentials to the projector augmented-wave method
98
Ab initio molecular-dynamics studies of the graphitization of flat and stepped diamond (111) surfaces
99
Ab initio calculations of the atomic and electronic structure of diamond (111) surfaces with steps
100
Structure of non-graphitising carbons
101
High-resolution electron microscopy studies of non-graphitizing carbons
102
Ab initio calculations of the atomic and electronic structure of clean and hydrogenated diamond (110) surfaces
103
Efficient iterative schemes for ab initio total-energy calculations using a plane-wave basis set.
104
Efficiency of ab-initio total energy calculations for metals and semiconductors using a plane-wave basis set
105
Fast parallel algorithms for short-range molecular dynamics
106
Kolmogorov's theorem and multilayer neural networks
107
Empirical potential for hydrocarbons for use in simulating the chemical vapor deposition of diamond films.
108
Empirical interatomic potential for carbon, with application to amorphous carbon.
109
Closed-shell structures and the building game
110
Theoretical studies of icosahedral C60 and some related species
111
C60: Buckminsterfullerene
112
Phase transition and shock-compression parameters to 120 GPa for three types of graphite and for amorphous carbon
113
SPECIAL POINTS FOR BRILLOUIN-ZONE INTEGRATIONS
114
Crystallization of Diamond and Graphite
115
Structural defects in graphene
116
Supplementary Materials for Machine learning unifies the modeling of materials and molecules
117
Anisotropic mechanical amorphization drives wear in diamond.
118
From the Cover: Simplifying the representation of complex free-energy landscapes using sketch-map.
119
FAST TRACK COMMUNICATION: Chemical accuracy for the van der Waals density functional
120
Energy Landscapes by David Wales
121
This is the author's peer reviewed, accepted manuscript. However, the online version of record will be different from this version once it has been copyedited and typeset
