Preferential Growth Mode of Large-Sized Vacancy Clusters in Silicon: A Neural-Network Potential and First-Principles Study

Abstract: An artificial-neural-network (ANN) interatomic potential trained with data from density-functional-theory (DFT) calculations is developed to reveal favorable modes of large-sized vacancy clusters in silicon. By varying the number of vacancies (n) up to around 103, formation energies (E f) and relaxed structures for four typical modes of vacancy clusters are examined: the 4-fold coordinated configuration (FC), hexagonal ring cluster (HRC), spherically shaped cluster (SPC), and (111)-oriented stacking fault (SF)… Show more

“…[14,15] First-principle calculations have reduced the computation time by introducing artificial NN potentials. [16][17][18][19][20] Learning pseudo-microscopic images has dramatically shortened and improved the determination of the physical properties of crystal growth. [21] Furthermore, ML has been applied to EBSD methods.…”

Prediction and Elucidation of Physical Properties of Polycrystalline Materials Using Multichannel Machine Learning of Electron Backscattering Diffraction

“…[14,15] First-principle calculations have reduced the computation time by introducing artificial NN potentials. [16][17][18][19][20] Learning pseudo-microscopic images has dramatically shortened and improved the determination of the physical properties of crystal growth. [21] Furthermore, ML has been applied to EBSD methods.…”

Prediction and Elucidation of Physical Properties of Polycrystalline Materials Using Multichannel Machine Learning of Electron Backscattering Diffraction

Atomic structures and stability of finite-size extended interstitial defects in silicon: Large-scale molecular simulations with a neural-network potential

Semantic segmentation in crystal growth process using fake micrograph machine learning