Defect engineering in two-dimensional materials for photocatalysis: A mini-review of first-principles design

Yiqing Chen , Xiao-Yan Li , Pengfei Ou

Front. Energy ›› 2025, Vol. 19 ›› Issue (1) : 59 -68.

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Front. Energy ›› 2025, Vol. 19 ›› Issue (1) : 59 -68. DOI: 10.1007/s11708-024-0961-5
MINI REVIEW

Defect engineering in two-dimensional materials for photocatalysis: A mini-review of first-principles design

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Abstract

Two-dimensional (2D) materials have emerged as a significant class of materials promising for photocatalysis, and defect engineering offers an effective route for enhancing their photocatalytic performance. In this mini-review, a first-principles design perspective on defect engineering in 2D materials for photocatalysis is provided. Various types of defects in 2D materials, spanning point, line, and planar defects are explored, and their influence on the intrinsic properties and photocatalytic efficacy of these materials is highlighted. Additionally, the use of theoretical descriptors to characterize the stability, electronic, optical, and catalytic properties of 2D defective systems is summarized. Central to the discussion is the understanding of electronic structure, optical properties, and reaction mechanisms to inform the rational design of photocatalysts based on 2D materials for enhanced photocatalytic performance. This mini-review aims to provide insights into the computational design of 2D defect systems tailored for efficient photocatalytic applications.

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photocatalysis / first-principles / defect engineering / descriptors / two-dimensional materials

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Yiqing Chen, Xiao-Yan Li, Pengfei Ou. Defect engineering in two-dimensional materials for photocatalysis: A mini-review of first-principles design. Front. Energy, 2025, 19(1): 59-68 DOI:10.1007/s11708-024-0961-5

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References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Moniz S J A, Shevlin S A, Martin D J. . Visible-light driven heterojunction photocatalysts for water splitting—A critical review. Energy & Environmental Science, 2015, 8(3): 731–759

[2]

Morozov S V, Novoselov K S, Katsnelson M I. . Giant intrinsic carrier mobilities in graphene and its bilayer. Physical Review Letters, 2008, 100(1): 016602

[3]

Peigney A, Laurent C, Flahaut E. . Specific surface area of carbon nanotubes and bundles of carbon nanotubes. Carbon, 2001, 39(4): 507–514

[4]

Lee C, Wei X, Kysar J W. . Measurement of the elastic properties and intrinsic strength of monolayer graphene. Science, 2008, 321(5887): 385–388

[5]

Novoselov K S, Geim A K, Morozov S V. . Electric field effect in atomically thin carbon films. Science, 2004, 306(5696): 666–669

[6]

Peng B, Ang P K, Loh K P. Two-dimensional dichalcogenides for light-harvesting applications. Nano Today, 2015, 10(2): 128–137

[7]

Mortazavi B, Fan Z, Pereira L F C. . Amorphized graphene: A stiff material with low thermal conductivity. Carbon, 2016, 103: 318–326

[8]

Chen Y, Meng F, Bie X. . Atomistic and continuum modeling of 3D graphene honeycombs under uniaxial in-plane compression. Computational Materials Science, 2021, 197: 110646

[9]

Di J, Hao G, Jiang W. . Defect chemistry in 2D atomic layers for energy photocatalysis. Accounts of Materials Research, 2023, 4(11): 910–924

[10]

Ou P, Zhou X, Meng F. . Single molybdenum center supported on N-doped black phosphorus as an efficient electrocatalyst for nitrogen fixation. Nanoscale, 2019, 11(28): 13600–13611

[11]

Chen Y, Ou P, Bie X. . Basal plane activation in monolayer MoTe2 for the hydrogen evolution reaction via phase boundaries. Journal of Materials Chemistry. A, Materials for Energy and Sustainability, 2020, 8(37): 19522–19532

[12]

Zhao Y, Chen Y, Ou P. . Basal plane activation via grain boundaries in monolayer MoS2 for carbon dioxide reduction. ACS Catalysis, 2023, 13(19): 12941–12951

[13]

Li Y, Li Y L, Sa B. . Review of two-dimensional materials for photocatalytic water splitting from a theoretical perspective. Catalysis Science & Technology, 2017, 7(3): 545–559

[14]

Samanta B, Morales-García Á, Illas F. . Challenges of modeling nanostructured materials for photocatalytic water splitting. Chemical Society Reviews, 2022, 51(9): 3794–3818

[15]

Ge L, Ke Y, Li X. Machine learning integrated photocatalysis: Progress and challenges. Chemical Communications, 2023, 59(39): 5795–5806

[16]

Luo B, Liu G, Wang L. Recent advances in 2D materials for photocatalysis. Nanoscale, 2016, 8(13): 6904–6920

[17]

Hisatomi T, Kubota J, Domen K. Recent advances in semiconductors for photocatalytic and photoelectrochemical water splitting. Chemical Society Reviews, 2014, 43(22): 7520–7535

[18]

Yu J, Xu C Y, Ma F X. . Monodisperse SnS2 nanosheets for high-performance photocatalytic hydrogen generation. ACS Applied Materials & Interfaces, 2014, 6(24): 22370–22377

[19]

Dong X, Cheng F. Recent development in exfoliated two-dimensional g-C3N4 nanosheets for photocatalytic applications. Journal of Materials Chemistry. A, Materials for Energy and Sustainability, 2015, 3(47): 23642–23652

[20]

Zhang X, Zhang Z, Wu D. . Computational screening of 2D materials and rational design of heterojunctions for water splitting photocatalysts. Small Methods, 2018, 2(5): 1700359

[21]

Faraji M, Yousefi M, Yousefzadeh S. . Two-dimensional materials in semiconductor photoelectrocatalytic systems for water splitting. Energy & Environmental Science, 2019, 12(1): 59–95

[22]

Hinnemann B, Moses P G, Bonde J. . Biomimetic hydrogen evolution: MoS2 nanoparticles as catalyst for hydrogen evolution. Journal of the American Chemical Society, 2005, 127(15): 5308–5309

[23]

Jaramillo TF, Jørgensen KP, Bonde J. . Identification of active edge sites for electrochemical H2 evolution from MoS2 nanocatalysts. Science, 2007, 317(5834): 100–102

[24]

Ouyang Y, Ling C, Chen Q. . Activating inert basal planes of MoS2 for hydrogen evolution reaction through the formation of different intrinsic defects. Chemistry of Materials, 2016, 28(12): 4390–4396

[25]

Li H, Tsai C, Koh A L. . Corrigendum: Activating and optimizing MoS2 basal planes for hydrogen evolution through the formation of strained sulphur vacancies. Nature Materials, 2016, 15(3): 364

[26]

Li L, Qin Z, Ries L. . Role of sulfur vacancies and undercoordinated Mo regions in MoS2 nanosheets toward the evolution of hydrogen. ACS Nano, 2019, 13(6): 6824–6834

[27]

Li H, Tsai C, Koh A L. . Activating and optimizing MoS2 basal planes for hydrogen evolution through the formation of strained sulphur vacancies. Nature Materials, 2016, 15(1): 48–53

[28]

Guan M, Xiao C, Zhang J. . Vacancy associates promoting solar-driven photocatalytic activity of ultrathin bismuth oxychloride nanosheets. Journal of the American Chemical Society, 2013, 135(28): 10411–10417

[29]

Bi W, Ye C, Xiao C. . Spatial location engineering of oxygen vacancies for optimized photocatalytic H2 evolution activity. Small, 2014, 10(14): 2820–2825

[30]

Liu Y, Xiao C, Li Z. . Vacancy engineering for tuning electron and phonon structures of two-dimensional materials. Advanced Energy Materials, 2016, 6(23): 1600436

[31]

Dou Y, He C T, Zhang L. . Approaching the activity limit of CoSe2 for oxygen evolution via Fe doping and Co vacancy. Nature Communications, 2020, 11(1): 1664

[32]

Feng C, Wu Z P, Huang K W. . Surface modification of 2D photocatalysts for solar energy conversion. Advanced Materials, 2022, 34(23): 2200180

[33]

Lei F, Zhang L, Sun Y. . Atomic-layer-confined doping for atomic-level insights into visible-light water splitting. Angewandte Chemie International Edition, 2015, 54(32): 9266–9270

[34]

Chen K, Zhou S, Jiang T. . Synergy of Fe dopants and oxygen vacancies confined in atomically-thin cobaltous oxide sheets for high-efficiency CO2 photoreduction. Journal of Materials Chemistry. A, Materials for Energy and Sustainability, 2021, 9(39): 22353–22363

[35]

Lee Y, Ling N, Kim D. . Heterophase boundary for active hydrogen evolution in MoTe2. Advanced Functional Materials, 2022, 32(10): 2105675

[36]

Zhao N, Wang L, Zhang Z. . Activating the MoS2 basal planes for electrocatalytic hydrogen evolution by 2H/1T′ structural interfaces. ACS Applied Materials & Interfaces, 2019, 11(45): 42014–42020

[37]

Zhu J, Wang Z C, Dai H. . Boundary activated hydrogen evolution reaction on monolayer MoS2. Nature Communications, 2019, 10(1): 1348

[38]

Peng R, Liang L, Hood Z D. . In-plane heterojunctions enable multiphasic two-dimensional (2D) MoS2 nanosheets as efficient photocatalysts for hydrogen evolution from water reduction. ACS Catalysis, 2016, 6(10): 6723–6729

[39]

Duong D L, Yun S J, Lee Y H. van der Waals layered materials: Opportunities and challenges. ACS Nano, 2017, 11(12): 11803–11830

[40]

Novoselov K S, Mishchenko A, Carvalho A. . 2D materials and van der Waals heterostructures. Science, 2016, 353(6298): aac9439

[41]

Luo Y, Wang S, Ren K. . Transition-metal dichalcogenides/Mg(OH)2 van der Waals heterostructures as promising water-splitting photocatalysts: A first-principles study. Physical Chemistry Chemical Physics, 2019, 21(4): 1791–1796

[42]

Ren K, Yu J, Tang W. A two-dimensional vertical van der Waals heterostructure based on g-GaN and Mg (OH)2 used as a promising photocatalyst for water splitting: A first-principles calculation. Journal of Applied Physics, 2019, 126(6): 065701

[43]

Yu H, Dai M, Zhang J. . Interface engineering in 2D/2D heterogeneous photocatalysts. Small, 2023, 19(5): 2205767

[44]

Xu J, Gao J, Qi Y. . Anchoring Ni2P on the UiO-66–NH2/g-C3N4-derived C-doped ZrO2/g-C3N4 heterostructure: Highly efficient photocatalysts for H2 production from water splitting. ChemCatChem, 2018, 10(15): 3327–3335

[45]

Ma Y, Qiu B, Zhang J. . Vacancy engineering of ultrathin 2D materials for photocatalytic CO2 reduction. ChemNanoMat: Chemistry of Nanomaterials for Energy, Biology and More, 2021, 7(4): 368–379

[46]

Wang X, Wu J, Zhang Y. . Vacancy defects in 2D transition metal dichalcogenide electrocatalysts: From aggregated to atomic configuration. Advanced Materials, 2023, 35(50): 2206576

[47]

Aras M, Kılıç Ç, Ciraci S. Lateral and vertical heterostructures of transition metal dichalcogenides. Journal of Physical Chemistry C, 2018, 122(3): 1547–1555

[48]

Bölle FT, Mikkelsen AEG, Thygesen KS. . Structural and chemical mechanisms governing stability of inorganic Janus nanotubes. npj Computational Materials, 2021, 7(1): 41

[49]

Freysoldt C, Grabowski B, Hickel T. . First-principles calculations for point defects in solids. Reviews of Modern Physics, 2014, 86(1): 253–305

[50]

Li A, Pan J, Dai X. . Electrical contacts of coplanar 2H/1T′ MoTe2 monolayer. Journal of Applied Physics, 2019, 125(7): 075104

[51]

Komsa H P, Berseneva N, Krasheninnikov A V. . Charged point defects in the flatland: Accurate formation energy calculations in two-dimensional materials. Physical Review X, 2014, 4(3): 031044

[52]

Dabo I, Kozinsky B, Singh-Miller N E. . Electrostatics in periodic boundary conditions and real-space corrections. Physical Review B: Condensed Matter and Materials Physics, 2008, 77(11): 115139

[53]

Schleder G R, Acosta C M, Fazzio A. Exploring two-dimensional materials thermodynamic stability via machine learning. ACS Applied Materials & Interfaces, 2020, 12(18): 20149–20157

[54]

Mounet N, Gibertini M, Schwaller P. . Two-dimensional materials from high-throughput computational exfoliation of experimentally known compounds. Nature Nanotechnology, 2018, 13(3): 246–252

[55]

Zhou J, Shen L, Costa M D. . 2DMatPedia, an open computational database of two-dimensional materials from top-down and bottom-up approaches. Scientific Data, 2019, 6(1): 86

[56]

Choudhary K, Kalish I, Beams R. . High-throughput identification and characterization of two-dimensional materials using density functional theory. Scientific Reports, 2017, 7(1): 5179

[57]

Ashton M, Paul J, Sinnott S B. . Topology-scaling identification of layered solids and stable exfoliated 2D materials. Physical Review Letters, 2017, 118(10): 106101

[58]

Huang P, Lukin R, Faleev M. . Unveiling the complex structure-property correlation of defects in 2D materials based on high throughput datasets. npj 2D Materials and Applications, 2023, 7(1): 6

[59]

Bertoldo F, Ali S, Manti S, Thygesen K S. Quantum point defects in 2D materials—The QPOD database. npj Computational Materials, 2022, 8(1): 56

[60]

Singh A K, Mathew K, Zhuang H L. . Computational screening of 2D materials for photocatalysis. Journal of Physical Chemistry Letters, 2015, 6(6): 1087–1098

[61]

Mathew K, Sundararaman R, Letchworth-Weaver K. . Implicit solvation model for density-functional study of nanocrystal surfaces and reaction pathways. Journal of Chemical Physics, 2014, 140(8): 084106

[62]

Steinmann S N, Sautet P, Michel C. Solvation free energies for periodic surfaces: Comparison of implicit and explicit solvation models. Physical Chemistry Chemical Physics, 2016, 18(46): 31850–31861

[63]

Pan B C, Yang W S, Yang J. Formation energies of topological defects in carbon nanotubes. Physical Review B: Condensed Matter, 2000, 62(19): 12652–12655

[64]

Malyi O I, Sopiha K V, Persson C. Energy, phonon, and dynamic stability criteria of two-dimensional materials. ACS Applied Materials & Interfaces, 2019, 11(28): 24876–24884

[65]

Chen Z, Dinh H N, Miller E. Photoelectrochemical Water Splitting. New York: Springer, 2013
[66]

Xiao H, Tahir-Kheli J, Goddard W A III. Accurate band gaps for semiconductors from density functional theory. Journal of Physical Chemistry Letters, 2011, 2(3): 212–217

[67]

Crowley J M, Tahir-Kheli J, Goddard W A III. Resolution of the band gap prediction problem for materials design. Journal of Physical Chemistry Letters, 2016, 7(7): 1198–1203

[68]

Jain M, Chelikowsky J R, Louie S G. Reliability of hybrid functionals in predicting band gaps. Physical Review Letters, 2011, 107(21): 216806

[69]

Saßnick H D, Cocchi C. Electronic structure of cesium-based photocathode materials from density functional theory: Performance of PBE, SCAN, and HSE06 functionals. Electronic Structure., 2021, 3(2): 027001

[70]

Mourino B, Jablonka K M, Ortega-Guerrero A. . In search of covalent organic framework photocatalysts: A DFT-based screening approach. Advanced Functional Materials, 2023, 33(32): 2301594

[71]

Wang H, Jin S, Zhang X. . Excitonic effects in polymeric photocatalysts. Angewandte Chemie International Edition, 2020, 59(51): 22828–22839

[72]

Botti S, Sottile F, Vast N. . Long-range contribution to the exchange-correlation kernel of time-dependent density functional theory. Physical Review B: Condensed Matter and Materials Physics, 2004, 69(15): 155112

[73]

Kronik L, Stein T, Refaely-Abramson S. . Excitation gaps of finite-sized systems from optimally tuned range-separated hybrid functionals. Journal of Chemical Theory and Computation, 2012, 8(5): 1515–1531

[74]

Shu H, Li Y, Niu X. . Greatly enhanced optical absorption of a defective MoS2 monolayer through oxygen passivation. ACS Applied Materials & Interfaces, 2016, 8(20): 13150–13156

[75]

Biswas T, Singh AK. Excitonic effects in absorption spectra of carbon dioxide reduction photocatalysts. npj Computational Materials, 2021, 7(1): 189

[76]

Ugeda M M, Bradley A J, Shi S F. . Giant bandgap renormalization and excitonic effects in a monolayer transition metal dichalcogenide semiconductor. Nature Materials, 2014, 13(12): 1091–1095

[77]

Qiu D Y, da Jornada F H, Louie S G. Optical spectrum of MoS2: Many-body effects and diversity of exciton states. Physical Review Letters, 2013, 111(21): 216805

[78]

Abild-Pedersen F, Greeley J, Studt F. . Scaling properties of adsorption energies for hydrogen-containing molecules on transition-metal surfaces. Physical Review Letters, 2007, 99(1): 016105

[79]

Wang X, Zhang G, Yang L. . Material descriptors for photocatalyst/catalyst design. Wiley Interdisciplinary Reviews. Computational Molecular Science, 2018, 8(5): e1369

[80]

Liu F, Shi C, Guo X. . Rational design of better hydrogen evolution electrocatalysts for water splitting: A review. Advanced Science, 2022, 9(18): 2200307

[81]

Østergaard F C, Bagger A, Rossmeisl J. Predicting catalytic activity in hydrogen evolution reaction. Current Opinion in Electrochemistry, 2022, 35: 101037

[82]

Hammer B, Nørskov J K. Electronic factors determining the reactivity of metal surfaces. Surface Science, 1995, 343(3): 211–220

[83]

Nilsson A, Pettersson L G M, Hammer B. . The electronic structure effect in heterogeneous catalysis. Catalysis Letters, 2005, 100(3): 111–114

[84]

Shu H, Zhou D, Li F. . Defect engineering in MoSe2 for the hydrogen evolution reaction: From point defects to edges. ACS Applied Materials & Interfaces, 2017, 9(49): 42688–42698

[85]

Pérez-Ramírez J, López N. Strategies to break linear scaling relationships. Nature Catalysis, 2019, 2(11): 971–976

[86]

Huang Y, Nielsen R J, Goddard W A III. . The reaction mechanism with free energy barriers for electrochemical dihydrogen evolution on MoS2. Journal of the American Chemical Society, 2015, 137(20): 6692–6698

[87]

Knøsgaard N R, Thygesen K S. Representing individual electronic states for machine learning GW band structures of 2D materials. Nature Communications, 2022, 13(1): 468

[88]

Tawfik S A, Isayev O, Stampfl C. . Efficient prediction of structural and electronic properties of hybrid 2D materials using complementary DFT and machine learning approaches. Advanced Theory and Simulations, 2019, 2(1): 1800128

[89]

Zhu Z, Dong B, Guo H. . Fundamental band gap and alignment of two-dimensional semiconductors explored by machine learning. Chinese Physics B, 2020, 29(4): 046101

[90]

Rajan A C, Mishra A, Satsangi S. . Machine-learning-assisted accurate band gap predictions of functionalized MXene. Chemistry of Materials, 2018, 30(12): 4031–4038

[91]

Dau M T, Al Khalfioui M, Michon A. . Descriptor engineering in machine learning regression of electronic structure properties for 2D materials. Scientific Reports, 2023, 13(1): 5426

[92]

Manzoor A, Arora G, Jerome B. . Machine learning based methodology to predict point defect energies in multi-principal element alloys. Frontiers in Materials, 2021, 8: 673574

[93]

Choudhary K, Sumpter B G. Can a deep-learning model make fast predictions of vacancy formation in diverse materials. AIP Advances, 2023, 13(9): 095109

[94]

Mueller T, Hernandez A, Wang C. Machine learning for interatomic potential models. Journal of Chemical Physics, 2020, 152(5): 050902

[95]

Musa E, Doherty F, Goldsmith B R. Accelerating the structure search of catalysts with machine learning. Current Opinion in Chemical Engineering, 2022, 35: 100771

[96]

Mortazavi B, Silani M, Podryabinkin E V. . First-principles multiscale modeling of mechanical properties in graphene/borophene heterostructures empowered by machine-learning interatomic potentials. Advanced Materials, 2021, 33(35): 2102807

[97]

Sun S, Singh A, Li Y, et al. Machine learning accelerated atomistic simulations for 2D materials with defects. In: ASME International Mechanical Engineering Congress and Exposition, 2023: American Society of Mechanical Engineers
[98]

Goryaeva A M, Dérès J, Lapointe C. . Efficient and transferable machine learning potentials for the simulation of crystal defects in bcc Fe and W. Physical Review Materials, 2021, 5(10): 103803

[99]

Dragoni D, Daff T D, Csányi G. . Achieving DFT accuracy with a machine-learning interatomic potential: Thermomechanics and defects in bcc ferromagnetic iron. Physical Review Materials, 2018, 2(1): 013808

[100]

Kumar R, Singh AK. Chemical hardness-driven interpretable machine learning approach for rapid search of photocatalysts. npj Computational Materials, 2021, 7(1): 197

[101]

Pan R, Liu J, Zhang J. Defect engineering in 2D photocatalytic materials for CO2 reduction. ChemNanoMat: Chemistry of Nanomaterials for Energy, Biology and More, 2021, 7(7): 737–747

[102]

Xiong J, Di J, Xia J. . Surface defect engineering in 2D nanomaterials for photocatalysis. Advanced Functional Materials, 2018, 28(39): 1801983

[103]

Shi R, Zhao Y, Waterhouse G I. . Defect engineering in photocatalytic nitrogen fixation. ACS Catalysis, 2019, 9(11): 9739–9750

[104]

Sun X, Zhang X, Xie Y. Surface defects in two-dimensional photocatalysts for efficient organic synthesis. Matter, 2020, 2(4): 842–861

[105]

Zhao Y, Chen G, Bian T. . Defect-rich ultrathin ZnAl-layered double hydroxide nanosheets for efficient photoreduction of CO2 to CO with water. Advanced Materials, 2015, 27(47): 7824–7831

[106]

Zhang X, Chen A, Chen L. . 2D materials bridging experiments and computations for electro/photocatalysis. Advanced Energy Materials, 2022, 12(4): 2003841

[107]

Momeni K, Ji Y, Wang Y. . Multiscale computational understanding and growth of 2D materials: A review. npj Computational Materials, 2020, 6(1): 22

[108]

Kovačič Ž, Likozar B, Huš M. Photocatalytic CO2 reduction: A review of ab initio mechanism, kinetics, and multiscale modeling simulations. ACS Catalysis, 2020, 10(24): 14984–15007

[109]

Koparde V N, Cummings P T. Molecular dynamics study of water adsorption on TiO2 nanoparticles. Journal of Physical Chemistry C, 2007, 111(19): 6920–6926

[110]

Raymand D, van Duin A C T, Spångberg D. . Water adsorption on stepped ZnO surfaces from MD simulation. Surface Science, 2010, 604(9–10): 741–752

[111]

Liu D J, Garcia A, Wang J. . Kinetic Monte Carlo simulation of statistical mechanical models and coarse-grained mesoscale descriptions of catalytic reaction–diffusion processes: 1D nanoporous and 2D surface systems. Chemical Reviews, 2015, 115(12): 5979–6050

[112]

Deskins N A, Rao P M, Dupuis M. Charge carrier management in semiconductors: Modeling charge transport and recombination. In: Bahnemann D, Patrocinio A O T, eds. Springer Handbook of Inorganic Photochemistry. Cham: Springer International Publishing, 2022
[113]

Lin F, Huang J, Hin C. Electron transport from quantum kinetic Monte Carlo simulations. Journal of Physical Chemistry C, 2018, 122(35): 20550–20554

[114]

Santos E. In search of lost descriptors: Correlations and their risks. Current Opinion in Electrochemistry, 2022, 37: 101194

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