Microenvironment Modulation for Electronic Structure of Atomically Dispersed Ir Species in Metal–Organic Frameworks Toward Boosting Catalytic DCPD Hydrogenation Performance

Tao Ban , Lingjing Yu , Rushuo Li , Changan Wang , Jing Lin , Juan Chen , Xinmeng Xu , Zhenghao Wang , Hongyi Gao , Ge Wang

Carbon Neutralization ›› 2025, Vol. 4 ›› Issue (2) : e70004 -13.

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Carbon Neutralization ›› 2025, Vol. 4 ›› Issue (2) : e70004 -13. DOI: 10.1002/cnl2.70004
RESEARCH ARTICLE

Microenvironment Modulation for Electronic Structure of Atomically Dispersed Ir Species in Metal–Organic Frameworks Toward Boosting Catalytic DCPD Hydrogenation Performance

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Abstract

The fine-tuning of the electronic structure and local environment surrounding the atomically dispersed metal centers is crucial in catalysis but remains a grand challenge that requires in-depth exploration. In this study, atomically dispersed Ir species were incorporated into a series of UiO-type metal−organic frameworks via the strong metal–support interactions (SMSI), and their electronic state was precisely modulated by regulating the metal-oxo clusters (Ce, Zr, and Hf) and organic ligands (BDC-X, where X = -H, -NH2, -Me, or -NO2) for enhancing their catalytic performance for dicyclopentadiene (DCPD) hydrogenation. The optimized Ir@Ce-UiO-66-NO2 effectively transforms DCPD into tetrahydrodicyclopentadiene (THDCPD), giving a 100% DCPD conversion and over 99% THDCPD selectivity, far superior to the corresponding counterparts. Experimental and theoretical results jointly demonstrated that Ce-oxo clusters with unique CeIII/CeIV redox pairs can facilitate the electron transfer to Ir species. Furthermore, electron-withdrawing -NO2 groups play a crucial role in increasing the CeIII/CeIV ratio, promoting the efficient electron uptake by the MOF support and leading to a low electron density around Ir species, which enhances stronger interactions between substrate molecules and active sites and contributes to the excellent catalytic activity. The findings presented in this work provide valuable insights into the rational design of advanced heterogeneous catalysts by leveraging the unique redox properties and electronic structure modulation capabilities of MOF supports.

Keywords

atomically dispersed Ir species / electron transfer / hydrogenation / microenvironment modulation / MOFs

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Tao Ban, Lingjing Yu, Rushuo Li, Changan Wang, Jing Lin, Juan Chen, Xinmeng Xu, Zhenghao Wang, Hongyi Gao, Ge Wang. Microenvironment Modulation for Electronic Structure of Atomically Dispersed Ir Species in Metal–Organic Frameworks Toward Boosting Catalytic DCPD Hydrogenation Performance. Carbon Neutralization, 2025, 4(2): e70004-13 DOI:10.1002/cnl2.70004

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References

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

L. Alig, M. Fritz, and S. Schneider, “First-Row Transition Metal (De)Hydrogenation Catalysis Based on Functional Pincer Ligands,” Chemical Reviews 119 (2019):2681–2751.
[2]

J. Bai, M. Tamura, A. Nakayama, Y. Nakagawa, and K. Tomishige, “Comprehensive Study on Ni-or Ir-Based Alloy Catalysts in the Hydrogenation of Olefins and Mechanistic Insight,” ACS Catalysis 11 (2021):3293–3309.
[3]

F. Meemken and A. Baiker, “Recent Progress in Heterogeneous Asymmetric Hydrogenation of C═O and C═C Bonds on Supported Noble Metal Catalysts,” Chemical Reviews 117 (2017):11522–11569.
[4]

D. Wang and D. Astruc, “The Golden Age of Transfer Hydrogenation,” Chemical Reviews 115 (2015):6621–6686.
[5]

G. Vilé, D. Albani, N. Almora-Barrios, N. López, and J. Pérez-Ramírez, “Advances in the Design of Nanostructured Catalysts for Selective Hydrogenation,” ChemCatChem 8 (2016):21–33.
[6]

J. Lin, T. Ban, T. Li, et al., “Machine-Learning-Assisted Intelligent Synthesis of UiO-66(Ce): Balancing the Trade-off Between Structural Defects and Thermal Stability for Efficient Hydrogenation of Dicyclopentadiene,” MGE Advances 2 (2024): e61.
[7]

D. Jia, J. Zhao, Z. Tao, et al., “Highly Dispersed Ni Nanocatalysts Supported by MOFs Derived Hierarchical N-Doped Porous Carbon for Hydrogenation of Dicyclopentadiene,” Carbon 184 (2021):855–863.
[8]

D. T. Genna, L. Y. Pfund, D. C. Samblanet, A. G Wong-Foy, A. J. Matzger, and M. S. Sanford, “Rhodium Hydrogenation Catalysts Supported in Metal Organic Frameworks: Influence of the Framework on Catalytic Activity and Selectivity,” ACS Catalysis 6 (2016):3569–3574.
[9]

D. Zhao, X. Li, K. Zhang, J. Guo, X. Huang, and G. Wang, “Recent Advances in Thermocatalytic Hydrogenation of Unsaturated Organic Compounds With Metal-Organic Frameworks-Based Materials: Construction Strategies and Related Mechanisms,” Coordination Chemistry Reviews 487 (2023): 215159.
[10]

W. Wang, J. Zhao, D. Jia, et al., “Highly Efficient Hydroisomerization of Endo-Tetrahydrodicyclopentadiene to Exo-Tetrahydrodicyclopentadiene Over Pt/Hy,” ACS Omega 6 (2021):17173–17182.
[11]

T. Ban, H.-M. Vu, J. Zhang, J.-Y. Yong, Q. Liu, and X.-Q. Li, “Rhodium-Catalyzed Azine-Directed C–H Amidation With N-Methoxyamides,” Journal of Organic Chemistry 87 (2022):5543–5555.
[12]

W. Xu, Y. Zhang, J. Wang, et al., “Defects Engineering Simultaneously Enhances Activity and Recyclability of MOFs in Selective Hydrogenation of Biomass,” Nature Communications 13 (2022): 2068.
[13]

L. Li, Z. Li, W. Yang, et al., “Integration of Pd Nanoparticles With Engineered Pore Walls in MOFs for Enhanced Catalysis,” Chem 7 (2021):686–698.
[14]

L. L. Ling, W. Yang, P. Yan, M. Wang, and H. L. Jiang, “Light-Assisted CO2 Hydrogenation Over Pd3Cu@UiO-66 Promoted by Active Sites in Close Proximity,” Angewandte Chemie International Edition 61 (2022): e202116396.
[15]

A. Gu, W. Tan, Z. Li, et al., “Preparation of Ag-MMOFs Composite and Its Degradation Properties on Nitrophenol, China Powder Science and Technology,” China Powder Science and Technology 28 (2022):15–23.
[16]

P. Parnicka, W. Lisowski, T. Klimczuk, A. Mikolajczyk, and A. Zaleska-Medynska, “A Novel (Ti/Ce)UiO-X MOFs@TiO2 Heterojunction for Enhanced Photocatalytic Performance: Boosting via Ce4+/Ce3+ and Ti4+/Ti3+ Redox Mediators,” Applied Catalysis B: Environmental 310 (2022): 121349.
[17]

S. Meng, G. Li, P. Wang, M. He, X. Sun, and Z. Li, “Rare Earth-Based MOFs for Photo/Electrocatalysis,” Materials Chemistry Frontiers 7 (2023):806–827.
[18]

W. Liu, S. Geng, N. Li, et al., “Highly Robust Microporous Metal-Organic Frameworks for Efficient Ethylene Purification Under Dry and Humid Conditions,” Angewandte Chemie International Edition 62 (2023): e202217662.
[19]

P. Yin, Q. Q. Yan, and H. W. Liang., “Strong Metal-Support Interactions Through Sulfur-Anchoring of Metal Catalysts on Carbon Supports,” Angewandte Chemie International Edition 62 (2023): e202302819.
[20]

X. Zhang, Z. Huang, M. Ferrandon, et al., “Catalytic Chemoselective Functionalization of Methane in a Metal–Organic Framework,” Nature Catalysis 1 (2018):356–362.
[21]

A. Wang, J. Li, and T. Zhang, “Heterogeneous Single-Atom Catalysis,” Nature Reviews Chemistry 2 (2018):65–81.
[22]

B. Qiao, A. Wang, X. Yang, et al., “Single-Atom Catalysis of CO Oxidation Using Pt1/FeOx,” Nature Chemistry 3 (2011):634–641.
[23]

S. H. Brodersen, U. Grønbjerg, B. Hvolbæk, and J. Schiøtz, “Understanding the Catalytic Activity of Gold Nanoparticles Through Multi-Scale Simulations,” Journal of Catalysis 284 (2011):34–41.
[24]

L. Zhang, M. Zhou, A. Wang, and T. Zhang, “Selective Hydrogenation Over Supported Metal Catalysts: From Nanoparticles to Single Atoms,” Chemical Reviews 120 (2020):683–733.
[25]

L. Liu and A. Corma, “Metal Catalysts for Heterogeneous Catalysis: From Single Atoms to Nanoclusters and Nanoparticles,” Chemical Reviews 118 (2018):4981–5079.
[26]

J. A. Farmer and C. T. Campbell, “Ceria Maintains Smaller Metal Catalyst Particles by Strong Metal-Support Bonding,” Science 329 (2010):933–936.
[27]

S. Zhou, T. Ban, T. Li, et al., “Defect Engineering in Ce-Based Metal–Organic Frameworks Toward Enhanced Catalytic Performance for Hydrogenation of Dicyclopentadiene,” ACS Applied Materials &Interfaces 16 (2024):38177–38187.
[28]

B. Zhang, Y. Sun, H. Xu, and X. He, “Hydrogen Storage Mechanism of Metal–Organic Framework Materials Based on Metal Centers and Organic Ligands,” Carbon Neutralization 2 (2023):632–645.
[29]

M. Zhao, K. Yuan, Y. Wang, et al., “Metal–Organic Frameworks as Selectivity Regulators for Hydrogenation Reactions,” Nature 539 (2016):76–80.
[30]

S. Ogihara, T. Komatsu, Y. Itoh, et al., “Metabolic-Pathway-Oriented Screening Targeting S-Adenosyl-L-Methionine Reveals the Epigenetic Remodeling Activities of Naturally Occurring Catechols,” Journal of the American Chemical Society 142 (2019):21–26.
[31]

X. Ma, H. Liu, W. Yang, G. Mao, L. Zheng, and H.-L. Jiang, “Modulating Coordination Environment of Single-Atom Catalysts and Their Proximity to Photosensitive Units for Boosting MOF Photocatalysis,” Journal of the American Chemical Society 143 (2021):12220–12229.
[32]

Y. Ma, X. Han, S. Xu, et al., “Atomically Dispersed Copper Sites in a Metal–Organic Framework for Reduction of Nitrogen Dioxide,” Journal of the American Chemical Society 143 (2021):10977–10985.
[33]

X. Yu and S. M. Cohen, “Photocatalytic Metal–Organic Frameworks for Selective 2, 2, 2-Trifluoroethylation of Styrenes,” Journal of the American Chemical Society 138 (2016):12320–12323.
[34]

B. An, L. Zeng, M. Jia, et al., “Molecular Iridium Complexes in Metal–Organic Frameworks Catalyze CO2Hydrogenation Via Concerted Proton and Hydride Transfer,” Journal of the American Chemical Society 139 (2017):17747–17750.
[35]

K. M. Choi, K. Na, G. A. Somorjai, and O. M. Yaghi, “Chemical Environment Control and Enhanced Catalytic Performance of Platinum Nanoparticles Embedded in Nanocrystalline Metal–Organic Frameworks,” Journal of the American Chemical Society 137 (2015):7810–7816.
[36]

S. Hu, C. Xie, Y.-P. Xu, et al., “Selectivity Control in the Direct CO Esterification over Pd@UiO-66: The Pd Location Matters,” Angewandte Chemi International Edition 64 (2023): e202311625.
[37]

Y. Wang, H. Sun, Z. Yang, Y. Zhu, and Y. Xia, “Bismuth-Based Metal-Organic Frameworks and Derivatives for Photocatalytic Applications in Energy and Environment: Advances and Challenges,” Carbon Neutralization 3 (2024):737–767.
[38]

W. Zhang, W. Shi, W. Ji, et al., “Microenvironment of MOF Channel Coordination With Pt NPs for Selective Hydrogenation of Unsaturated Aldehydes,” ACS Catalysis 10 (2020):5805–5813.
[39]

Y. Shen, T. Pan, P. Wu, et al., “Regulating Electronic Status of Platinum Nanoparticles by Metal–Organic Frameworks for Selective Catalysis,” CCS Chemistry 3 (2021):1607–1614.
[40]

S. Chen, G. Hai, H. Gao, et al., “Modulation of the Charge Transfer Behavior of Ni(Ii)-Doped NH2-MIL-125(Ti): Regulation of Ni Ions Content and Enhanced Photocatalytic CO2 Reduction Performance,” Chemical Engineering Journal 406 (2021): 126886.
[41]

Z. Wang, J. J. Liu, S. Y. Yin, et al., “Ultralong Near Infrared Room Temperature Phosphorescence in Cu(I) Metal-Organic Framework Based-on D–π–A–π–D Linkers,” Advanced Functional Materials 33 (2023): 202212985.
[42]

X.-P. Wu, L. Gagliardi, and D. G. Truhlar, “Cerium Metal–Organic Framework for Photocatalysis,” Journal of the American Chemical Society 140 (2018):7904–7912.
[43]

K. Murakami, Y. Sugawara, J. Tomita, A. Ishii, I. Oikawa, and H. Takamura, “The Low-Temperature Synthesis of Cation-Ordered Ce–Zr-Based Oxideviaan Intermediate Phase Between Ce and Fe,” Journal of Materials Chemistry A 10 (2022):21291–21299.
[44]

H. Chen, C. Liu, W. Guo, et al., “Functionalized UiO-66(Ce) for Photocatalytic Organic Transformation: The Role of Active Sites Modulated by Ligand Functionalization,” Catalysis Science &Technology 12 (2022):1812–1823.
[45]

M. Liu, S. Li, N. Tang, Y. Wang, X. Yang, and S. Wang, “Highly Efficient Capture of Phosphate From Water via Cerium-Doped Metal-Organic Frameworks,” Journal of Cleaner Production 265 (2020): 121782.
[46]

P. H. M Andrade, N. Henry, C. Volkringer, et al., “Iodine Uptake by Zr-/Hf-Based UiO-66 Materials: The Influence of Metal Substitution on Iodine Evolution,” ACS Applied Materials &Interfaces 14 (2022):29916–29933.
[47]

Z. Liu, L. Wang, C. Wang, et al., “Modulating the Strong Metal-Support Interactions by Regulating the Chemical Microenvironment of Pt Confined in MOFs for Low Temperature Hydrogenation of DCPD,” Chemical Engineering Journal 479 (2024): 147601.
[48]

M. Hao and Z. Li, “Efficient Visible Light Initiated One-Pot Syntheses of Secondary Amines From Nitro Aromatics and Benzyl Alcohols Over Pd@NH2-Uio-66(Zr),” Applied Catalysis B: Environmental 305 (2022): 121031.
[49]

G. C. Shearer, S. Chavan, S. Bordiga, S. Svelle, U. Olsbye, and K. P. Lillerud, “Defect Engineering: Tuning the Porosity and Composition of the Metal–Organic Framework UiO-66 via Modulated Synthesis,” Chemistry of Materials 28 (2016):3749–3761.
[50]

S. Dai, E. Montero-Lanzuela, A. Tissot, et al., “Room Temperature Design of Ce(iv)-MOFs: From Photocatalytic HER and OER to Overall Water Splitting Under Simulated Sunlight Irradiation,” Chemical Science 14 (2023):3451–3461.
[51]

M. Campanelli, T. Del Giacco, F. De Angelis, et al., “Solvent-Free Synthetic Route for Cerium(Iv) Metal–Organic Frameworks With UiO-66 Architecture and Their Photocatalytic Applications,” ACS Applied Materials &Interfaces 11 (2019):45031–45037.
[52]

L. Chu, J. Guo, Z. Huang, H. Yang, M. Yang, and G. Wang, “Excellent Catalytic Performance Over Acid-Treated MOF-808(Ce) for Oxidative Desulfurization of Dibenzothiophene,” Fuel 332 (2023): 126012.
[53]

H. Y. Wu, Y. Y. Qin, Y. H. Xiao, et al., “Boosting Activity and Selectivity of UiO-66 through Acidity/Alkalinity Functionalization in Dimethyl Carbonate Catalysis,” Small 19 (2023): 2208238.
[54]

J. Zhang, X. Fu, F. Xia, et al., “Core-Shell Nanostructured Ru@Ir–O Electrocatalysts for Superb Oxygen Evolution in Acid,” Small 18 (2022): 2108031.
[55]

J. Yang, Y. Shen, Y. Sun, J. Xian, Y. Long, and G. Li, “Ir Nanoparticles Anchored on Metal-Organic Frameworks for Efficient Overall Water Splitting Under pH-Universal Conditions,” Angewandte Chemie International Edition 17 (2023): e202302220.
[56]

G.-P. Lu, X. Li, L. Zhong, S. Li, and F. Chen, “Ru@UiO-66(Ce) Catalyzed Acceptorless Dehydrogenation of Primary Amines to Nitriles: The Roles of Lewis Acid–Base Pairs in the Reaction,” Green Chemistry 21 (2019):5386–5393.
[57]

X. Zheng, M. Qin, S. Ma, et al., “Strong Oxide-Support Interaction Over IrO2/V2O5 for Efficient pH-Universal Water Splitting,” Advanced Science 9 (2022): 2104636.
[58]

S. Rojas-Buzo, B. Bohigues, D. Salusso, A. Corma, M. Moliner, and S. Bordiga, “Synergic Effect of Isolated Ce3+and Ptδ+Species in UiO-66(Ce) for Heterogeneous Catalysis,” ACS Catalysis 13 (2023):9171–9180.
[59]

S. Rojas-Buzo, D. Salusso, F. Bonino, M. C. Paganini, and S. Bordiga, “Unraveling the Reversible Formation of Defective Ce3+Sites in the UiO-66(Ce) Material: A Multi-Technique Study,” Materials Today Chemistry 27 (2023): 101337.
[60]

H. Wang, G. Cui, H. Lu, et al., “Facilitating the Dry Reforming of Methane With Interfacial Synergistic Catalysis in an Ir@CeO2–x Catalyst,” Nature Communications 15 (2024): 3765.
[61]

M. Babucci, E. T. Conley, A. S. Hoffman, S. R. Bare, and B. C. Gates, “Iridium Pair Sites Anchored to Zr6O8 Nodes of the Metal–Organic Framework UiO-66 Catalyze Ethylene Hydrogenation,” Journal of Catalysis 411 (2022):177–186.
[62]

E. Guan, L. Debefve, M. Vasiliu, S. Zhang, D. A. Dixon, and B. C. Gates, “Mgo-Supported Iridium Metal Pair-Site Catalysts Are More Active and Resistant to CO Poisoning Than Analogous Single-Site Catalysts for Ethylene Hydrogenation and Hydrogen–Deuterium Exchange,” ACS Catalysis 9 (2019):9545–9553.
[63]

X. Zhou, P. Pulay, R. Hargitai, A. Stirling, and J. Mink, “Complete Assignment of Vibrational Spectra of 1, 5-Cyclooctadiene—A Theoretical and Experimental Infrared and Raman Study,” Spectrochimica Acta Part A: Molecular Spectroscopy 49A (1993):257–270.
[64]

J. Cao, Y. Lin, T. Shao, et al., “The Positive Role of Ir0 and OV on the Reduction of SO2 by CO Over Ir/CeO2,” Applied Surface Science 620 (2023): 156826.
[65]

T.-S. Nguyen, G. Postole, S. Loridant, et al., “Ultrastable Iridium–Ceria Nanopowders Synthesized in One Step by Solution Combustion for Catalytic Hydrogen Production,” Journal of Materials Chemistry A: Materials for Energy and Sustainability 2 (2014):19822–19832.
[66]

Z. Wang, L. Zhang, J. Ji, et al., “Catalytic Enhancement of Small Sizes of CeO2 Additives on Ir/Al2O3 for Toluene Oxidation,” Applied Surface Science 571 (2022): 151200.
[67]

S. F. Kurtoğlu, A. S. Hoffman, D. Akgül, et al., “Electronic Structure of Atomically Dispersed Supported Iridium Catalyst Controls Iridium Aggregation,” ACS Catalysis 10 (2020):12354–12358.
[68]

G. Zhao, G. Hai, P. Zhou, et al., “Electrochemical Oxidation of 5-Hydroxymethylfurfural on CeO2-Modified Co3O4 With Regulated Intermediate Adsorption and Promoted Charge Transfer,” Advanced Functional Materials 33 (2023): 2213170.
[69]

S. Li, S. Zhao, F. Hu, et al., “Exploring the Potential Ru-Based Catalysts for Commercial-Scale Polymer Electrolyte Membrane Water Electrolysis: A Systematic Review,” Progress in Materials Science 145 (2024): 101294.
[70]

N. Antil, M. Chauhan, N. Akhtar, et al., “Metal–Organic Framework-Encaged Monomeric Cobalt(III) Hydroperoxides Enable Chemoselective Methane Oxidation to Methanol,” ACS Catalysis 12 (2022):11159–11168.
[71]

G. Fang, F. Wei, J. Lin, et al., “Retrofitting Zr-Oxo Nodes of UiO-66 by Ru Single Atoms to Boost Methane Hydroxylation With Nearly Total Selectivity,” Journal of the American Chemical Society 145 (2023):13169–13180.
[72]

H. Liang, G. Chen, D. Liu, et al., “Exploring the Ni 3d Orbital Unpaired Electrons Induced Polarization Loss Based on Ni Single-Atoms Model Absorber,” Advanced Functional Materials 33 (2022): 2212604.
[73]

Y. Lykhach, S. M. Kozlov, T. Skála, et al., “Counting Electrons on Supported Nanoparticles,” Nature Materials 15 (2015):284–288.
[74]

L. Deng, S.-F. Hung, S. Liu, et al., “Accelerated Proton Transfer in Asymmetric Active Units for Sustainable Acidic Oxygen Evolution Reaction,” Journal of the American Chemical Society 146 (2024):23146–23157.
[75]

H. Wang, X. Liu, W. Yang, et al., “Surface-Clean Au 25 Nanoclusters in Modulated Microenvironment Enabled by Metal–Organic Frameworks for Enhanced Catalysis,” Journal of the American Chemical Society 144 (2022):22008–22017.
[76]

X. Zarate, E. Schott, and R. Arratia-Pérez, “Effects of the Peripheral Substituents (–NH2, –OH, –CH3, –H, –C6H5, –Cl, –CO2H and –NO2) on Molecular Properties of a Ni-Porphyrazine Dimers Family,” Polyhedron 50 (2013):131–138.
[77]

S. Guo, Y. Zhao, C. Wang, H. Jiang, and G. J. Cheng, “A Single-Atomic Noble Metal Enclosed Defective MOF Via Cryogenic UV Photoreduction for CO Oxidation With Ultrahigh Efficiency and Stability,” ACS Applied Materials &Interfaces 12 (2020):26068–26075.
[78]

C. Gao, Y. Su, X. Quan, et al., “Electronic Modulation of Iron-Bearing Heterogeneous Catalysts to Accelerate Fe(III)/Fe(II) Redox Cycle for Highly Efficient Fenton-Like Catalysis,” Applied Catalysis B: Environmental 276 (2020): 119016.
[79]

Y. Lykhach, S. M. Kozlov, T. Skála, et al., “Counting Electrons on Supported Nanoparticles,” Nature Materials 15 (2016):284–288.
[80]

Y. Zhao, K. R. Yang, Z. Wang, et al., “Stable Iridium Dinuclear Heterogeneous Catalysts Supported on Metal-Oxide Substrate for Solar Water Oxidation,” Proceedings of the National Academy of Sciences 115 (2018):2902–2907.
[81]

Z. Sun, M. Chen, K. Wang, et al., “Towards Scalable Reductive Etherification of 5-Hydroxymethyl-Furfural Through Iridium-Zeolite-Based Bifunctional Catalysis,” Green Chemistry 25 (2023):10381–10386.
[82]

Y. Hao, S.-F. Hung, L. Wang, et al., “Designing Neighboring-Site Activation of Single Atom via Tunnel Ions for Boosting Acidic Oxygen Evolution,” Nature Communications 15 (2024): 8015.
[83]

D. Yang, S. O. Odoh, J. Borycz, et al., “Tuning Zr6 Metal–Organic Framework (MOF) Nodes as Catalyst Supports: Site Densities and Electron-Donor Properties Influence Molecular Iridium Complexes as Ethylene Conversion Catalysts,” ACS Catalysis 6 (2016):235–247.
[84]

L. L. Ling, W. Yang, P. Yan, M. Wang, and H. L. Jiang. “Light-Assisted CO2 Hydrogenation over Pd3Cu@UiO-66 Promoted by Active Sites in Close Proximity,” Angewandte Chemie International Edition 61 (2022): e202116396.
[85]

C. Atzori, K. A. Lomachenko, J. Jacobsen, et al., “Bimetallic Hexanuclear Clusters in Ce/Zr-UiO-66 MOFs: In Situ FTIR Spectroscopy and Modelling Insights,” Dalton Transactions 49 (2020):5794–5797.
[86]

K. Shirayama, X. Jin, and K. Nozaki, “Selective Hydrogenation of Aldehydes Under Syngas Using CeO2-Supported Au Nanoparticle Catalyst,” Journal of the American Chemical Society 146 (2024):14086–14094.
[87]

J. Lu, P. Serna, and B. C. Gates, “Zeolite-and MgO-Supported Molecular Iridium Complexes: Support and Ligand Effects in Catalysis of Ethene Hydrogenation and H–D Exchange in the Conversion of H2+D2,” ACS Catalysis 1 (2011):1549–1561.
[88]

A. Uzun, V. Ortalan, N. D. Browning, and B. C. Gates, “A Site-Isolated Mononuclear Iridium Complex Catalyst Supported on MgO: Characterization by Spectroscopy and Aberration-Corrected Scanning Transmission Electron Microscopy,” Journal of Catalysis 269 (2010):318–328.
[89]

Q. Liu, Y. Li, Y. Fan, C.-Y. Su, and G. Li, “Chemoselective Hydrogenation of α β-Unsaturated Aldehydes Over Rh Nanoclusters Confined in a Metal–Organic Framework,” Journal of Materials Chemistry A 8 (2020):11442–11447.
[90]

R. Gao, L. Pan, H. Wang, et al., “Breaking Trade-Off between Selectivity and Activity of Nickel-Based Hydrogenation Catalysts by Tuning Both Steric Effect and d-Band Center,” Advanced Science 6 (2019): 1900054.
[91]

H. Zhao, C. Liu, Y. Zheng, et al., “Precisely Designed Nitrogen-Doped Mesoporous Carbon Sphere-Confined Electron-Deficient Pd Nanoclusters With Enhanced Catalytic Hydrogenation Performance,” ACS Catalysis 14 (2024):8619–8630.
[92]

L. Yu, H. Nie, P. Yang, H. Gao, and G. Wang, “Hydrogenation Reaction Mechanisms on Ni-Doped MoS2 Catalysts: A Density Functional Theory Study of Sulfur Edge Engineering and Coregulated Electronic Effects,” ACS Applied Materials &Interfaces 16 (2024):67839–67853.
[93]

H. Xu, D. Cheng, D. Cao, and X. C. Zeng, “RETRACTED ARTICLE: A Universal Principle for a Rational Design of Single-Atom Electrocatalysts,” Nature Catalysis 1 (2018):339–348.
[94]

R. Li, T. Ban, D. Zhao, et al., “Defect Engineering and Ni Promoter Synergistically Accelerating Electron Transfer to Ru0 Sites in UiO-66(Ce) for Dicyclopentadiene Hydrogenation Under Mild Condition,” Nano Research 17 (2024):9550–9563.

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