1.
NiCO2S4@graphene as a Bifunctional Electrocatalyst for Oxygen Redu..
[1103]
|
2.
Graphene Oxide Film as Solid Lubricant
[930]
|
3.
固体润滑薄膜结构与超低摩擦
[810]
|
4.
Understanding the ultra-low friction behavior of hydrogenated full..
[704]
|
5.
4种马来酸酐接枝物对PA66/TLCP共混物界面的增容作用
[696]
|
6.
Ultralow friction behaviors of hydrogenated fullerene-like carbon ..
[663]
|
7.
Friction and wear behavior polyamide 66/poly(vinylidene fluoride) ..
[580]
|
8.
Hydrophobic, mechanical and tribological properties of fluorine in..
[560]
|
9.
一种含氢纳米结构CNx梯度薄膜的制备方法
[540]
|
10.
Mechanical properties and tribological behavior of fullerene-like ..
[534]
|
11.
三价铬电镀硬铬及镀层性能的研究
[522]
|
12.
DLC薄膜技术在汽车发动机关键零部件的应用研究
[515]
|
13.
Graphene Supported Co-g-C3N4 as a Novel Metal-Macrocyclic Electroc..
[497]
|
14.
Nitrogen-doped porous carbon nanosheets made from biomass as highl..
[497]
|
15.
Spontaneous symmetry breaking discovers the formation of aeroplane..
[495]
|
16.
FeCo-N-x embedded graphene as high performance catalysts for oxyge..
[491]
|
17.
The effect of a static magnetic field on the hydrogen bonding in w..
[467]
|
18.
Lower friction and higher wear resistance of fluorine-incorporated..
[461]
|
19.
Catalyst-Free Synthesis of Crumpled Boron and Nitrogen Co-Doped Gr..
[458]
|
20.
润滑添加剂的分子结构与摩擦学性能
[453]
|
21.
Silver Nanoparticles Capped by Oleylamine: Formation, Growth, and ..
[452]
|
22.
Growth and structure of hydrogenated carbon films containing fulle..
[448]
|
23.
Why the decorative chromium coating electrodeposited from trivalen..
[448]
|
24.
Direct Synthesis of Nitrogen-Doped Carbon Nanosheets with High Sur..
[444]
|
25.
Transforming organic molecular films into carbon films as solid lu..
[443]
|
26.
Designed fabrication of hard Cr—Cr2O3—Cr7C3 nanocomposite coatin..
[439]
|
27.
Super-low friction and super-elastic hydrogenated carbon films ori..
[438]
|
28.
A general and controllable synthesis of ComSn (Co9S8, Co3S4, and C..
[438]
|
29.
Ultra-low friction of fluorine-doped hydrogenated carbon film with..
[437]
|
30.
Improving the internal stress and wear resistance of DLC film by l..
[429]
|
31.
From sphere to polyhedron: A hypothesis on the formation of high-i..
[412]
|
32.
模具钢表面多层梯度纳米复合类金刚石薄膜的制备方法
[408]
|
33.
类富勒烯碳膜的制备方法
[391]
|
34.
Study on the anti-reflection and structure evolution of hydrogenat..
[387]
|
35.
Efficient Oxygen Reduction Electrocatalyst Based on Edge-Nitrogen-..
[387]
|
36.
Mechanical and tribological properties of Ti-DLC films with differ..
[380]
|
37.
Ultra-elastic recovery and low friction of amorphous carbon films ..
[380]
|
38.
Advanced Oxygen Reduction Electrocatalyst Based on Nitrogen-Doped ..
[379]
|
39.
Facile synthesis of CNTs-doped diamond-like carbon film by electro..
[376]
|
40.
Controllable preparation of fluorine-containing fullerene-like car..
[376]
|
41.
Photochemical grafting of fluorinate alkenes on DLC coated Ti6Al4V..
[375]
|
42.
A general method for the preparation of a thickness-controllable f..
[371]
|
43.
Anti-wear properties of Cr-C and Ni-Co alloy coatings as substitut..
[370]
|
44.
Graphene oxide as efficient high-concentration formaldehyde scaven..
[368]
|
45.
Electrochemical corrosion behavior of nanocrystalline Co coatings ..
[366]
|
46.
Cathode electrodeposition and characterization of Ru nanoparticles..
[356]
|
47.
Nanocrystalline diamond embedded in hydrogenated fullerenelike car..
[356]
|
48.
Annealing improves tribological property of poly(octadecene-alt-ma..
[354]
|
49.
Preparation and biocompatibility of BSA monolayer on slicon surfac..
[354]
|
50.
Photocarrier Promoted Pore and Inverted Pyramid Formation in Porou..
[350]
|
51.
Ultralow friction regime from the in situ production of a richer f..
[349]
|
52.
Deposition of hard elastic hydrogenated fullerenelike carbon films
[348]
|
53.
Mechanism for wettability alteration of ZnO nanorod arrays via the..
[346]
|
54.
Graphene-based non-noble-metal Co/N/C catalyst for oxygen reductio..
[346]
|
55.
Increasing fluorine concentration to control the microstructure fr..
[345]
|
56.
Fabrication of Superhydrophobic Surfaces on Engineering Materials ..
[340]
|
57.
Graphene-xerogel-based non-precious metal catalyst for oxygen redu..
[340]
|
58.
Structure characterization and tribological properties of thick ch..
[340]
|
59.
Surfactant Inducing Phase Change of ZnO Nanorods to Low Friction
[338]
|
60.
Identifying the Active Site in Nitrogen-Doped Graphene for the VO2..
[337]
|
61.
A fluorine-contained copolymer ultra-thin film: Stability and elec..
[336]
|
62.
Preparation and tribological properties of self-assembled poly(ami..
[333]
|
63.
凹凸棒粘土改性聚合物材料的研究进展
[329]
|
64.
在不锈钢上制备薄膜的方法
[322]
|
65.
Tribological performance of fluoroalkylsilane modification of sol..
[321]
|
66.
Electrochemical corrosion behavior of carbon nanotube-doped hard c..
[318]
|
67.
Good electrical and mechanical properties induced by the multilaye..
[317]
|
68.
以环戊二烯为碳源制备类富勒烯结构碳基薄膜的结构及力学性能
[307]
|
69.
类金刚石碳基薄膜在1-乙基-3-甲基咪唑四氟硼酸盐中的摩擦学性能
[306]
|
70.
Effects of negative bias on the structural,topological and tribolo..
[305]
|
71.
Investigation of the friction and wear behaviors of Cu(I) and Cu(I..
[304]
|
72.
Field emission properties of DLC and phosphorus-doped DLC films pr..
[303]
|
73.
Fullerene nanostructure-induced excellent mechanical properties in..
[303]
|
74.
Fabrication of superhydrophobic surfaces by a Pt nanowire array on..
[301]
|
75.
Comparative studies between synthetic routes of SiO2@Au composite ..
[300]
|
76.
Characterization of tribofilms derived from zinc dialkyldithiophos..
[296]
|
77.
Preparation of Crystalline Chromium Coating on Cu Substrate Direct..
[296]
|
78.
Fabrication and wear protection performance of superhydrophobic su..
[294]
|
79.
Comparing internal stress in diamond-like carbon films with differ..
[293]
|
80.
Engineering-scale superlubricity of the fingerprintlike carbon fil..
[289]
|
81.
The effect of thermal annealing on the microstructure and mechanic..
[288]
|
82.
Conciliating surface superhydrophobicities and mechanical strength..
[287]
|
83.
Fabrication of a nanocrystalline Cr–C layer with excellent anti-w..
[287]
|
84.
Design and evaluation of a mixed monolayer consisting of alkylsila..
[287]
|
85.
Template-synthesized protein nanotubes with controlled size based ..
[285]
|
86.
Mechanical and Tribological Behaviors of Polyamide 66/Ultra High M..
[284]
|
87.
Further improving the mechanical and tribological properties of lo..
[281]
|
88.
Structure, mechanical, and frictional properties of hydrogenated f..
[281]
|
89.
The tribological properties of fullerene-like hydrogenated carbon ..
[280]
|
90.
A facile method for preparing a non-adhesive superhydrophobic ZnO ..
[279]
|
91.
Electrochemical corrosion behavior of chromium–phosphorus coating..
[278]
|
92.
Formation and tribology study of amide-containing stratified self-..
[278]
|
93.
Enhanced tribology durability of a self-assembled monolayer of alk..
[278]
|
94.
Influence of nitrogen content on the structural, electrical and me..
[278]
|
95.
Effects of Ar/H/N-ion bombardment on the surface free energy and f..
[276]
|
96.
聚酰胺胺类树枝形聚合物(PAMAM)插入式自组装膜的制备与摩擦学性能:小分..
[273]
|
97.
在钛合金表面制备生物活性复合薄膜的方法
[273]
|
98.
Elastic properties of a-C:N:H films
[271]
|
99.
Fabrication and electrochemistry study of multi-thiol coronary mol..
[268]
|
100.
Morphological, thermal and mechanical propertie of compatibilized ..
[265]
|