一、個人簡介:
冉奮,教授/博導,甘肅省飛天學者,2022科睿唯安“高被引科學家”。”沈陽化工大學高分子復合材料本科畢業(yè),分別于北京化工大學材料科學與工程學院(化工資源有效利用國家重點實驗室)、四川大學高分子科學與工程學院(高分子材料工程國家重點實驗室)獲得工學碩士、工學博士學位。新加坡國立大學訪問研究員、美國加州大學圣克魯斯分校訪問學者,美國加州大學圣芭芭拉分校學習雙語教育教學法。擔任中國生物材料學會血液凈化材料分會委員,擔任InfoMat、Energy&Environmental Materials、eScience、Advaned Power Materials、InfoScience、材料導報、電子元件與材料等期刊的青年編委、執(zhí)行編委或編委。獲得甘肅省青年教師成才獎,甘肅省重點人才項目和蘭州理工大學紅柳杰出人才計劃資助。現(xiàn)為蘭州理工大學材料科學與工程學院教師。個人簡介:orcid.org/0000-0002-7383-1265 。
二、主持項目:
主持國家自然科學基金包括青年、地區(qū)、面上項目5項;主持并完成博士后面上項目、博士后特別資助,甘肅省重點人才項目,以及甘肅省自然科學基金;主持四川大學高分子材料與工程國家重點實驗室開放基金、沈陽金屬材料國家實驗室-蘭州理工大學有色金屬先進加工與再利用國家重點實驗室共同資助培育項目,以及蘭州理工大學紅柳優(yōu)秀基金、紅柳杰出人才項目。
二、學術(shù)專著:
[1] 撰寫:Polyethersulfone、Polyethersulfone Membrane、Polypropylene、Polypropylene Membrane,《Encyclopedia of Membranes》, Editors: E. Droli, L. Giorno, Springer 2015.
[2] 撰寫:Chapter 10: Polyaniline based composites and nanocomposites,《Polyaniline: Blends, Composites and Nanocomposites》, Editor: Alexandru Mihai Grumezescu, Elsevier 2016.
[3] 撰寫:Chapter 1: Polyethersulfone (PES) fiber, Volume 5: Polymer Fibers,《Composites in Biomedical Engineering (multi volume SET I-IX)》, Editor: Ashutosh Tiwari, Elsevier 2017.
[4] 主編:《Advanced Nanomaterials for Energy Storage and Power Battery》, Elsevier 2019.
三、代表性學術(shù)論文:
[1] Modification of polyethersulfone membrane-A review of methods, Progress in Materials Science 2013, 58(1): 76-150.
[2] Metal-Organic-Framework-Derived Nanostructures as Multifaceted Electrodes in Metal-Sulfur Batteries, Advanced Materials, 2021, 33(27): 2008784.
[3] Nanoribbons Self-Assembled by Rapid Cooling Method Towards High-Capacity Vanadium Nitride Anode Materials, Advanced Energy Materials 2022, 12(13): 2103158.
[4] Sulfur-Containing Polymer Cathode Materials: From Energy Storage Mechanism to Energy Density, InfoMat 2022, 4(8): e12319.
[5] Design Strategies of 3D Carbon-based Electrodes for Charge/Ion Transport in Lithium Ion Battery and Sodium Ion Battery. Advanced Functional Materials 2021: 2010041.
[6] Energy Storage Mechanism of Vanadium Nitride via Intercalating Different Atomic Radius for Expanding Interplanar Spacing, Energy & Environmental Materials 2022 (5): 565-571.
[7] Surfactant Induced Self-Assembly to Prepare Vanadium Nitride/N, S Co-doped Carbon as High-Capacitance Anode Materials, Chemical Communications 2021, 57, 10246-10249.
[8] Integrating Supercapacitor with Sodium Hyaluronate based Hydrogel as A Novel All-In-One Wound Dressing: Self-Powered Electronic Stimulation, Chemical Engineering Journal 2023, 452: 139491.
[9] A New Strategy Based on Multi-Phase Polymeric Material System to Improve the Electrochemical Behavior of Supercapacitor Negative Electrode, Nano-Micro Letters 2018, 10: 63.
[10] 3D Layered Nanostructure of Vanadium Nitrides Quantum Dots@Graphene Anode Materials via In-Situ Redox Reaction Strategy, Chemical Engineering Journal 2021, 417: 129267.
[11] All-In-One Energy Storage Devices Supported and Interfacially Cross-linked by Gel Polymeric Electrolyte, Energy Storage Materials 2021, 37: 587-597.
[12] Cobalt-based Double Catalytic Sites on Mesoporous Carbon as Reversible Polysulfide Catalysts for Fast-Kinetic Li-S Batteries, ACS Applied Materials & Interfaces 2021, 13(43), 51174–51185.
[13] Cyclic Stability of Supercapacitors: Materials, Energy Storage Mechanism, Test Methods, and Device, Journal of Materials Chemistry A 2021, 9, 24094-24147.
[14] Conductive 3D networks in a 2D layer for high performance ultrafiltration membrane with high flux-retention and robust cyclic stability, Journal of Membrane Science 2021, 640: 119781.
[15] Chemically building interpenetrating polymeric networks of bi-crosslinked hydrogel macromolecules for membrane supercapacitors. Carbohydrate Polymers 2021, 255: 117346.
[16] Hydrated halide clusters on electrode materials for aqueous supercapacitor. Journal of Power Sources 2021, 491: 229612.
[17] Vanadium Nitride for aqueous Supercapacitors: A Topic Review, Journal of Materials Chemistry A 2020, 8: 8218-8233.
[18] Dual High-Conductivity Networks via Importing a Polymeric Gel Electrolyte into the Electrode Bulk, ACS Applied Materials & Interfaces 2020, 12(37): 41239-41249.
[19] Fundamental Triangular Interaction of Electron Trajectory Deviation and P-N Junction to Promote Redox Reactions for the High-Energy-Density Electrode, ACS Applied Materials & Interfaces 2020, 12(26): 29404-29413.
[20] Electrolyte-philic Electrode Material with Functional Polymer Brush, ACS Applied Materials & Interfaces 2019, 11(17): 16087-16095.