The joint automated repository for various integrated simulations (JARVIS) for data-driven materials design

Choudhary, Kamal; Garrity, Kevin F.; Reid, Andrew; DeCost, Brian; Biacchi, Adam J.; Walker, Angela R. Hight; Trautt, Zachary; Hattrick‐Simpers, Jason; Kusne, A. Gilad; Centrone, Andrea; Davydov, Albert V.; Jiang, Jie; Pachter, Ruth; Cheon, Gowoon; Reed, Evan J.; Agrawal, Ankit; Qian, Xiaofeng; Sharma, Vinit; Zhuang, Houlong; Kalinin, Sergei V.; Sumpter, Bobby G.; Pilania, Ghanshyam; Acar, Pınar; Mandal, Subhasish; Haule, Kristjan; Vanderbilt, David; Rabe, Karin M.; Tavazza, Francesca

doi:10.1038/s41524-020-00440-1

Cited by 242 publications

(182 citation statements)

References 68 publications

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“…STM imaging is particularly well-suited to studying two-dimensional (2D) materials, such as graphene 16 , MoS 2 17 , NbSe 2 18 , WSe 2 19 , WTe 2 20 , FeSe 21 , black-phosphrous 22 , 23 and SnSe 24 . 2D materials 25 , 26 has opened diverse areas of application, such as sub-micron level electronics 27 , flexible and tunable electronics 28 , superconductivity 29 , photo-voltaics 30 , water-purification 31 , sensors 32 , thermal-management 33 , energy-storage 34 , medicine 35 , quantum dots 36 , 37 and composites 38 – 40 . The surfaces of 2D materials are unique because they lack dangling bonds, allowing them to be exfoliated.…”

Section: Background and Summarymentioning

confidence: 99%

“…We use the recently developed JARVIS-DFT database ( https://jarvis.nist.gov/jarvisdft ) and select 2D materials with exfoliation energy less than 200 meV/atom. The JARVIS-DFT database contains about 40000 bulk and 1000 two-dimensional materials with their DFT-computed structural, energetic 26 , elastic 41 , optoelectronic 42 , thermoelectric 43 , piezoelectric, dielectric, infrared 44 , solar-efficiency 45 , and topological 46 , 47 properties. We note that there are several factors that can influence the appearance of experimental or DFT-based STM image predictions, such as the STM-tip material, bias voltage, and the scanning mode, i.e .…”

Section: Background and Summarymentioning

confidence: 99%

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Computational scanning tunneling microscope image database

et al. 2021

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We introduce the systematic database of scanning tunneling microscope (STM) images obtained using density functional theory (DFT) for two-dimensional (2D) materials, calculated using the Tersoff-Hamann method. It currently contains data for 716 exfoliable 2D materials. Examples of the five possible Bravais lattice types for 2D materials and their Fourier-transforms are discussed. All the computational STM images generated in this work are made available on the JARVIS-STM website (https://jarvis.nist.gov/jarvisstm). We find excellent qualitative agreement between the computational and experimental STM images for selected materials. As a first example application of this database, we train a convolution neural network model to identify the Bravais lattice from the STM images. We believe the model can aid high-throughput experimental data analysis. These computational STM images can directly aid the identification of phases, analyzing defects and lattice-distortions in experimental STM images, as well as be incorporated in the autonomous experiment workflows.

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Section: Background and Summarymentioning

confidence: 99%

Section: Background and Summarymentioning

confidence: 99%

Computational scanning tunneling microscope image database

et al. 2021

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“…Since its launch in 2011, the Materials Genome Initiative (MGI) 33 has spurred the generation of several high-throughput databases and tools such as from AFLOW 34 , Materials Project 35 , Open Quantum Materials Database (OQMD) 36 , Materials Cloud 37 , AiiDA 38 , NOMAD 39 , and NIST-JARVIS 40 . They have played key roles in the generation of electronic-property related databases to reduce the time between materials discovery and application.…”

Section: Background and Summarymentioning

confidence: 99%

“…We use our Wannierization workflow on the JARVIS-DFT ( https://jarvis.nist.gov/jarvisdft ) database which is a part of the MGI at NIST. The NIST-JARVIS 40 ( https://jarvis.nist.gov ) has several components such as JARVIS-FF 47 , 48 , JARVIS-DFT 48 – 57 , JARVIS-ML 49 , 51 , 57 – 59 , JARVIS-STM 51 , JARVIS-Heterostructure 53 and hosts material-properties such as lattice parameters 50 , formation energies 60 , 2D exfoliation energies 55 , bandgaps, elastic constants 50 , dielectric constants 59 , infrared intensities 59 , piezoelectric constants 59 , thermoelectric properties 57 , optoelectronic properties, solar-cell efficiencies 47 , 49 , topological materials 17 , 21 , electric field gradient 61 , and computational STM images 51 . The JARVIS-DFT database consists of ≈ 40000 3D and ≈1000 2D materials.…”

Section: Background and Summarymentioning

confidence: 99%

Database of Wannier tight-binding Hamiltonians using high-throughput density functional theory

Garrity

Choudhary

2021

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Wannier tight-binding Hamiltonians (WTBH) provide a computationally efficient way to predict electronic properties of materials. In this work, we develop a computational workflow for high-throughput Wannierization of density functional theory (DFT) based electronic band structure calculations. We apply this workflow to 1771 materials (1406 3D and 365 2D), and we create a database with the resulting WTBHs. We evaluate the accuracy of the WTBHs by comparing the Wannier band structures to directly calculated spin-orbit coupling DFT band structures. Our testing includes k-points outside the grid used in the Wannierization, providing an out-of-sample test of accuracy. We illustrate the use of WTBHs with a few example applications. We also develop a web-app that can be used to predict electronic properties on-the-fly using WTBH from our database. The tools to generate the Hamiltonian and the database of the WTB parameters are made publicly available through the websites https://github.com/usnistgov/jarvis and https://jarvis.nist.gov/jarviswtb.

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“…4,5 The upsurge of interest in these materials has motivated many computational high-throughput searches. This has resulted in the generation of several databases, [6][7][8][9][10][11] with a great amount of prospective 2D materials with energetically favorable phases. In some of them, interlayer van der Waals interactions imply that they might be obtained by exfoliation.…”

Section: Introductionmentioning

confidence: 99%