Neural Network Potentials: A Concise Overview of Methods

Literature Cited

1. 1. 

   book 2018. Machine Learning: An Overview of Artificial Intelligence Scotts Valley, CA: CreateSpace
2. 2. 

   Alpaydin E. 2020. Introduction to Machine Learning Cambridge, MA: MIT Press
3. 3. 

   Mater AC, Coote ML. 2019. Deep learning in chemistry. J. Chem. Inf. Model. 59:2545–59
   [Google Scholar]
4. 4. 

   Larranaga P, Calvo B, Santana R, Bielza C, Galdiano J et al. 2005. Machine learning in bioinformatics. Brief. Bioinform. 7:86–112
   [Google Scholar]
5. 5. 

   von Lilienfeld OA, Burke K. 2020. Retrospective on a decade of machine learning for chemical discovery. Nat. Commun. 11:4895
   [Google Scholar]
6. 6. 

   Mamoshina P, Vieira A, Putin E, Zhavoronkov A 2016. Applications of deep learning in biomedicine. Mol. Pharm. 13:1445–54
   [Google Scholar]
7. 7. 

   Libbrecht MW, Noble WS. 2015. Machine learning applications in genetics and genomics. Nat. Rev. Genet. 16:6321–32
   [Google Scholar]
8. 8. 

   Selvaratnam B, Koodali RT. 2021. Machine learning in experimental materials chemistry. Catal. Today 371:77–84
   [Google Scholar]
9. 9. 

   Agrawal A, Choudhary A. 2016. Perspective: materials informatics and big data: realization of the “fourth paradigm” of science in materials science. APL Mater 4:053208
   [Google Scholar]
10. 10. 

    Handley CM, Popelier PLA. 2010. Potential energy surfaces fitted by artificial neural networks. J. Phys. Chem. A 114:3371–83
    [Google Scholar]
11. 11. 

    Behler J. 2011. Neural network potential-energy surfaces in chemistry: a tool for large-scale simulations. Phys. Chem. Chem. Phys. 13:17930–55
    [Google Scholar]
12. 12. 

    Behler J. 2016. Perspective: machine learning potentials for atomistic simulations. J. Chem. Phys. 145:170901
    [Google Scholar]
13. 13. 

    Dral PO. 2020. Quantum chemistry in the age of machine learning. J. Phys. Chem. Lett. 11:2336–47
    [Google Scholar]
14. 14. 

    Deringer VL, Caro MA, Csányi G 2019. Machine learning interatomic potentials as emerging tools for materials science. Adv. Mater. 31:1902765
    [Google Scholar]
15. 15. 

    Noé F, Tkatchenko A, Müller KR, Clementi C. 2020. Machine learning for molecular simulation. Ann. Rev. Phys. Chem. 71:361–90
    [Google Scholar]
16. 16. 

    Zubatiuk T, Isayev O. 2021. Development of multimodal machine learning potentials: toward a physics-aware artificial intelligence. Acc. Chem. Res. 54:1575–85
    [Google Scholar]
17. 17. 

    Zhang J, Lei YK, Zhang Z, Chang J, Li M et al. 2020. A perspective on deep learning for molecular modeling and simulations. J. Phys. Chem. A 124:6745–63
    [Google Scholar]
18. 18. 

    Unke OT, Chmiela S, Sauceda HE, Gastegger M, Poltavsky I et al. 2021. Machine learning force fields. Chem. Rev. 121:10142–86
    [Google Scholar]
19. 19. 

    Friederich P, Häse F, Proppe J, Aspuru-Guzik A. 2021. Machine-learned potentials for next-generation matter simulations. Nat. Mater. 20:6750–61
    [Google Scholar]
20. 20. 

    Grisafi A, Nigam J, Ceriotti M. 2021. Multi-scale approach for the prediction of atomic scale properties. Chem. Sci. 12:2078–90
    [Google Scholar]
21. 21. 

    Blank TB, Brown SD, Calhoun AW, Doren DJ 1995. Neural network models of potential energy surfaces. J. Chem. Phys. 103:104129–37
    [Google Scholar]
22. 22. 

    Lorenz S, Groß A, Scheffler M 2004. Representing high-dimensional potential-energy surfaces for reactions at surfaces by neural networks. Chem. Phys. Lett. 395:210–15
    [Google Scholar]
23. 23. 

    Behler J, Parrinello M. 2007. Generalized neural-network representation of high-dimensional potential-energy surfaces. Phys. Rev. Lett. 98:146401
    [Google Scholar]
24. 24. 

    Schütt KT, Sauceda HE, Kindermans PJ, Tkatchenko A, Müller KR 2018. SchNet—a deep learning architecture for molecules and materials. J. Chem. Phys. 148:241722
    [Google Scholar]
25. 25. 

    Unke OT, Meuwly M. 2019. PhysNet: a neural network for predicting energies, forces, dipole moments, and partial charges. J. Chem. Theory Comput. 15:3678–93
    [Google Scholar]
26. 26. 

    Bartók AP, Payne MC, Kondor R, Csányi G 2010. Gaussian approximation potentials: the accuracy of quantum mechanics, without the electrons. Phys. Rev. Lett. 104:136403
    [Google Scholar]
27. 27. 

    Bartók AP, Csányi G. 2015. Gaussian approximation potentials: a brief tutorial introduction. Int. J. Quant. Chem. 115:1051–57
    [Google Scholar]
28. 28. 

    Chmiela S, Sauceda HE, Poltavsky I, Müller KR, Tkatchenko A. 2019. sGDML: constructing accurate and data efficient molecular force fields using machine learning. Comput. Phys. Commun. 240:38–45
    [Google Scholar]
29. 29. 

    Thompson AP, Swiler LP, Trott CR, Foiles SM, Tucker GJ. 2015. Spectral neighbor analysis method for automated generation of quantum-accurate interatomic potentials. J. Comput. Phys. 285:316–30
    [Google Scholar]
30. 30. 

    Wood MA, Thompson AP. 2018. Extending the accuracy of the SNAP interatomic potential form. J. Chem. Phys. 148:241721
    [Google Scholar]
31. 31. 

    Shapeev AV. 2016. Moment tensor potentials: a class of systematically improvable interatomic potentials. Multiscale Model. Simul. 14:1153–73
    [Google Scholar]
32. 32. 

    Drautz R. 2019. Atomic cluster expansion for accurate and transferable interatomic potentials. Phys. Rev. B 99:014104
    [Google Scholar]
33. 33. 

    Allen A, Dusson G, Ortner C, Csanyi G. 2021. Atomic permutationally invariant polynomials for fitting molecular force fields. Mach. Learn. Sci. Techn. 2:025017
    [Google Scholar]
34. 34. 

    Balabin RM, Lomakina EI. 2011. Support vector machine regression (LS-SVM)—an alternative to artificial neural networks (ANNs) for the analysis of quantum chemistry data?. Phys. Chem. Chem. Phys. 13:11710
    [Google Scholar]
35. 35. 

    Cybenko G. 1989. Approximation by superpositions of a sigmoidal function. Math. Control Signals Syst. 2:303–14
    [Google Scholar]
36. 36. 

    Ko TW, Finkler JA, Goedecker S, Behler J. 2021. General-purpose machine learning potentials capturing nonlocal charge transfer. Acc. Chem. Res. 54:808–17
    [Google Scholar]
37. 37. 

    Behler J. 2021. Four generations of high-dimensional neural network potentials. Chem. Rev. 121:10037–72
    [Google Scholar]
38. 38. 

    Ko TW, Finkler JA, Goedecker S, Behler J 2021. A fourth-generation high-dimensional neural network potential with accurate electrostatics including non-local charge transfer. Nat. Commun. 12:398
    [Google Scholar]
39. 39. 

    Rupp M, Tkatchenko A, Müller KR, von Lilienfeld OA 2012. Fast and accurate modeling of molecular atomization energies with machine learning. Phys. Rev. Lett. 108:058301
    [Google Scholar]
40. 40. 

    Zeng M, Kumar JN, Zeng Z, Savitha R, Chandrasekhar VR, Hippalgaonkar K. 2018. Graph convolutional neural networks for polymers property prediction. arXiv:1811.06231 [cond-mat.mtrl-sci]
41. 41. 

    Omprakash P, Manikandan B, Sandeep A, Shrivastava R, Viswesh P, Panemangalore DB. 2021. Graph representational learning for bandgap prediction in varied perovskite crystals. Comput. Mater. Sci. 196:110530
    [Google Scholar]
42. 42. 

    Miccio LA, Schwartz GA. 2020. From chemical structure to quantitative polymer properties prediction through convolutional neural networks. Polymer 193:122341
    [Google Scholar]
43. 43. 

    Behler J. 2017. First principles neural network potentials for reactive simulations of large molecular and condensed systems. Angew. Chem. Int. Ed. 56:12828
    [Google Scholar]
44. 44. 

    Brown DFR, Gibbs MN, Clary DC. 1996. Combining ab initio computations, neural networks, and diffusion Monte Carlo: an efficient method to treat weakly bound molecules. J. Chem. Phys. 105:7597
    [Google Scholar]
45. 45. 

    No KT, Chang BH, Kim SY, Jhon MS, Scheraga HA 1997. Description of the potential energy surface of the water dimer with an artificial neural network. Chem. Phys. Lett. 271:152–56
    [Google Scholar]
46. 46. 

    Bittencourt ACP, Prudente FV, Vianna JDM. 2004. The fitting of potential energy and transition moment functions using neural networks: transition probabilities in OH (A² to X²). Chem. Phys. 297:153–61
    [Google Scholar]
47. 47. 

    Lee HM, Raff LM. 2008. Cis → trans, trans → cis isomerizations and N=O bond dissociation of nitrous acid (HONO) on an ab initio potential surface obtained by novelty sampling and feed-forward neural network fitting. J. Chem. Phys. 128:194310
    [Google Scholar]
48. 48. 

    Behler J, Reuter K, Scheffler M. 2008. Nonadiabatic effects in the dissociation of oxygen molecules at the Al(111) surface. Phys. Rev. B 77:115421
    [Google Scholar]
49. 49. 

    Goikoetxea I, Beltrán J, Meyer J, Juaristi JI, Alducin M, Reuter K 2012. Non-adiabatic effects during the dissociative adsorption of O₂ at Ag(111)? A first-principles divide and conquer study. New J. Phys. 14:013050
    [Google Scholar]
50. 50. 

    Manzhos S, Yamashita K 2010. A model for the dissociative adsorption of N₂O on Cu(100) using a continuous potential energy surface. Surf. Sci. 604:554–60
    [Google Scholar]
51. 51. 

    Cho KW, No KT, Scheraga HA. 2002. A polarizable force field for water using an artificial neural network. J. Mol. Struct. 641:77–91
    [Google Scholar]
52. 52. 

    Gassner H, Probst M, Lauenstein A, Hermansson K 1998. Representation of intermolecular potential functions by neural networks. J. Phys. Chem. A 102:4596–605
    [Google Scholar]
53. 53. 

    Hobday S, Smith R, Belbruno J 1999. Applications of neural networks to fitting interatomic potential functions. Model. Simul. Mater. Sci. Eng. 7:397–412
    [Google Scholar]
54. 54. 

    Manzhos S, Carrington T Jr. 2006. Using neural networks to represent potential surfaces as sums of products. J. Chem. Phys. 125:194105
    [Google Scholar]
55. 55. 

    Manzhos S, Carrington T Jr. 2007. Using redundant coordinates to represent potential energy surfaces with lower-dimensional functions. J. Chem. Phys. 127:014103
    [Google Scholar]
56. 56. 

    Manzhos S, Carrington T Jr. 2008. Using neural networks, optimized coordinates, and high-dimensional model representations to obtain a vinyl bromide potential surface. J. Chem. Phys. 129:224104
    [Google Scholar]
57. 57. 

    Malshe M, Narulkar R, Raff LM, Hagan M, Bukkapatnam S et al. 2009. Development of generalized potential-energy surfaces using many-body expansions, neural networks, and moiety energy approximations. J. Chem. Phys. 130:184102
    [Google Scholar]
58. 58. 

    Brown A, Braams BJ, Christoffel K, Jin Z, Bowman JM 2003. Classical and quasiclassical spectral analysis of using an ab initio potential energy surface. J. Chem. Phys. 119:8790
    [Google Scholar]
59. 59. 

    Braams BJ, Bowman JM. 2009. Permutationally invariant potential energy surfaces in high dimensionality. Int. Rev. Phys. Chem. 28:577–606
    [Google Scholar]
60. 60. 

    Jiang B, Guo H. 2013. Permutation invariant polynomial neural network approach to fitting potential energy surfaces. J. Chem. Phys. 139:054112
    [Google Scholar]
61. 61. 

    Li J, Jiang B, Guo H. 2013. Permutation invariant polynomial neural network approach to fitting potential energy surfaces. II. Four-atom systems. J. Chem. Phys. 139:204103
    [Google Scholar]
62. 62. 

    Behler J, Lorenz S, Reuter K. 2007. Representing molecule-surface interactions with symmetry-adapted neural networks. J. Chem. Phys. 127:014705
    [Google Scholar]
63. 63. 

    Langer MF, Goessmann A, Rupp M 2020. Representations of molecules and materials for interpolation of quantum-mechanical simulations via machine learning. arXiv:2003.12081 [physics.comp-ph]
64. 64. 

    Himanen L, Jägera MOJ, Morooka EV, Canova FF, Ranawat YS et al. 2020. DScribe: library of descriptors for machine learning in materials science. Comput. Phys. Commun. 247:106949
    [Google Scholar]
65. 65. 

    Gastegger M, Schwiedrzik L, Bittermann M, Berzsenyi F, Marquetand P. 2018. WACSF—weighted atom-centered symmetry functions as descriptors in machine learning potentials. J. Chem. Phys. 148:241709
    [Google Scholar]
66. 66. 

    Zhang Y, Hu C, Jiang B. 2019. Embedded atom neural network potentials: efficient and accurate machine learning with a physically inspired representation. J. Phys. Chem. Lett. 10:4962–67
    [Google Scholar]
67. 67. 

    Behler J. 2011. Atom-centered symmetry functions for constructing high-dimensional neural network potentials. J. Chem. Phys. 134:074106
    [Google Scholar]
68. 68. 

    Behler J. 2015. Constructing high-dimensional neural network potentials: a tutorial review. Int. J. Quantum Chem. 115:1032–50
    [Google Scholar]
69. 69. 

    Singraber A, Morawietz T, Behler J, Dellago C. 2019. Parallel multi-stream training of high-dimensional neural network potentials. J. Chem. Theory Comput. 15:3075–92
    [Google Scholar]
70. 70. 

    Khorshidi A, Peterson AA. 2016. Amp: a modular approach to machine learning in atomistic simulations. Comput. Phys. Commun. 207:310–24
    [Google Scholar]
71. 71. 

    Smith JS, Isayev O, Roitberg AE. 2017. ANI-1: an extensible neural network potential with DFT accuracy at force field computational cost. Chem. Sci. 8:3192–203
    [Google Scholar]
72. 72. 

    Liu M, Kitchin JR. 2020. SingleNN: a modified Behler-Parrinello neural network with shared weights for atomistic simulations with transferability. J. Phys. Chem. C 124:17811–18
    [Google Scholar]
73. 73. 

    Profitt TA, Pearson JK. 2019. A shared-weight neural network architecture for predicting molecular properties. Phys. Chem. Chem. Phys. 21:26175
    [Google Scholar]
74. 74. 

    Imbalzano G, Anelli A, Giofre D, Klees S, Behler J, Ceriotti M. 2018. Automatic selection of atomic fingerprints and reference configurations for machine-learning potentials. J. Chem. Phys. 148:241730
    [Google Scholar]
75. 75. 

    Mahoney MW, Drineas P. 2009. CUR matrix decompositions for improved data analysis. PNAS 106:697–702
    [Google Scholar]
76. 76. 

    Selvaratnam B, Koodali RT, Miro P. 2020. Application of symmetry functions to large chemical spaces using a convolutional neural network. J. Chem. Inf. Model. 160:1928–35
    [Google Scholar]
77. 77. 

    Jovan Jose KV, Artrith N, Behler J 2012. Construction of high-dimensional neural network potentials using environment-dependent atom pairs. J. Chem. Phys. 136:194111
    [Google Scholar]
78. 78. 

    Yao K, Herr JE, Brown SN, Parkhill J. 2017. Intrinsic bond energies from a bonds-in-molecules neural network. J. Phys. Chem. Lett. 8:2689–94
    [Google Scholar]
79. 79. 

    Hansen K, Biegler F, Ramakrishnan R, Pronobis W, von Lilienfeld OA et al. 2015. Machine learning predictions of molecular properties: accurate many-body potentials and nonlocality in chemical space. J. Phys. Chem. Lett. 6:2326–31
    [Google Scholar]
80. 80. 

    Glick ZL, Metcalf DP, Koutsoukas A, Spronk SA, Cheney DL, Sherrill CD. 2020. AP-Net: an atomic-pairwise neural network for smooth and transferable interaction potentials. J. Chem. Phys. 153:044112
    [Google Scholar]
81. 81. 

    Zhang L, Han J, Wang H, Car R, E W 2018. Deep potential molecular dynamics: a scalable model with the accuracy of quantum mechanics. Phys. Rev. Lett. 120:143001
    [Google Scholar]
82. 82. 

    Han J, Zhang L, Car R, E W 2018. Deep potential: a general representation of a many-body potential energy surface. Commun. Comput. Phys. 23:629–39
    [Google Scholar]
83. 83. 

    Zhang L, Han J, Wang H, Saidi WA, Car R, E W 2018. End-to-end symmetry preserving inter-atomic potential energy model for finite and extended systems. Proceedings of the 32nd International Conference on Neural Information Processing Systems S Bengio, HM Wallach, H Larochelle, K Grauman, N Cesa-Bianchi 4441–51 New York: ACM
84. 84. 

    Daw M, Foiles S, Baskes M 1993. The embedded-atom method: a review of theory and applications. Mater. Sci. Rep. 9:251
    [Google Scholar]
85. 85. 

    Duvenaud D, Maclaurin D, Aguilera-Iparraguirre J, Gomez-Bombarelli R, Hirzel T et al. 2015. Convolutional networks on graphs for learning molecular fingerprints. Proceedings of the 28th International Conference on Neural Information Processing Systems C Cortes, DD Lee, M Sugiyama, R Garnett 2224–32 New York: ACM
86. 86. 

    Rogers D, Hahn M. 2010. Extended-connectivity fingerprints. J. Chem. Inf. Model. 50:742–54
    [Google Scholar]
87. 87. 

    Gilmer J, Schoenholz SS, Riley PF, Vinyals O, Dahl GE. 2017. Neural message passing for quantum chemistry. Proceedings of the 34th International Conference on Machine Learning1263–72 Sydney, Aust: JMLR
88. 88. 

    Schütt KT, Arbabzadah F, Chmiela S, Müller KR, Tkatchenko A. 2017. Quantum-chemical insights from deep tensor neural networks. Nat. Commun. 8:13890
    [Google Scholar]
89. 89. 

    Schütt K, Kindermans PJ, Felix HES, Chmiela S, Tkatchenko A, Müller KR 2017. SchNet: a continuous-filter convolutional neural network for modeling quantum interactions. Proceedings of the 28th International Conference on Neural Information Processing Systems U von Luxburg, I Guyon, S Bengio, H Wallach, R Fergus 992–1002 New York: ACM
90. 90. 

    Lubbers N, Smith JS, Barros K. 2018. Hierarchical modeling of molecular energies using a deep neural network. J. Chem. Phys. 148:241715
    [Google Scholar]
91. 91. 

    Zubatyuk R, Smith JS, Leszczynski J, Isayev O 2019. Accurate and transferable multitask prediction of chemical properties with an atoms-in-molecules neural network. Sci. Adv. 5:eaav6490
    [Google Scholar]
92. 92. 

    Kronik L, Tkatchenko A. 2014. Understanding molecular crystals with dispersion-inclusive density functional theory: pairwise corrections and beyond. Acc. Chem. Res. 47:3208–16
    [Google Scholar]
93. 93. 

    Houlding S, Liem SY, Popelier PLA. 2007. A polarizable high-rank quantum topological electrostatic potential developed using neural networks: molecular dynamics simulations on the hydrogen fluoride dimer. Int. J. Quantum Chem. 107:2817–27
    [Google Scholar]
94. 94. 

    Handley CM, Popelier PLA. 2009. Dynamically polarizable water potential based on multipole moments trained by machine learning. J. Chem. Theory Comput. 5:1474–89
    [Google Scholar]
95. 95. 

    Nebgen B, Lubbers N, Smith JS, Sifain A, Lokhov A et al. 2018. Transferable dynamic molecular charge assignment using deep neural networks. J. Chem. Theory Comput. 14:4687–98
    [Google Scholar]
96. 96. 

    Gastegger M, Behler J, Marquetand P. 2017. Machine learning molecular dynamics for the simulation of infrared spectra. Chem. Sci. 8:6924
    [Google Scholar]
97. 97. 

    Zubatyuk R, Smith JS, Nebgen BT, Tretiak S, Isayev O 2021. Teaching a neural network to attach and detach electrons from molecules. Nat. Commun. 12:4870
    [Google Scholar]
98. 98. 

    Metcalf DP, Jiang A, Spronk SA, Cheney DL, Sherrill CD. 2021. Electron-passing neural networks for atomic charge prediction in systems with arbitrary molecular charge. J. Chem. Inf. Model. 61:115–22
    [Google Scholar]
99. 99. 

    Cuevas-Zuvira B, Pacios LF. 2021. Machine learning of analytical electron density in large molecules through message-passing. J. Chem. Inf. Model. 61:2658–66
    [Google Scholar]
100. 100. 

     Wang Y, Fass J, Stern CD, Luo K, Chodera J 2019. Graph nets for partial charge prediction. arXiv:1909.07903 [physics.comp-ph]
101. 101. 

     Wang J, Cao D, Tang C, Xu L, He Q et al. 2021. DeepAtomicCharge: a new graph convolutional network-based architecture for accurate prediction of atomic charges. Brief. Bioinform. 22:3bbaa183
     [Google Scholar]
102. 102. 

     Artrith N, Morawietz T, Behler J. 2011. High-dimensional neural-network potentials for multicomponent systems: applications to zinc oxide. Phys. Rev. B 83:153101
     [Google Scholar]
103. 103. 

     Morawietz T, Sharma V, Behler J. 2012. A neural network potential-energy surface for the water dimer based on environment-dependent atomic energies and charges. J. Chem. Phys. 136:064103
     [Google Scholar]
104. 104. 

     Ewald PP. 1921. Die Berechnung optischer und elektrostatischer Gitterpotentiale. Ann. Phys. 64:253–87
     [Google Scholar]
105. 105. 

     Grimme S. 2006. Semiempirical GGA-type density functional constructed with a long-range dispersion correction. J. Comput. Chem. 27:151787–99
     [Google Scholar]
106. 106. 

     Yao K, Herr JE, Toth DW, Mckintyre R, Parkhill J 2018. The TensorMol-0.1 model chemistry: a neural network augmented with long-range physics. Chem. Sci. 9:2261–69
     [Google Scholar]
107. 107. 

     Ghasemi SA, Hofstetter A, Saha S, Goedecker S. 2015. Interatomic potentials for ionic systems with density functional accuracy based on charge densities obtained by a neural network. Phys. Rev. B 92:045131
     [Google Scholar]
108. 108. 

     Xie X, Persson KA, Small DW. 2020. Incorporating electronic information into machine learning potential energy surfaces via approaching the ground-state electronic energy as a function of atom-based electronic populations. J. Chem. Theory Comput. 16:4256–70
     [Google Scholar]
109. 109. 

     Rappe AK, Goddard WA III. 1991. Charge equilibration for molecular dynamics simulations. J. Phys. Chem. 95:3358
     [Google Scholar]
110. 110. 

     Bartók AP, Kondor R, Csányi G. 2013. On representing chemical environments. Phys. Rev. B 87:184115
     [Google Scholar]
111. 111. 

     Kaduk B, Kowalczyk T, Voorhis TV. 2011. Constrained density functional theory. Chem. Rev. 112:321–70
     [Google Scholar]
112. 112. 

     Devereux C, Smith JS, Huddleston KK, Barros K, Zubatyuk R et al. 2020. Extending the applicability of the ANI deep learning molecular potential to sulfur and halogens. J. Chem. Theory Comput. 16:4192–202
     [Google Scholar]
113. 113. 

     Seung HS, Opper M, Sompolinsky H. 1992. Query by committee. Proceedings of the 5th Annual Workshop on Computational Learning Theory287–94 New York: ACM
114. 114. 

     Artrith N, Behler J. 2012. High-dimensional neural network potentials for metal surfaces: a prototype study for copper. Phys. Rev. B 85:045439
     [Google Scholar]
115. 115. 

     Podryabinkin EV, Shapeev AV. 2017. Active learning of linearly parametrized interatomic potentials. Comput. Mater. Sci. 140:171–80
     [Google Scholar]
116. 116. 

     Loeffler TD, Manna S, Patra TK, Chan H, Narayanan B, Sankaranarayanan S. 2020. Active learning a neural network model for gold clusters & bulk from sparse first principles training data. ChemCatChem 12:4796–806
     [Google Scholar]
117. 117. 

     Zhang L, Lin DY, Wang H, Car R, E W 2019. Active learning of uniformly accurate interatomic potentials for materials simulation. Phys. Rev. Mater. 3:023804
     [Google Scholar]
118. 118. 

     Sivaraman G, Krishnamoorthy AN, Baur M, Holm C, Stan M et al. 2020. Machine-learned interatomic potentials by active learning: amorphous and liquid hafnium dioxide. NPJ Comput. Mater. 6:104
     [Google Scholar]
119. 119. 

     Smith JS, Nebgen B, Lubbers N, Isayev O, Roitberg AE. 2018. Less is more: sampling chemical space with active learning. J. Chem. Phys. 148:241733
     [Google Scholar]
120. 120. 

     Schran C, Behler J, Marx D. 2020. Automated fitting of neural network potentials at coupled cluster accuracy: protonated water clusters as testing ground. J. Chem. Theory Comput. 16:88–99
     [Google Scholar]
121. 121. 

     Lin Q, Zhang L, Zhang Y, Jiang B. 2021. Searching configurations in uncertainty space: active learning of high-dimensional neural network reactive potentials. J. Chem. Theory Comput. 17:2691–701
     [Google Scholar]
122. 122. 

     Bernstein N, Csányi G, Deringer VL 2019. De novo exploration and self-guided learning of potential-energy surfaces. NPJ Comput. Mater. 5:99
     [Google Scholar]
123. 123. 

     Sun G, Sautet P. 2019. Toward fast and reliable potential energy surfaces for metallic Pt clusters by hierarchical delta neural networks. J. Chem. Theory Comput. 15:105614–27
     [Google Scholar]
124. 124. 

     Ramakrishnan R, Dral PO, Rupp M, von Lilienfeld OA 2015. Big data meets quantum chemistry approximations: the delta-machine learning approach. J. Chem. Theory Comput. 11:2087–96
     [Google Scholar]
125. 125. 

     Dral PO, Owens A, Dral A, Csányi G. 2020. Hierarchical machine learning of potential energy surfaces. J. Chem. Phys. 152:204110
     [Google Scholar]
126. 126. 

     Unke OT, Chmiela S, Gastegger M, Schütt KT, Sauceda HE, Müller KR. 2021. SpookyNet: learning force fields with electronic degrees of freedom and nonlocal effects. arXiv:2105.00304 [physics.chem-ph]
127. 127. 

     Eckhoff M, Behler J. 2021. High-dimensional neural network potentials for magnetic systems using spin-dependent atom-centered symmetry functions. arXiv:2104.14439 [physics.comp-ph]
128. 128. 

     Gastegger M, Schütt KT, Müller KR. 2020. Machine learning of solvent effects on molecular spectra and reactions. arxiv:2010.14942 [physics.chem-ph]
129. 129. 

     Li H, Collins C, Tanha M, Gordon GJ, Yaron DJ 2018. A density functional tight binding layer for deep learning of chemical Hamiltonians. J. Chem. Theory Comput. 14:5764–76
     [Google Scholar]
130. 130. 

     Zubatyuk T, Nebgen B, Lubbers N, Smith JS, Zubatyuk R et al. 2019. Machine learned Hückel theory: interfacing physics and deep neural networks. arXiv:1909.12963v1 [cond-mat.dis-nn]
131. 131. 

     Qiao Z, Welborn M, Anandkumar A, Manby FR, Miller TF III. 2020. OrbNet: deep learning for quantum chemistry using symmetry-adapted atomic-orbital features. J. Chem. Phys. 153:124111
     [Google Scholar]
132. 132. 

     Pfau D, Spencer JS, Matthews AGDG, Foulkes WMC. 2020. Ab initio solution of the many-electron Schrödinger equation with deep neural networks. Phys. Rev. Res. 2:033429
     [Google Scholar]
133. 133. 

     Hermann J, Schätzle Z, Noé F. 2020. Deep-neural-network solution of the electronic Schrödinger equation. Nat. Chem. 12:891–97
     [Google Scholar]