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年访问量

123

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总访问量

835

  • 内部: 124

  • 外部: 711

  • 国内: 714

  • 国外: 121

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1. Highly selective and active CO2 reduction electro-catalysts based .. [1236]
2. Strongly Coupled lnorganic/Nanocarbon Hybrid Materials for Advance.. [1135]
3. Methyl Thioether Functionalization of a Polymeric Donor for Effici.. [1060]
4. Rational Design of Molecular Fluorophores for Biological Imaging i.. [985]
5. Domino electroreduction of CO2 to methanol on a molecular catalyst [947]
6. Active sites of copper-complex catalytic materials for electrochem.. [902]
7. Facile Synthesis of Nickel-Iron/Nanocarbon Hybrids as Advanced Ele.. [688]
8. Traumatic Brain Injury Imaging in the Second Near-Infrared Window .. [602]
9. Iron-Doped Cobalt Monophosphide Nanosheet/ Carbon Nanotube Hybrids.. [520]
10. 共轭分子材料的功能化及应用 [397]
11. Molecular engineering of dispersed nickel phthalocyanines on carbo.. [344]
12. Molecular imaging of biological systems with a clickable dye in th.. [309]
13. Co-N4大环配合物分子应用于异相电催化CO2还原 [217]
14. Tracing the Origin of Visible Light Enhanced Oxygen Evolution Reac.. [215]
15. Donor Engineering for NIR-II Molecular Fluorophores with Enhanced .. [193]
16. Stable cycling of mesoporous Sn4P3/SnO2@C nanosphere anode with hi.. [192]
17. Phthalocyanine Precursors To Construct Atomically Dispersed Iron E.. [187]
18. Organic Spherical Nucleic Acids for the Transport of a NIR-II-Emit.. [164]
19. Design of active nickel single-atom decorated MoS2 as a pH-univers.. [151]
20. Propylenedioxy Thiophene Donor to Achieve NIR-II Molecular Fluorop.. [151]
21. Revealing the hidden performance of metal phthalocyanines for CO_2.. [145]
22. Multiplexed NIR-II Probes for Lymph Node-Invaded Cancer Detection .. [142]
23. A bright organic NIR-II nanofluorophore for three-dimensional imag.. [141]
24. Developing a Bright NIR-II Fluorophore with Fast Renal Excretion a.. [133]
25. Head-to-Head Linkage Containing Dialkoxybithiophene-Based Polymeri.. [128]
26. Effect of dipole moment on dye-sensitized solar cells [122]
27. Phthalocyanine precursors to construct atomically dispersed metal .. [121]
28. Magnetic "Squashing" of Circulating Tumor Cells on Plasmonic Subst.. [120]
29. 面向高性能高分子光探测器的分子设计 [119]
30. IN VIVO VASCULAR IMAGING OF TRAUMATIC BRAIN INJURY IN THE SECOND N.. [111]
31. Rational design of a super-contrast NIR-II fluorophore affords hig.. [108]
32. Establishing Multifunctional Interface Layer of Perovskite Ligand .. [108]
33. General Construction of Molybdenum-Based Nanowire Arrays for pH-Un.. [107]
34. Shielding Unit Engineering of NIR-II Molecular Fluorophores for Im.. [106]
35. Materials Design via Optimized Intramolecular Noncovalent Interact.. [105]
36. Light-sheet microscopy in the near-infrared II window [103]
37. Metal phthalocyanines to construct advanced single metal site elec.. [102]
38. Naphthodithiophene-Based Semiconducting Materials for Applications.. [102]
39. Nanographene–Osmapentalyne Complexes as a Cathode Interlayer in O.. [101]
40. High-Performance Fullerene-Free Polymer Solar Cells Featuring Effi.. [100]
41. Molecular Cancer Imaging in the Second Near-Infrared Window Using .. [99]
42. Molybdenum Phosphide/Carbon Nanotube Hybrids as pH-Universal Elect.. [99]
43. Recent Advances in Interface Engineering for Planar Heterojunction.. [98]
44. Multiplexed evaluation of immunity against SARS-CoV-2 variants usi.. [97]
45. Self-Cleaning Catalyst Electrodes for Stabilized CO2 Reduction to .. [96]
46. Visible to Near-Infrared Fluorescence Enhanced Cellular Imaging on.. [96]
47. SiRNA Delivery with PEGylated Graphene Oxide Nan osheets for Combi.. [95]
48. An efficient and thickness insensitive cathode interface material .. [94]
49. Monodisperse, nanoporous ceria microspheres embedded with Pt nanop.. [94]
50. Enhanced performance of inverted perovskite solar cells using solu.. [93]
51. Engineering MoS2 Basal Planes for Hydrogen Evolution via Synergist.. [92]
52. In Situ Tin(II) Complex Antisolvent Process Featuring Simultaneous.. [91]
53. Direct electrosynthesis of methylamine from carbon dioxide and nit.. [91]
54. Development of a high quantum yield dye for tumour imaging [90]
55. Thieno[3,4-c]pyrrole-4,6(5H)-dione Polymers with Optimized Energy .. [90]
56. A bio-inspired O 2 .. [89]
57. High Performance, Multiplexed Lung Cancer Biomarker Detection on a.. [88]
58. Assessing the energy offset at the electron donor/acceptor interfa.. [87]
59. High brightness NIR-II nanofluorophores based on fused-ring accept.. [87]
60. Brain imaging with near-infrared fluorophores [84]
61. Nickel Hydr(oxy)oxide Nanoparticles on Metallic MoS2 Nanosheets: A.. [84]
62. A non-fullerene small molecule processed with green solvent as an .. [84]
63. Proteoliposome-based full-length ZnT8 self-antigen for type 1 diab.. [84]
64. Molecular Engineering on Conjugated Side Chain for Polymer Solar C.. [84]
65. 3D NIR-II Molecular Imaging Distinguishes Targeted Organs with Hig.. [83]
66. Metal Phthalocyanine-Derived Single-Atom Catalysts for Selective C.. [83]
67. Combining ZnO and PDINO as a Thick Cathode Interface Layer for Pol.. [81]
68. Methyl functionalization on conjugated side chains for polymer sol.. [80]
69. Organic Spherical NucleicAcids for the Transport ofaNIR-II-Emittin.. [80]
70. Theory-Driven Design of Electrocatalysts for the Two-Electron Oxyg.. [79]
71. Dithieno[3,2-b:2 ',3 '-d]pyran-containing organic D-pi-A sensitize.. [77]
72. Stability of organic solar cells (OSCs) [77]
73. Sensitively detecting antigen of SARS-CoV-2 by NIR-II fluorescent .. [75]
74. Rational design of conjugated side chains for high-performance all.. [73]
75. Head-to-Head Linkage Containing Bithiophene-Based Polymeric Semico.. [73]
76. A theranostic agent for cancer therapy and imaging in the second n.. [72]
77. Regulating Morphological Features of Nickel Single-Atom Catalysts .. [72]
78. Highly active oxygen evolution integrated with efficient CO2 to CO.. [71]
79. Transition-Metal Doped Ceria Microspheres with Nanoporous Structur.. [69]
80. Toward Highly Sensitive Polymer Photodetectors by Molecular Engine.. [66]
81. Selective and High Current CO2 Electro-Reduction to Multicarbon Pr.. [66]
82. Cobalt-N4 macrocyclic complexes for heterogeneous electrocatalysis.. [66]
83. Low-Dose NIR-II Preclinical Bioimaging Using Liposome-Encapsulated.. [61]
84. Cobalt oxide/nanocarbon hybrid materials as alternative cathode ca.. [60]
85. Heterogeneous Molecular Catalysts of Metal Phthalocyanines for Ele.. [60]
86. Interfacial Layer Engineering for Performance Enhancement in Polym.. [57]
87. Rational Design of High Brightness NIR-II Organic Dyes with S-D-A-.. [56]
88. Furan Donor for NIR-II Molecular Fluorophores with Enhanced Bioima.. [56]
89. Zinc acetylacetonate doping for enhanced cathode interface layer i.. [55]
90. 3,4-Ethylenedithio thiophene donor for NIR-II fluorophores with im.. [55]
91. Accessing Organonitrogen Compounds via C-N Coupling in Electrocata.. [54]
92. Molecular Catalyst with Near 100% Selectivity for CO2 Reduction in.. [54]
93. Aggregation-Induced Emission (AIE), Life and Health [50]
94. Dispersed Nickel Phthalocyanine Molecules on Carbon Nanotubes as C.. [46]
95. Deciphering the selectivity descriptors of heterogeneous metal pht.. [45]
96. Molecular electrocatalysts for rapid and selective reduction of ni.. [45]
97. 金属酞菁电催化剂的分子调控 [44]
98. Reply To: Confined molecular catalysts provide an alternative inte.. [41]
99. A bio-inspired O2-tolerant catalytic CO2 reduction electrode [37]
100. Amine-Functionalized Carbon Dots as PEDOT:PSS Dopants for Organic .. [32]
下载量
1. Recent Advances in Interface Engineering for Planar Heterojunction.. [1]
2. Transition-Metal Doped Ceria Microspheres with Nanoporous Structur.. [1]
3. Multiplexed evaluation of immunity against SARS-CoV-2 variants usi.. [1]
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