A review of machine learning potentials and their applications to molecular simulation

doi:10.11949/0438-1157.20231030

Abstract

Abstract:

Molecular dynamics simulation has become an important tool for the research and development of chemical engineering processes and technologies. However, the insufficient accuracy of classical molecular dynamics simulations and the high computational cost of ab initio molecular dynamics simulations have restricted the widespread applications of molecular simulation technology. The emergence and development of machine learning technology has led to the rapid development of molecular simulation based on machine learning potentials, which offers an efficient way to achieve a greatly improved accuracy at a lower computing loading, thereby bolstering the potential of molecular simulations in practical applications. This review started by an overview of the development of machine learning potentials with emphasis on the construction methods and principles of machine learning potential models. The techniques associated with machine learning potentials including dataset construction, model training, model transfer and application were detailed. The strengths and weaknesses of different types of machine learning models were also discussed, followed by the prospects for the development and applications machine learning potentials.

Key words: machine learning potentials, molecular simulation, computational chemistry, thermodynamics

摘要：

分子动力学模拟已经成为化工过程和技术研发的重要工具，但经典分子动力学模拟的精度不足和从头计算分子动力学模拟的高昂计算成本，制约了分子模拟技术的广泛应用。机器学习技术的出现和发展使得基于机器学习势的分子模拟快速发展起来，该方法兼具速度快与准确性高的优势，将极大地加速分子模拟技术在化工中的应用。首先回顾了机器学习势的发展历程，给出了构建机器学习势模型的原则，介绍了数据集构建、模型训练和模型迁移与应用等，分析了不同类型的机器学习势的特点和局限性，最后对机器学习势的应用前景进行了展望。

关键词: 机器学习势, 分子模拟, 计算化学, 热力学

CLC Number:

TP 391.9

Dongfei LIU, Fan ZHANG, Zheng LIU, Diannan LU. A review of machine learning potentials and their applications to molecular simulation[J]. CIESC Journal, 2024, 75(4): 1241-1255.

刘东飞, 张帆, 刘铮, 卢滇楠. 机器学习势及其在分子模拟中的应用综述[J]. 化工学报, 2024, 75(4): 1241-1255.

Figures/Tables 6

Fig.1 (a) Locality approximation for central atom and neighboring atoms within the cutoff radius Rc; (b) Under the locality approximation, each atom corresponds to one separate neural network

Fig.2 The general process of training and applying MLPs

Fig.3 The sampling process in active learning

Table 1 Summary of MLPs models， model characteristics， and typical cases of each model

机器学习方法	MLPs模型	模型特点	应用体系
神经网络	DPMD^{[13, 64]}	二代NNPs	水的相图预测^[65]，尿素分解反应^[33]，甲烷燃烧反应^[66]
	ANI^[67-68]	二代NNPs	ANI-1x数据库^[69]
	TensorMol^[70]	三代NNPs	水分子簇^[70]，多肽(PDB: 2MZX)^[70]
	n2p2^[12]	二代NNPs	体相水^[71]，单层纳米限域水相图^[72]
	RuNNer^[73-74]	四代NNPs	水在ZnO表面的解离^[75]，Au₂-MgO^[76]，Na₉Cl $8 +$ ^[76]
	EANN^[77]	二代NNPs	有机小分子与Cu、Ge等周期性体系^[77]
	DTNN^[78]	消息传递机制	GDB-7、GDB-9^[79]
	SchNet^{[14-15, 80-81]}	消息传递机制	QM9^[82-83]，MD17^[20]，ISO17^{[78, 81, 83]}
	DimeNet^[18]	消息传递机制	QM9^[82-83]
	GemNet^[19]	消息传递机制	COLL^[84]，MD17^[20]，OC20^[85]
	NequIP^[16]	消息传递机制	MD17^[20]，Li₄P₂O₇^[16]，甲酸在Cu表面的分解^[16]
	Allegro^[86]	消息传递机制	QM9^[82-83]，MD17^[20]，Li₃PO₄^[86]
	MACE^[87]	消息传递机制	MD17^[20]，3BPA^[88]
	ViSNet^[56]	消息传递机制	QM9^[82-83]，MD17^[20]等
	HIP-NN^[89]	二代NNPs	QM9^[82-83]，MD17^[20]
	SpookyNet^[90]	四代NNPs	C₁₀H₂/ C₁₀H $3 +$ ^[90]，Au₂-MgO^[90]，MD17^[20]，QM7
	PhysNet^[49]	三代NNPs	QM9^[82-83]，MD17^[20]，ISO17，S_N2反应，Ala₁₀
	ForceNet^[17]	消息传递机制	OC20^[85]
核岭回归	GDML^[21]	核方法	MD17^[20]
核岭回归	sGDML^{[20, 22-23]}	核方法	有机小分子^[20]
高斯过程回归	GAP^[24-25]	核方法	单质体系^[24]，无定形碳材料^[30]

Table 1 Summary of MLPs models， model characteristics， and typical cases of each model

机器学习方法	MLPs模型	模型特点	应用体系
神经网络	DPMD^{[13, 64]}	二代NNPs	水的相图预测^[65]，尿素分解反应^[33]，甲烷燃烧反应^[66]
	ANI^[67-68]	二代NNPs	ANI-1x数据库^[69]
	TensorMol^[70]	三代NNPs	水分子簇^[70]，多肽(PDB: 2MZX)^[70]
	n2p2^[12]	二代NNPs	体相水^[71]，单层纳米限域水相图^[72]
	RuNNer^[73-74]	四代NNPs	水在ZnO表面的解离^[75]，Au₂-MgO^[76]，Na₉Cl $8 +$ ^[76]
	EANN^[77]	二代NNPs	有机小分子与Cu、Ge等周期性体系^[77]
	DTNN^[78]	消息传递机制	GDB-7、GDB-9^[79]
	SchNet^{[14-15, 80-81]}	消息传递机制	QM9^[82-83]，MD17^[20]，ISO17^{[78, 81, 83]}
	DimeNet^[18]	消息传递机制	QM9^[82-83]
	GemNet^[19]	消息传递机制	COLL^[84]，MD17^[20]，OC20^[85]
	NequIP^[16]	消息传递机制	MD17^[20]，Li₄P₂O₇^[16]，甲酸在Cu表面的分解^[16]
	Allegro^[86]	消息传递机制	QM9^[82-83]，MD17^[20]，Li₃PO₄^[86]
	MACE^[87]	消息传递机制	MD17^[20]，3BPA^[88]
	ViSNet^[56]	消息传递机制	QM9^[82-83]，MD17^[20]等
	HIP-NN^[89]	二代NNPs	QM9^[82-83]，MD17^[20]
	SpookyNet^[90]	四代NNPs	C₁₀H₂/ C₁₀H $3 +$ ^[90]，Au₂-MgO^[90]，MD17^[20]，QM7
	PhysNet^[49]	三代NNPs	QM9^[82-83]，MD17^[20]，ISO17，S_N2反应，Ala₁₀
	ForceNet^[17]	消息传递机制	OC20^[85]
核岭回归	GDML^[21]	核方法	MD17^[20]
核岭回归	sGDML^{[20, 22-23]}	核方法	有机小分子^[20]
高斯过程回归	GAP^[24-25]	核方法	单质体系^[24]，无定形碳材料^[30]

Fig.4 The construction of ACSF descriptors for water molecules system in ANI model

Fig.5 Scheme of the message passing process in graph neural network

References 120

1	Rahman A, Stillinger F H. Molecular dynamics study of liquid water[J]. The Journal of Chemical Physics, 1971, 55(7): 3336-3359.
2	Car R, Parrinello M. Unified approach for molecular dynamics and density-functional theory[J]. Physical Review Letters, 1985, 55(22): 2471-2474.
3	Schulz R, Lindner B, Petridis L, et al. Scaling of multimillion-atom biological molecular dynamics simulation on a petascale supercomputer[J]. Journal of Chemical Theory and Computation, 2009, 5(10): 2798-2808.
4	Fu Y, Bernasconi L, Liu P. Ab initio molecular dynamics simulations of the S_N1/S_N2 mechanistic continuum in glycosylation reactions[J]. Journal of the American Chemical Society, 2021, 143(3): 1577-1589.
5	Sangiovanni D G, Gueorguiev G K, Kakanakova-Georgieva A. Ab initio molecular dynamics of atomic-scale surface reactions: insights into metal organic chemical vapor deposition of AlN on graphene[J]. Physical Chemistry Chemical Physics: PCCP, 2018, 20(26): 17751-17761.
6	Kocer E, Ko T W, Behler J. Neural network potentials: a concise overview of methods[J]. Annual Review of Physical Chemistry, 2022, 73: 163-186.
7	Cramer C J. Essentials of Computational Chemistry: Theories and Models[M]. 2nd ed. Chichester, West Sussex, England: Wiley, 2004:6.
8	Weiner S J, Kollman P A, Case D A, et al. A new force field for molecular mechanical simulation of nucleic acids and proteins[J]. Journal of the American Chemical Society, 1984, 106(3): 765-784.
9	Weinan E. The dawning of a new era in applied mathematics[J]. Notices of the American Mathematical Society, 2021, 68(4): 1.
10	Hornik K, Stinchcombe M, White H. Multilayer feedforward networks are universal approximators[J]. Neural Networks, 1989, 2(5): 359-366.
11	Blank T B, Brown S D, Calhoun A W, et al. Neural network models of potential energy surfaces[J]. The Journal of Chemical Physics, 1995, 103(10): 4129-4137.
12	Behler J, Parrinello M. Generalized neural-network representation of high-dimensional potential-energy surfaces[J]. Physical Review Letters, 2007, 98(14): 146401.
13	Wang H, Zhang L F, Han J Q, et al. DeePMD-kit: a deep learning package for many-body potential energy representation and molecular dynamics[J]. Computer Physics Communications, 2018, 228: 178-184.
14	Schütt K T, Kessel P, Gastegger M, et al. SchNetPack: a deep learning toolbox for atomistic systems[J]. Journal of Chemical Theory and Computation, 2019, 15(1): 448-455.
15	Schütt K T, Hessmann S S P, Gebauer N W A, et al. SchNetPack 2.0: a neural network toolbox for atomistic machine learning[EB/OL]. 2022. .
16	Batzner S, Musaelian A, Sun L X, et al. E(3)-equivariant graph neural networks for data-efficient and accurate interatomic potentials[J]. Nature Communications, 2022, 13: 2453.
17	Hu W H, Shuaibi M, Das A, et al. ForceNet: a graph neural network for large-scale quantum calculations[EB/OL]. 2021. .
18	Gasteiger J, Yeshwanth C, Günnemann S. Directional message passing on molecular graphs via synthetic coordinates[EB/OL]. 2021. .
19	Gasteiger J, Becker F, Günnemann S. GemNet: universal directional graph neural networks for molecules[EB/OL]. 2021. .
20	Chmiela S, Sauceda H E, Poltavsky I, et al. sGDML: constructing accurate and data efficient molecular force fields using machine learning[J]. Computer Physics Communications, 2019, 240: 38-45.
21	Chmiela S, Tkatchenko A, Sauceda H E, et al. Machine learning of accurate energy-conserving molecular force fields[J]. Science Advances, 2017, 3(5): e1603015.
22	Chmiela S, Sauceda H E, Müller K R, et al. Towards exact molecular dynamics simulations with machine-learned force fields[J]. Nature Communications, 2018, 9: 3887.
23	Chmiela S, Vassilev-Galindo V, Unke O T, et al. Accurate global machine learning force fields for molecules with hundreds of atoms[J]. Science Advances, 2023, 9(2): eadf0873.
24	Bartók A P, Payne M C, Kondor R, et al. Gaussian approximation potentials: the accuracy of quantum mechanics, without the electrons[J]. Physical Review Letters, 2010, 104(13): 136403.
25	Bartók A P, Csányi G. Gaussian approximation potentials: a brief tutorial introduction[J]. International Journal of Quantum Chemistry, 2015, 115(16): 1051-1057.
26	Thompson A P, Swiler L P, Trott C R, et al. Spectral neighbor analysis method for automated generation of quantum-accurate interatomic potentials[J]. Journal of Computational Physics, 2015, 285: 316-330.
27	Li X G, Hu C Z, Chen C, et al. Quantum-accurate spectral neighbor analysis potential models for Ni-Mo binary alloys and FCC metals[J]. Physical Review B, 2018, 98(9): 094104.
28	Rosenbrock C W, Gubaev K, Shapeev A V, et al. Machine-learned interatomic potentials for alloys and alloy phase diagrams[J]. NPJ Computational Materials, 2021, 7: 24.
29	Behler J. Four generations of high-dimensional neural network potentials[J]. Chemical Reviews, 2021, 121(16): 10037-10072.
30	Deringer V L, Csányi G. Machine learning based interatomic potential for amorphous carbon[J]. Physical Review B, 2017, 95(9): 094203.
31	Schran C, Thiemann F L, Rowe P, et al. Machine learning potentials for complex aqueous systems made simple[J]. Proceedings of the National Academy of Sciences of the United States of America, 2021, 118(38): e2110077118.
32	Thiemann F L, Schran C, Rowe P, et al. Water flow in single-wall nanotubes: oxygen makes it slip, hydrogen makes it stick[J]. ACS Nano, 2022, 16(7): 10775-10782.
33	Yang M Y, Bonati L, Polino D, et al. Using metadynamics to build neural network potentials for reactive events: the case of urea decomposition in water[J]. Catalysis Today, 2022, 387: 143-149.
34	Zhao W, Qiu H, Guo W L. A deep neural network potential for water confined in graphene nanocapillaries[J]. The Journal of Physical Chemistry C, 2022, 126(25): 10546-10553.
35	Himanen L, Jäger M O J, Morooka E V, et al. DScribe: library of descriptors for machine learning in materials science[J]. Computer Physics Communications, 2020, 247: 106949.
36	Bartók A P, Kondor R, Csányi G. On representing chemical environments[J]. Physical Review B, 2013, 87(18): 184115.
37	Rupp M, Tkatchenko A, Müller K R, et al. Fast and accurate modeling of molecular atomization energies with machine learning[J]. Physical Review Letters, 2012, 108(5): 058301.
38	Jindal S, Chiriki S, Bulusu S S. Spherical harmonics based descriptor for neural network potentials: structure and dynamics of Au₁₄₇ nanocluster[J]. The Journal of Chemical Physics, 2017, 146(20): 204301.
39	Rupp M. Unified representation of molecules and crystals for machine learning[J]. Machine Learning: Science and Technology, 2022, 3(4): 045017.
40	von Lilienfeld O A, Müller K R, Tkatchenko A. Exploring chemical compound space with quantum-based machine learning[J]. Nature Reviews Chemistry, 2020, 4: 347-358.
41	Schran C, Brezina K, Marsalek O. Committee neural network potentials control generalization errors and enable active learning[J]. The Journal of Chemical Physics, 2020, 153(10): 104105.
42	Zhang L F, Lin D Y, Wang H, et al. Active learning of uniformly accurate interatomic potentials for materials simulation[J]. Physical Review Materials, 2019, 3(2): 023804.
43	Podryabinkin E V, Tikhonov E V, Shapeev A V, et al. Accelerating crystal structure prediction by machine-learning interatomic potentials with active learning[J]. Physical Review B, 2019, 99(6): 064114.
44	Bernstein N, Csányi G, Deringer V L. De novo exploration and self-guided learning of potential-energy surfaces[J]. NPJ Computational Materials, 2019, 5: 99.
45	Schran C, Behler J, Marx D. Automated fitting of neural network potentials at coupled cluster accuracy: protonated water clusters as testing ground[J]. Journal of Chemical Theory and Computation, 2020, 16(1): 88-99.
46	Tan A R, Urata S, Goldman S, et al. Single-model uncertainty quantification in neural network potentials does not consistently outperform model ensembles[J]. NPJ Computational Materials, 2023, 9: 225.
47	Zhang Y Z, Wang H D, Chen W J, et al. DP-GEN: a concurrent learning platform for the generation of reliable deep learning based potential energy models[J]. Computer Physics Communications, 2020, 253: 107206.
48	Smith J S, Nebgen B, Lubbers N, et al. Less is more: sampling chemical space with active learning[J]. The Journal of Chemical Physics, 2018, 148(24): 241733.
49	Unke O T, Meuwly M. PhysNet: a neural network for predicting energies, forces, dipole moments, and partial charges[J]. Journal of Chemical Theory and Computation, 2019, 15(6): 3678-3693.
50	Unke O T, Stöhr M, Ganscha S, et al. Accurate machine learned quantum-mechanical force fields for biomolecular simulations[EB/OL]. 2022. .
51	Huang B, von Lilienfeld O A. Quantum machine learning using atom-in-molecule-based fragments selected on the fly[J]. Nature Chemistry, 2020, 12: 945-951.
52	Eckhoff M, Behler J. From molecular fragments to the bulk: development of a neural network potential for MOF-5[J]. Journal of Chemical Theory and Computation, 2019, 15(6): 3793-3809.
53	Eastman P, Behara P K, Dotson D L, et al. SPICE, a dataset of drug-like molecules and peptides for training machine learning potentials[J]. Scientific Data, 2023, 10: 11.
54	Pople J A. Nobel lecture: quantum chemical models[J]. Reviews of Modern Physics, 1999, 71(5): 1267-1274.
55	Bogojeski M, Vogt-Maranto L, Tuckerman M E, et al. Quantum chemical accuracy from density functional approximations via machine learning[J]. Nature Communications, 2020, 11: 5223.
56	Wang Y S, Wang T, Li S N, et al. Enhancing geometric representations for molecules with equivariant vector-scalar interactive message passing[J]. Nature Communications, 2024, 15: 313.
57	Tokita A M, Behler J. How to train a neural network potential[J]. The Journal of Chemical Physics, 2023, 159(12): 121501.
58	Chong S, Grasselli F, Ben Mahmoud C, et al. Robustness of local predictions in atomistic machine learning models[J]. Journal of Chemical Theory and Computation, 2023, 19(22): 8020-8031.
59	Morrow J D, Gardner J L A, Deringer V L. How to validate machine-learned interatomic potentials[J]. The Journal of Chemical Physics, 2023, 158(12): 121501.
60	Jordan M I, Mitchell T M. Machine learning: trends, perspectives, and prospects[J]. Science, 2015, 349(6245): 255-260.
61	LeCun Y, Bengio Y, Hinton G. Deep learning[J]. Nature, 2015, 521: 436-444.
62	Pandey M, Fernandez M, Gentile F, et al. The transformational role of GPU computing and deep learning in drug discovery[J]. Nature Machine Intelligence, 2022, 4: 211-221.
63	Knight J C, Nowotny T. Larger GPU-accelerated brain simulations with procedural connectivity[J]. Nature Computational Science, 2021, 1: 136-142.
64	Zhang L F, Han J Q, Wang H, et al. End-to-end symmetry preserving inter-atomic potential energy model for finite and extended systems[C]//Proceedings of the 32nd International Conference on Neural Information Processing Systems. Montréal, Canada: ACM, 2018: 4441-4451.
65	Zhang L F, Wang H, Car R, et al. Phase diagram of a deep potential water model[J]. Physical Review Letters, 2021, 126(23): 236001.
66	Zeng J Z, Cao L Q, Xu M Y, et al. Complex reaction processes in combustion unraveled by neural network-based molecular dynamics simulation[J]. Nature Communications, 2020, 11: 5713.
67	Smith J S, Isayev O, Roitberg A E. ANI-1: an extensible neural network potential with DFT accuracy at force field computational cost[J]. Chemical Science, 2017, 8(4): 3192-3203.
68	Gao X, Ramezanghorbani F, Isayev O, et al. TorchANI: a free and open source PyTorch-based deep learning implementation of the ANI neural network potentials[J]. Journal of Chemical Information and Modeling, 2020, 60(7): 3408-3415.
69	Smith J S, Isayev O, Roitberg A E. ANI-1, a data set of 20 million calculated off-equilibrium conformations for organic molecules[J]. Scientific Data, 2017, 4: 170193.
70	Yao K, Herr J E, Toth D W, et al. The TensorMol-0.1 model chemistry: a neural network augmented with long-range physics[J]. Chemical Science, 2018, 9(8): 2261-2269.
71	Desai S, Reeve S T, Belak J F. Implementing a neural network interatomic model with performance portability for emerging exascale architectures[J]. Computer Physics Communications, 2022, 270: 108156.
72	Kapil V, Schran C, Zen A, et al. The first-principles phase diagram of monolayer nanoconfined water[J]. Nature, 2022, 609: 512-516.
73	Behler J. Constructing high-dimensional neural network potentials: a tutorial review[J]. International Journal of Quantum Chemistry, 2015, 115(16): 1032-1050.
74	Behler J. First principles neural network potentials for reactive simulations of large molecular and condensed systems[J]. Angewandte Chemie International Edtion, 2017, 56(42): 12828-12840.
75	Quaranta V, Hellström M, Behler J. Proton-transfer mechanisms at the water-ZnO interface: the role of presolvation[J]. The Journal of Physical Chemistry Letters, 2017, 8(7): 1476-1483.
76	Ko T W, Finkler J A, Goedecker S, et al. A fourth-generation high-dimensional neural network potential with accurate electrostatics including non-local charge transfer[J]. Nature Communications, 2021, 12: 398.
77	Zhang Y L, Hu C, Jiang B. Embedded atom neural network potentials: efficient and accurate machine learning with a physically inspired representation[J]. The Journal of Physical Chemistry Letters, 2019, 10(17): 4962-4967.
78	Schütt K T, Arbabzadah F, Chmiela S, et al. Quantum-chemical insights from deep tensor neural networks[J]. Nature Communications, 2017, 8: 13890.
79	Blum L C, Reymond J L. 970 million druglike small molecules for virtual screening in the chemical universe database GDB-13[J]. Journal of the American Chemical Society, 2009, 131(25): 8732-8733.
80	Schütt K T, Sauceda H E, Kindermans P J, et al. SchNet — a deep learning architecture for molecules and materials[J]. The Journal of Chemical Physics, 2018, 148(24): 241722.
81	Schütt K T, Kindermans P J, Sauceda H E, et al. SchNet: a continuous-filter convolutional neural network for modeling quantum interactions[C]//Proceedings of the 31st International Conference on Neural Information Processing Systems. Long Beach, California, USA: ACM, 2017: 992-1002.
82	Ruddigkeit L, van Deursen R, Blum L C, et al. Enumeration of 166 billion organic small molecules in the chemical universe database GDB-17[J]. Journal of Chemical Information and Modeling, 2012, 52(11): 2864-2875.
83	Ramakrishnan R, Dral P O, Rupp M, et al. Quantum chemistry structures and properties of 134 kilo molecules[J]. Scientific Data, 2014, 1: 140022.
84	Gasteiger J, Giri S, Margraf J T, et al. Fast and uncertainty-aware directional message passing for non-equilibrium molecules[EB/OL]. 2020. .
85	Chanussot L, Das A, Goyal S, et al. Open catalyst 2020 (OC20) dataset and community challenges[J]. ACS Catalysis, 2021, 11(10): 6059-6072.
86	Musaelian A, Batzner S, Johansson A, et al. Learning local equivariant representations for large-scale atomistic dynamics[J]. Nature Communications, 2023, 14: 579.
87	Batatia I, Kovács D P, Simm G N C, et al. MACE: higher order equivariant message passing neural networks for fast and accurate force fields[EB/OL]. 2022. .
88	Kovács D P, Oord C V, Kucera J, et al. Linear atomic cluster expansion force fields for organic molecules: beyond RMSE[J]. Journal of Chemical Theory and Computation, 2021, 17(12): 7696-7711.
89	Lubbers N, Smith J S, Barros K. Hierarchical modeling of molecular energies using a deep neural network[J]. The Journal of Chemical Physics, 2018, 148(24): 241715.
90	Unke O T, Chmiela S, Gastegger M, et al. SpookyNet: learning force fields with electronic degrees of freedom and nonlocal effects[J]. Nature Communications, 2021, 12: 7273.
91	Rasmussen C E, Williams C K I. Gaussian Processes for Machine Learning[M]. Cambridge: MIT Press, 2006.
92	Wood M A, Thompson A P. Extending the accuracy of the SNAP interatomic potential form[J]. The Journal of Chemical Physics, 2018, 148(24): 241721.
93	Schütt K, Unke O, Gastegger M. Equivariant message passing for the prediction of tensorial properties and molecular spectra[C]//Proceedings of the 38th International Conference on Machine Learning. PMLR, 2021: 9377-9388.
94	Hofmann T, Schölkopf B, Smola A J. Kernel methods in machine learning[J]. The Annals of Statistics, 2008, 36(3): 1171-1220.
95	Zhang L F, Wang H, Muniz M C, et al. A deep potential model with long-range electrostatic interactions[J]. The Journal of Chemical Physics, 2022, 156(12): 124107.
96	Zeng J Z, Giese T J, Ekesan Ş, et al. Development of range-corrected deep learning potentials for fast, accurate quantum mechanical/molecular mechanical simulations of chemical reactions in solution[J]. Journal of Chemical Theory and Computation, 2021, 17(11): 6993-7009.
97	Zhang D, Bi H R, Dai F Z, et al. DPA-1: pretraining of attention-based deep potential model for molecular simulation[EB/OL]. 2022. .
98	Zhang D, Liu X, Zhang X Y, et al. DPA-2: towards a universal large atomic model for molecular and material simulation[EB/OL]. 2023. .
99	Zeng J Z, Zhang D, Lu D H, et al. DeePMD-kit v2: a software package for deep potential models[J]. The Journal of Chemical Physics, 2023, 159(5): 054801.
100	Smith J S, Nebgen B T, Zubatyuk R, et al. Outsmarting Quantum Chemistry Through Transfer Learning[M/OL]. ChemRxiv, 2018[2024-02-02]. .
101	Devereux C, Smith J S, Huddleston K K, et al. Extending the applicability of the ANI deep learning molecular potential to sulfur and halogens[J]. Journal of Chemical Theory and Computation, 2020, 16(7): 4192-4202.
102	Gilmer J, Schoenholz S S, Riley P F, et al. Neural message passing for quantum chemistry[C]//Proceedings of the 34th International Conference on Machine Learning-Volume 70. Sydney, NSW, Australia: ACM, 2017: 1263-1272.
103	Duval A, Mathis S V, Joshi C K, et al. A hitchhiker's guide to geometric GNNs for 3D atomic systems[EB/OL]. 2023. .
104	Ghasemi S A, Hofstetter A, Saha S, et al. Interatomic potentials for ionic systems with density functional accuracy based on charge densities obtained by a neural network[J]. Physical Review B, 2015, 92(4): 045131.
105	Anstine D M, Isayev O. Machine learning interatomic potentials and long-range physics[J]. The Journal of Physical Chemistry. A, 2023, 127(11): 2417-2431.
106	Jia W, Wang H, Chen M, et al. Pushing the limit of molecular dynamics with ab initio accuracy to 100 million atoms with machine learning[C]//Proceedings of Sc20: the International Conference for High Performance Computing, Networking, Storage and Analysis (Sc20). New York: IEEE, 2020.
107	Jose K V, Artrith N, Behler J. Construction of high-dimensional neural network potentials using environment-dependent atom pairs[J]. The Journal of Chemical Physics, 2012, 136(19): 194111.
108	Artrith N, Behler J. High-dimensional neural network potentials for metal surfaces: a prototype study for copper[J]. Physical Review B, 2012, 85(4): 045439.
109	Marques M R G, Wolff J, Steigemann C, et al. Neural network force fields for simple metals and semiconductors: construction and application to the calculation of phonons and melting temperatures[J]. Physical Chemistry Chemical Physics, 2019, 21(12): 6506-6516.
110	Liu J C, Liu R X, Cao Y, et al. Solvation structures of calcium and magnesium ions in water with the presence of hydroxide: a study by deep potential molecular dynamics[J]. Physical Chemistry Chemical Physics: PCCP, 2023, 25(2): 983-993.
111	Hellström M, Quaranta V, Behler J. One-dimensional vs. two-dimensional proton transport processes at solid-liquid zinc-oxide-water interfaces[J]. Chemical Science, 2018, 10(4): 1232-1243.
112	Quaranta V, Behler J, Hellström M. Structure and dynamics of the liquid-water/zinc-oxide interface from machine learning potential simulations[J]. The Journal of Physical Chemistry C, 2019, 123(2): 1293-1304.
113	Natarajan S K, Behler J. Neural network molecular dynamics simulations of solid-liquid interfaces: water at low-index copper surfaces[J]. Physical Chemistry Chemical Physics: PCCP, 2016, 18(41): 28704-28725.
114	Kozinsky B, Musaelian A, Johansson A, et al. Scaling the leading accuracy of deep equivariant models to biomolecular simulations of realistic size[C]//Proceedings of the International Conference for High Performance Computing, Networking, Storage and Analysis. Denver, CO, USA: ACM, 2023.
115	Gallo P, Amann-Winkel K, Angell C A, et al. Water: a tale of two liquids[J]. Chemical Reviews, 2016, 116(13): 7463-7500.
116	Cisneros G A, Wikfeldt K T, Ojamäe L, et al. Modeling molecular interactions in water: from pairwise to many-body potential energy functions[J]. Chemical Reviews, 2016, 116(13): 7501-7528.
117	Behler J, Martonák R, Donadio D, et al. Metadynamics simulations of the high-pressure phases of silicon employing a high-dimensional neural network potential[J]. Physical Review Letters, 2008, 100(18): 185501.
118	Zhang D, Yi P Y, Lai X M, et al. Active machine learning model for the dynamic simulation and growth mechanisms of carbon on metal surface[J]. Nature Communications, 2024, 15: 344.
119	Gartner T E, Ferguson A L, Debenedetti P G. Data-driven molecular design and simulation in modern chemical engineering[J]. Nature Chemical Engineering, 2024, 1: 6-9.
120	Kovács D P, Moore J H, Browning N J, et al. MACE-OFF23: transferable machine learning force fields for organic molecules[EB/OL]. 2023. .

[1]	Zheng ZHANG, Wuqiong WANG, Yajing ZHANG, Kangjun WANG, Yuanhui JI. Research progress in theoretical calculation of pharmaceutical formulation design [J]. CIESC Journal, 2024, 75(4): 1429-1438.
[2]	Kang ZHOU, Jianxin WANG, Hai YU, Chaoliang WEI, Fengqi FAN, Xinhao CHE, Lei ZHANG. Foam rupture properties of mineral base oils based on molecular dynamics simulation [J]. CIESC Journal, 2024, 75(4): 1668-1678.
[3]	Haoqi CHEN, Bohui SHI, Qi PENG, Qi KANG, Shangfei SONG, Haiyuan YAO, Haihong CHEN, Haihao WU, Jing GONG. Phase equilibrium calculation of acid/alcohol hydrocarbon and water system based on stability analysis [J]. CIESC Journal, 2024, 75(3): 789-800.
[4]	Xinzi ZHOU, Zenghui LI, Xianyang MENG, Jiangtao WU. Experimental study on viscosity of high purity air at low temperatures [J]. CIESC Journal, 2024, 75(3): 782-788.
[5]	Fan WU, Xudong PENG, Jinbo JIANG, Xiangkai MENG, Yangyang LIANG. Study on adaptability of molecular dynamics in predicting density and viscosity of natural gas [J]. CIESC Journal, 2024, 75(2): 450-462.
[6]	Xin YANG, Wen WANG, Kai XU, Fanhua MA. Simulation analysis of temperature characteristics of the high-pressure hydrogen refueling process [J]. CIESC Journal, 2023, 74(S1): 280-286.
[7]	Minghui CHANG, Lin WANG, Jiajia YUAN, Yifei CAO. Study on the cycle performance of salt solution-storage-based heat pump [J]. CIESC Journal, 2023, 74(S1): 329-337.
[8]	Minghao SONG, Fei ZHAO, Shuqing LIU, Guoxuan LI, Sheng YANG, Zhigang LEI. Multi-scale simulation and study of volatile phenols removal from simulated oil by ionic liquids [J]. CIESC Journal, 2023, 74(9): 3654-3664.
[9]	Jianbo HU, Hongchao LIU, Qi HU, Meiying HUANG, Xianyu SONG, Shuangliang ZHAO. Molecular dynamics simulation insight into translocation behavior of organic cage across the cellular membrane [J]. CIESC Journal, 2023, 74(9): 3756-3765.
[10]	Jiajia ZHAO, Shixiang TIAN, Peng LI, Honggao XIE. Microscopic mechanism of SiO₂-H₂O nanofluids to enhance the wettability of coal dust [J]. CIESC Journal, 2023, 74(9): 3931-3945.
[11]	Manzheng ZHANG, Meng XIAO, Peiwei YAN, Zheng MIAO, Jinliang XU, Xianbing JI. Working fluid screening and thermodynamic optimization of hazardous waste incineration coupled organic Rankine cycle system [J]. CIESC Journal, 2023, 74(8): 3502-3512.
[12]	Linzheng WANG, Yubing LU, Ruizhi ZHANG, Yonghao LUO. Analysis on thermal oxidation characteristics of VOCs based on molecular dynamics simulation [J]. CIESC Journal, 2023, 74(8): 3242-3255.
[13]	Ji CHEN, Ze HONG, Zhao LEI, Qiang LING, Zhigang ZHAO, Chenhui PENG, Ping CUI. Study on coke dissolution loss reaction and its mechanism based on molecular dynamics simulations [J]. CIESC Journal, 2023, 74(7): 2935-2946.
[14]	Xiaokun HE, Rui LIU, Yuan XUE, Ran ZUO. Review of gas phase and surface reactions in AlN MOCVD [J]. CIESC Journal, 2023, 74(7): 2800-2813.
[15]	Ming DONG, Jinliang XU, Guanglin LIU. Molecular dynamics study on heterogeneous characteristics of supercritical water [J]. CIESC Journal, 2023, 74(7): 2836-2847.