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总访问量

428

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  • 外部: 396

  • 国内: 364

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1. AuB8-: an Au-borozene complex [2683]
2. Non defect-stabilized thermally stable single-atom catalyst [816]
3. Ruthenium/titanium oxide interface promoted electrochemical nitrog.. [722]
4. Ultrahigh-Loading of Ir Single Atoms on NiO Matrix to Dramatically.. [537]
5. Scalable two-step annealing method for preparing ultra-high-densit.. [444]
6. Molecular engineering of dispersed nickel phthalocyanines on carbo.. [342]
7. Infrared Spectroscopy of Neutral Water Dimer Based on a Tunable Va.. [293]
8. Infrared spectroscopic study of hydrogen bonding topologies in the.. [280]
9. Chromium Single-Atom Catalyst with Graphyne Support: A Theoretical.. [249]
10. Gas-assisted transformation of gold from fcc to the metastable 4H .. [230]
11. Coordination engineering of iridium nanocluster bifunctional elect.. [189]
12. Identification of the Electronic and Structural Dynamics of Cataly.. [173]
13. Atomically-precise dopant-controlled single cluster catalysis for .. [163]
14. Carbon Monoxide Gas Induced 4H-to- fcc Phase Transformation of Gol.. [159]
15. Publisher Correction: Scalable two-step annealing method for prepa.. [157]
16. Infrared spectroscopy of neutral water clusters at finite temperat.. [155]
17. Catalytic mechanism and bonding analyses of Au-Pd single atom allo.. [141]
18. Multiple Bonding Between Group 3 Metals and Fe(CO)3− [138]
19. High-loading and thermally stable Pt-1/MgAl1.2Fe0.8O4 single-atom .. [138]
20. Single-Atom AuI-N3 Site for Acetylene Hydrochlorination Reaction [130]
21. Physical origin of chemical periodicities in the system of element.. [127]
22. Non-noble metal single-atom catalyst of Co-1/MXene (Mo2CS2) for CO.. [119]
23. Atomic metal-non-metal catalytic pair drives efficient hydrogen ox.. [119]
24. Non-noble metal single-atom catalysts with phosphotungstic acid (P.. [116]
25. Underpotential-deposition synthesis and in-line electrochemical an.. [116]
26. Unveiling the In Situ Generation of a Monovalent Fe(I) Site in the.. [116]
27. Giant Emission Enhancement of Solid-State Gold Nanoclusters by Sur.. [114]
28. Dual Metal Active Sites in an Ir-1/FeOx Single-Atom Catalyst: A Re.. [114]
29. Understanding the Uniqueness of 2p Elements in Periodic Tables [114]
30. Theoretical Understandings of Graphene-based Metal Single-Atom Cat.. [113]
31. Remarkable active-site dependent H2O promoting effect in CO oxidat.. [108]
32. Three-dimensional open nano-netcage electrocatalysts for efficient.. [107]
33. Triazine COF-supported single-atom catalyst (Pd1/trzn-COF) for CO .. [106]
34. Unraveling the coordination structure-performance relationship in .. [105]
35. Quadruple bonding between iron and boron in the BFe(CO)(3)(-) comp.. [105]
36. Dual Metal Active Sites in an Ir1/FeOx Single-Atom Catalyst: A Red.. [105]
37. Size sensitivity of supported Ru catalysts for ammonia synthesis: .. [105]
38. Co13O8- Metalloxocubes: A new class of perovskite-like neutral clu.. [100]
39. Theoretical studies of MXene-supported single-atom catalysts: Os-1.. [100]
40. Theoretical Inspection of M1/PMA Single-Atom Electrocatalyst: Ultr.. [99]
41. Impeded degradation of perovskite solar cells via the dual interfa.. [99]
42. Rational design of copper-based single-atom alloy catalysts for el.. [96]
43. Unravelling the Enigma of Nonoxidative Conversion of Methane on Ir.. [95]
44. Using general computational chemistry strategy to unravel the reac.. [93]
45. Selective hydrogenation of acetylene on graphene-supported non-nob.. [92]
46. Phosphorene Supported Single-Atom Catalysts for CO Oxidation: A Co.. [91]
47. Electronic Structure and Spectroscopic Properties of Group-7 Tri-O.. [91]
48. Understanding the Electronic Structure and Stability of BnXn0/2– .. [90]
49. Tandem catalyzing the hydrodeoxygenation of 5-hydroxymethylfurfura.. [88]
50. Boosting the overall electrochemical water splitting performance o.. [88]
51. Constructing High-Loading Single-Atom/Cluster Catalysts via an Ele.. [87]
52. Vertically stacked RGB LEDs with optimized distributed Bragg refle.. [87]
53. The df-d Dative Bonding in a Uranium-Cobalt Heterobimetallic Compl.. [85]
54. A Single-Atom Manipulation Approach for Synthesis of Atomically Mi.. [85]
55. Dynamic Frustrated Lewis Pairs on Ceria for Direct Nonoxidative Co.. [84]
56. Lanthanides with Unusually Low Oxidation States in the PrB3- and P.. [83]
57. Single Iridium Atom Doped Ni2P Catalyst for Optimal Oxygen Evoluti.. [83]
58. Molecular nitrogen promotes catalytic hydrodeoxygenation [80]
59. Planar B41- and B42- c.. [79]
60. Few-Atom Pt Ensembles Enable Efficient Catalytic Cyclohexane Dehyd.. [79]
61. Unravelling a general mechanism of converting ionic B/N complexes .. [78]
62. Breaking Long-Range Order in Iridium Oxide by Alkali Ion for Effic.. [77]
63. Progress toward larger molecular simulation on a quantum computer:.. [77]
64. Rh single atoms on TiO2 dynamically respond to reaction conditions.. [76]
65. Heterogeneous Single-Cluster Catalysts for Selective Semihydrogena.. [75]
66. Excited-State Chemistry: Photocatalytic Methanol Oxidation by Uran.. [75]
67. Unravelling a general mechanism of converting ionic B/N complexes .. [74]
68. Cooperative Catalysis by Multiple Active Centers in Nonoxidative C.. [74]
69. Infrared spectroscopic signature of the structural diversity of th.. [74]
70. [La(eta(x)-B-x)La](-) (x=7-9): a new class of inverse sandwich com.. [73]
71. Identifying Key Descriptors for the Single-Atom Catalyzed CO Oxida.. [73]
72. Bonding Nature of "Ionic Carbenes" in [M-3(mu(3)-CH2)]-Containing .. [73]
73. Revisiting the Intriguing Electronic Features of the BeOBeC Carbyn.. [72]
74. Understanding Periodic and Non-periodic Chemistry in Periodic Tabl.. [72]
75. The smallest 4f-metalla-aromatic molecule of cyclo-PrB2- with Pr-B.. [72]
76. The Key Role of Support Surface Hydrogenation in the CH4 to CH3OH .. [71]
77. Formation and Characterization of a BeOBeC Multiple Radical Featur.. [71]
78. 2-Butene Tetraanion Bridged Dinuclear Samarium(III) Complexes via .. [70]
79. Exploring the difference of bonding strength between silver(i) and.. [70]
80. Coordination Sphere of Lanthanide Aqua Ions Resolved with Ab Initi.. [70]
81. Triple bonds between iron and heavier group-14 elements in the AFe.. [69]
82. Interplay between remote single-atom active sites triggers speedy .. [69]
83. Metal Oxo-Fluoride Molecules OnMF2 (M = Mn and Fe; n=1-4) and O2Mn.. [68]
84. Highly efficient ammonia synthesis at low temperature over a Ru-Co.. [66]
85. Norm-Conserving Pseudopotentials and Basis Sets to Explore Actinid.. [66]
86. Exploring Stability of Transition-Metal Single Atoms on Cu2O Surfa.. [66]
87. An Ultrastable Matryoshka [Hf-13] Nanocluster as a Luminescent Sen.. [65]
88. Heterogeneous Two-Atom Single-Cluster Catalysts for the Nitrogen E.. [65]
89. Spherical trihedral metallo-borospherenes [64]
90. Critical Role of Explicit Inclusion of Solvent and Electrode Poten.. [64]
91. A polyoxometalate cluster-based single-atom catalyst for NH3 synth.. [62]
92. An ultrastable Ti-based metallocalixarene nanocage cluster with ph.. [61]
93. Mechanistic Investigations on Thermal Hydrogenation of CO2 to Meth.. [59]
94. Non-noble metal single-atom catalyst with MXene support: Fe1/Ti2CO.. [59]
95. 基于ReaxFF的甲烷无氧转化气相机理研究(英文) [58]
96. Integrating Dissociative and Associative Routes for Efficient Ammo.. [58]
97. An unexpected all-metal aromatic tetranuclear silver cluster in hu.. [58]
98. Recent Progresses in the Investigation of Rare-earth Boron Inverse.. [57]
99. Breaking the scaling relations for efficient N-2-to-NH3 conversion.. [57]
100. La3B14-: an inverse triple-decker lanthanide boron cluster [56]
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1. Three-dimensional open nano-netcage electrocatalysts for efficient.. [1]
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