共找到11條詞條名為陳煜的結果 展開
陳煜
陝西師範大學教授
理學博士,南京大學,2006.09-2009.02
教授 (博導),陝西師範大學,2015.12-至今
男,博士,教授。2003–2006年期間,師從南京師範大學陸天虹研究員攻讀碩士學位,研究方向為燃料電池;2006–2009年期間,師從南京大學鄭麗敏教授和夏興華教授攻讀博士學位,研究方向為界面化學和模擬酶生物電化學。博士畢業論文獲“2009年度禮來亞洲優秀研究生論文獎”二等獎。2009年9月——2013年12月南京師範大學化學與環境科學學院工作。2014年4月到2015年4月,新加坡南陽理工大學博士后。2015年陝西師範大學,材料科學與工程學院教授。
主要從事結構功能納米材料的設計合成及其在化學/電化學能量轉換技術方面的工作。
(i) 高性能低溫燃料電池陰/陽極貴金屬納米晶電催化劑的設計合成。
(ii) 高分子聚合物-貴金屬納米晶有機-無機複合材料的界面結構-催化活性相互關係研究。
(iii)原子厚超薄二維過渡金屬/貴金屬納米材料的設計合成及其在水電解池、氮氣電化學還原和化學產氫領域中的應用。
(iv)碳材料在金屬空氣電池和水電解池領域中的應用。
近年主持國家自然科學基金、省自然科學基金、中央高校基金等科研項目9項,獲授權中國發明專利10項。迄今發表SCI論文120餘篇,作為通訊作者在 Chemical Science,Nano Energy,, NPG Asia Materials,ACS Catalysis, Small, Journal of Materials Chemistry A, ACS Applied Materials & Interfaces, Chemistry–A European Journal, Nano Research,Nanoscale等能源/材料期刊發表SCI論文80餘篇(包括邀請綜述及封面論文)。截止2018年,論文被 ChemicalReviews, ChemicalSocietyReviews, Nano Today等期刊正面引用評價3200餘次, 論文H-index為35。其中,單篇引用超過50次的20篇,10篇論文被評為全球ESI高被引(1%)論文。多項研究成果被ChemistryViews,Chemistry World,X-MOL化學資訊平台 和材料人資訊平台等多個國內外媒體亮點報道。合作編輯《 Electrochemical Reduction of Carbon Dioxide: Fundamentals and Technologies》2章。
1.PdCo alloy nanonetworks-polyallylamine inorganic-organic nanohybrids towards the oxygen reduction reaction. Advanced Materials Interfaces.2018, 1701322.
1. Polyallylamine functionalized platinum tripods: Enhancement of hydrogen evolution reaction by proton carriers. ACS Catalysis.2017,7, 452-458.
2.Bimetallic AuRh nanodendrites consisting of Au cores and atomically ultrathin Rh nanoplate shells: Synthesis and light-enhanced catalytic activity. NPG Asia Materials.2017, 9, e407.
3.Polyethyleneimine functionalized platinum superstructures: Enhancinghydrogenevolution performance by morphological and interfacial control. Chemical Science.2017, 8, 8411-8418.
4.A microribbon hybrid structure of CoOx-MoC encapsulated in N-doped carbon nanowire derived from MOF as efficient oxygen evolution electrocatalysts. Small. 2017, 13, 1702753.
5.Trimetallic PtRhNi alloy nanoassemblies as highly active electrocatalyst for ethanol electrooxidation. Nano Research.2017, 10, 3324-3332.
6.Ultrathin rhodium oxide nanosheet nanoassemblies: Synthesis, morphological stability, and electrocatalytic application. ACS Applied Materials & Interfaces.2017, 5, 5646-5650.
7.Rhodium nanosheets-reduced graphene oxide hybrids: A highly active platinum-alternative electrocatalyst for the methanol oxidation reaction in alkaline media. ACS Sustainable Chemistry & Engineering.2017,5, 10156-10162
8. Two-dimensional cobalt/N-doped carbon hybrid structure derived from metal-organic frameworks as efficient electrocatalysts for hydrogen evolution. ACS Sustainable Chemistry & Engineering. 2017, 5, 5646-5650
9.Polyethyleneimine modified AuPd@PdAu alloy nanocrystals as advanced electrocatalysts towards the oxygen reduction reaction. Journal ofEnergy Chemistry. 2017, 26, 1153-1159.
10.Research advances in unsupported Pt-based catalysts for electrochemical methanol oxidation. Journal ofEnergy Chemistry.2017, 26,1067-1076. (Review)
1. Morphological and interfacial control of platinum nanostructures for electrocatalytic oxygen reduction. ACS Catalysis. 2016, 6, 5260-5267.
2. Sandwich-structured Au@polyallylamine@Pd nanostructures: tuning electronic property of Pd shell for electrocatalysis. Journal of Materials Chemistry A. 2016, 4, 12020-12024.
3. Dendritic platinum-copper bimetallic nanoassemblies with tunable composition and structure: Arginine driven self-assembly andenhanced electrocatalytic activity. Nano Research. 2016, 9, 755-765.
4. One pot, gold seed-assisted synthesis of gold/platinum wire nanoassemblies and their enhanced electrocatalytic activity for the oxalic acid oxidation. Nanoscale. 2016, 8, 2875-2880. .
5. The chemical functionalized platinum nanodendrites: The effect of chemical molecular weight on electrocatalytic property. Journal of Power Sources. 2016, 306, 587-592.
6. Hollow PtNi alloy nanospheres with enhanced activity and methanol tolerance for the oxygen reduction reaction. Nano Research. 2016, 9, 3494-3503.
7. Unexpected catalytic activity of rhodium nanodendrites with nanosheet subunits for methanol electrooxidation in the alkaline medium. Nano Research. 2016, 9, 3893-3902.
8. One-pot fabrication of hollow and porous Pd-Cu alloy nanospheres and their remarkably improved catalytic performance for the hexavalent chromium reduction. ACS Applied Materials & Interfaces. 2016,8, 30948-30955.
9. Hydrothermal synthesis and catalytic application of ultrathin rhodium nanosheet nanoassemblies. ACS Applied Materials & Interfaces. 2016, 8, 33635-33641.
1. Trimetallic PtAgCu@PtCu core@shell concave nanooctahedrons with enhanced activity for formic acid oxidation reaction. Nano Energy. 2015, 12, 824-832.
2. Thermal decomposition synthesis of functionalized PdPt alloy nanodendrites with high selectivity for oxygen reduction reaction. NPG Asia Materials.2015, 7, e219.
3. Polyhedral palladium–silver alloy nanocrystals as highly active and stable electrocatalysts for the formic acid oxidation reaction. Scientific Reports.2015, 5, 13703.
4. A Strategy for fabricating porous PdNi@ Pt core-shell nanostructures and their enhanced activity and durability for the methanol electrooxidation. Scientific Reports. 2015, 5, 7619.
5. Polyethyleneimine-assisted synthesis of high-quality platinum/graphene hybrids: the effect of molecular weight on electrochemical properties. Journal of Materials Chemistry A. 2015, 3, 12000-12004.
6. Highly active and durable platinum-lead bimetallic alloy nanoflowers for formic acid electrooxidation. Nanoscale. 2015, 7, 4894-4899.
7. Platinum-copper alloy nanocrystals supported on reduced graphene oxide: One-pot synthesis and electrocatalytic applications. Carbon. 2015, 91, 338-345.
8. Ethanol-tolerant polyethyleneimine functionalized palladium nanowires in alkaline media: the "molecular window gauze" induced the selectivity for the oxygen reduction reaction. Journal of Materials Chemistry A. 2015, 3, 21083-21089.
9. Arginine-mediated synthesis of cube-like platinum nanoassemblies as efficient electrocatalysts. Nano Research. 2015, 8, 3963-3971.
1. Pt-Pd-Co trimetallic alloy network nanostructures with superior electrocatalytic activity towards the oxygen reduction reaction. Chemistry – A European Journal.2014, 20, 585-590.
2. Highly branched platinum nanolance assemblies by polyallylamine functionalization as superior active, stable, and alcohol-tolerant oxygen reduction electrocatalysts. Nanoscale. 2014, 6, 8226-823.
3. Hydrothermal synthesis of Pt–Ag alloy nano-octahedra and their enhanced electrocatalytic activity for the methanol oxidation reaction. Nanoscale. 2014, 6, 12310-12314.
4. Multi-generation overgrowth induced synthesis of three-dimensional highly branched palladium tetrapods and their electrocatalytic activity for formic acid oxidation. Nanoscale. 2014, 6, 2776-2781.
5. Seed-assisted synthesis of Pd@Au core-shell nanotetrapods and their optical and catalytic properties. Nanoscale. 2014, 6, 9273-9278.
6. Synthesis and electrocatalytic activity of Au@Pd core-shell nanothorns for the oxygen reduction reaction. Nano Research. 2014, 7, 1205-1214.
7. Arginine-assisted synthesis and catalytic properties of single-crystalline palladium tetrapods. ACS Applied Materials & Interfaces. 2014, 6, 22790-22795.
8. Autocatalysis and selective oxidative etching induced synthesis of platinum–copper bimetallic alloy nanodendrites electrocatalysts. ACS Applied Materials & Interfaces. 2014, 6, 7301-7308.
9. A ruthenium(iii) phosphonate complex on polyallylamine functionalized carbon nanotube multilayer films: self-assembly, direct electrochemistry, and electrocatalysis. Journal of Materials Chemistry B. 2014, 2, 102-109.
10. Pd@Pt core–shell tetrapods as highly active and stable electrocatalysts for the oxygen reduction reaction. Journal of Materials Chemistry A.2014, 2, 20855-20860.
11. Facile synthesis of Pd-Co-P ternary alloy network nanostructures and their enhanced electrocatalytic activity towards hydrazine oxidation. Journal of Materials Chemistry A. 2014, 2, 1252-1256.
1. Water-based synthesis and sensing application of polyallylamine functionalized platinum nanodendrite assemblies. Journal of Materials Chemistry A. 2013, 1, 14874-14878.
2. One-pot water-based synthesis of Pt–Pd alloy nanoflowers and their superior electrocatalytic activity for the oxygen reduction reaction and remarkable methanol-tolerant ability in acid media. The Journal of Physical Chemistry C. 2013, 117, 9826-9834.
3. Polyallylamine functionalized palladium icosahedra: One-pot water-based synthesis and their superior electrocatalytic activity and ethanol tolerant ability in alkaline media. Langmuir.2013, 29, 4413-4420.
4. Green synthesis and catalytic properties of polyallylamine functionalized tetrahedral palladium nanocrystals. Applied Catalysis B: Environmental.2013, 138–139, 167-174.
5. Crystalline palladium–cobalt alloy nanoassemblies with enhanced activity and stability for the formic acid oxidation reaction. Applied Catalysis B: Environmental.2013, 138–139, 229-235.
6. Efficient anchorage of highly dispersed and ultrafine palladium nanoparticles on the water-soluble phosphonate functionalized multiwall carbon nanotubes. Applied Catalysis B: Environmental. 2013, 129, 394-402.
7. One-pot, water-based and high-yield synthesis of tetrahedral palladium nanocrystal decorated graphene. Nanoscale. 2013, 5, 8007-8014.
8.Self-Assembly of tetrakis (3-trifluoromethylphenoxy) phthalocyaninato cobalt(ii) on multiwalled carbon nanotubes and their amperometric sensing application for nitrite. ACS Applied Materials & Interfaces. 2013, 5, 2255-2266.