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1. Gas-assisted transformation of gold from fcc to the metastable 4H .. [62]
2. Exposing Cu-rich {110} active facets in PtCu nanostars for boostin.. [37]
3. Enantioselective photoinduced cyclodimerization of a prochiral ant.. [35]
4. Catalytic mechanism and bonding analyses of Au-Pd single atom allo.. [32]
5. Catalytic performance and reaction mechanism of NO oxidation over .. [31]
6. N-Coordinated Dual-Metal Single-Site Catalyst for Low-Temperature .. [29]
7. In-situ polymerization induced atomically dispersed manganese site.. [28]
8. Rational design of copper-based single-atom alloy catalysts for el.. [28]
9. Unraveling the catalytically active phase of carbon dioxide hydrog.. [24]
10. Synergistic effect of Ru-N4 sites and Cu-N3 sites in carbon nitrid.. [24]
11. Surface-structure tailoring of ultrafine PtCu nanowires for enhanc.. [23]
12. Diffusion and Surface Segregation of Interstitial Ti Defects Induc.. [23]
13. Mechanistic Insight into the Oxygen Reduction Reaction on the Mn-N.. [21]
14. Fast Transformation of CO2into CO Via a Hydrogen Bond Network on t.. [21]
15. Dopant-Free Phthalocyanine Hole Conductor with Thermal-Induced Hol.. [21]
16. Mechanistic insight into the catalytically active phase of CO2 hyd.. [20]
17. Direct transformation of lignin into fluorescence-switchable graph.. [19]
18. Lattice oxygen self-spillover on reducible oxide supported metal c.. [19]
19. Single-element amorphous palladium nanoparticles formed via phase .. [19]
20. Atomic origin of CO-Interaction effect of PtPb@Pt catalyst reveale.. [18]
21. Potential-Dependent Free Energy Relationship in Interpreting theEl.. [18]
22. Engineering of Coordination Environment and Multiscale Structure i.. [17]
23. Pseudo-adsorption and long-range redox coupling during oxygen redu.. [17]
24. Heterogeneous Single-Cluster Catalysts for Selective Semihydrogena.. [15]
25. Molecular engineering of dispersed nickel phthalocyanines on carbo.. [15]
26. Carbon Monoxide Gas Induced 4H-to- fcc Phase Transformation of Gol.. [15]
27. Surface Brønsted-Lewis dual acid sites for high-efficiency dinitr.. [14]
28. Kinetic diffusion-controlled synthesis of twinned intermetallic na.. [13]
29. Theoretical understanding of the stability of single-atom catalyst.. [12]
30. Tandem catalyzing the hydrodeoxygenation of 5-hydroxymethylfurfura.. [12]
31. Solvent promotion on the metal-support interaction and activity of.. [12]
32. Unravelling the Enigma of Nonoxidative Conversion of Methane on Ir.. [11]
33. Mechanistic insight into methanol electro-oxidation catalyzed by P.. [11]
34. Tuning phase compositions of MoS2 nanomaterials for enhanced heavy.. [11]
35. 铂铜合金催化甲醇电氧化的机理研究 [10]
36. Phosphorene Supported Single-Atom Catalysts for CO Oxidation: A Co.. [9]
37. Carbon corrosion mechanism on nitrogen-doped carbon support — A d.. [9]
38. Fully exposed palladium cluster catalysts enable hydrogen producti.. [9]
39. Heterogeneous Two-Atom Single-Cluster Catalysts for the Nitrogen E.. [8]
40. Non-noble metal single-atom catalyst with MXene support: Fe1/Ti2CO.. [8]
41. Modeling the Potential-Dependent Kinetics of CO2 Electroreduction .. [8]
42. Molecular Design of Dispersed Nickel Phthalocyanine@Nanocarbon Hyb.. [7]
43. Solvation enhanced long-range proton transfer in aqueous phase for.. [7]
44. Supported Metal Clusters: Fabrication and Application in Heterogen.. [6]
45. Using general computational chemistry strategy to unravel the reac.. [6]
46. Special Issue of Single-atom Catalysis [6]
47. Screened Fe-3 and Ru-3 Single-Cluster Catalysts Anchored on MoS2 S.. [6]
48. Continuous constant potential model for describing the potential-d.. [6]
49. Atomic metal–non-metal catalytic pair drives efficient hydrogen o.. [6]
50. How interfacial electron-donating defects influence the structure .. [6]
51. Tailoring the Active-Site Spacing of a Single-Atom Catalyst for CH.. [6]
52. Conjugated linker-boosted self-assembled monolayer molecule for in.. [6]
53. Exploring electronic-level principles how size reduction enhances .. [5]
54. Modeling Interfacial Dynamics on Single Atom Electrocatalysts: Exp.. [5]
55. Potential Dependence and Substituent Effect in CO2 Elec.. [5]
56. Controlling the Selectivity of Electrocatalytic NO Reduction throu.. [5]
57. Critical Role of Explicit Inclusion of Solvent and Electrode Poten.. [4]
58. Spontaneous decoration of ionic compounds at perovskite interfaces.. [4]
59. Dynamic simulation on surface hydration and dehydration of monocli.. [3]
60. Aldehyde Hydrogenation by Pt/TiO2 Catalyst in Aqueous Phase: Syner.. [3]
61. Breaking the C[sbnd]C bond of glucose on tungsten oxide-based cata.. [3]
62. Realistic Modeling of the Electrocatalytic Process at Complex Soli.. [3]
63. Atomic metal-non-metal catalytic pair drives efficient hydrogen ox.. [3]
64. Phosphorus coordinated Co/Se2 heterointerface nanowires: in-situ c.. [3]
65. Enhancing perovskite solar cell performance through dynamic hydrog.. [3]
66. Formation of Supernarrow Borophene Nanoribbons [3]
67. Unraveling the Reasons Behind SnO2/Perovskite Defects a.. [3]
68. Crystalline Lattice-Confined Atomic Pt in Metal Carbides to Match .. [2]
69. Three-Dimensional Silicene-Based Materials: A Universal Anode for .. [2]
70. Mechanistic exploration of furfural hydrogenation on copper surfac.. [2]
71. Anisotropic Growth of One-Dimensional Carbides in Single-Walled Ca.. [2]
72. Catalytic Activity Coupled with Structural Stability within a Hete.. [2]
73. 3D porous sulfur-graphdiyne with splendid electrocatalytic and ene.. [2]
74. First-row transition metal carbide nanosheets as high-performance .. [2]
75. Coverage-Induced Cation Dehydration and Migration for Enhanced CO-.. [2]
76. Mechanistic Insight into the Superior Catalytic Activity of Au/Co<.. [2]
77. Binary Microcrystal Additives Enabled Antisolvent-Free Perovskite .. [1]
78. Fully Exposed Iridium Clusters Enable Efficient Hydrogenation of N.. [1]
79. Constant Potential Thermodynamic Integration for Obtaining the Fre.. [1]
80. Metal–N4 model single-atom catalyst with electroneutral quadri-py.. [1]
81. Synthesis of Metal-Nitrogen-Carbon Electrocatalysts with Atomicall.. [1]
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