作为项目负责人承担科技部国家国际合作专项、国家自然科学基金面上项目、教育部重点实验室开放基金、陕西省科技厅创新团队、能源陕西实验室科技项目、陕西省科技厅重点研发-工业公关、咸阳市重点研发等。主持中石油集团横向课题及其他横向课题多项。已有1项成果获省部级科技进步一等奖（第二完成单位）；先后发表论文七十余篇，申请国家发明专利26项，获准授权17项。

近期代表性论文(通讯作者) ：

[1] Multifunctional integrated separator based on electrospinningstructure engineering for high-stability lithium sulfur batteries. ChemicalEngineering Journal. 2025, 166813.

[2] Engineering a Semi-Immobilized Ionic Liquid InterfaceLayer to Boost Li⁺ Conduction at Organic-Inorganic Interface. Applied SurfaceScience. 2025, 713, 164342.

[3] Bilateral molecular bond- bridging organic-inorganic interfaces forenhanced lithium ion transport in composite solid-state electrolytes. Journalof Power Sources. 2025, 655, 237952.

[4] Boosting Polysulfides Conversion with Fe3O4-LoadedCarbon Derived from Willow Sawdust for High Sulfur Loading and Lean ElectrolyteLithium Sulfur Batteries. Journal of Power Sources. Journal of Power Sources. 2025,650, 237500.

[5] Ultra-stable all-solid-state lithium metal batteries facilitated byin-situ LiF-rich single-ion conductor composite polymer electrolytes. ChemicalEngineering Journal. 2025, 162820.

[6] Composite solid electrolytes with cation assisted effect to enhancethe electrochemical performance of all solid-state lithium metal batteries. CeramicsInternational. 2025, 51(10), 12738-12747.

[7] FeOOH Nanorod-Assisted Carbon Cloth Sandwich Cathodes forLithium-Sulfur Batteries. ACS Applied Nano Materials. 2025, 8(7), 3487-3496.

[8] Synergistic Interaction of Strongly Polar Zinc Selenide and HighlyConductive Carbon Nanoframeworks Accelerates Redox Kinetics of Polysulfides.ACS Applied Materials & Interfaces. 2024, 16(44), 60356-60365.

[9] Building TiO2-Ti3C2Txheterojunction by microwave-assisted hydrothermal as an amphiphilic nanoreactorfor high-performance lithium sulfur batteries. Materials Today Physics. 2024,48, 101571.

[11] Bimetallic NiCo@C with a Hollow Sea Urchin Structure Enables Li-SBatteries to Hasten the Reaction Kinetics and Effectively Inhibit the Shuttlingof Polysulfides. Inorganic Chemistry. 2024, 63(42), 19835-19846.

[12] Mediation of the electrochemical polarization for durable zincanode. Journal of Materials Chemistry A. 2024, 12, 26568–26577.

[13] Self-support interlayer of dual-intercalation MXene for acceleratingpolysufides conversion in lithium-sulfur batteries. Journal of Alloys andCompounds, 2024, 979, 173478.

[14] Cubic CoSe2@carbon as polysulfides adsorption-catalyticmediator for fast redox kinetics and advanced stability lithium-sulfurbatteries. Journal of Colloid and Interface Science. 2024,660, 246-256.

[15] In-situ coupling construction of interface bridge to enhanceelectrochemical stability of all solid-state lithium metal batteries. Journalof Energy Chemistry. 2024, 89, 18-26.

[16] Homogenous conduction: Stable multifunctional gel polymerelectrolyte for lithium-sulfur batteries. Colloids and Surfaces A:Physicochemical and Engineering Aspects. 2024, 680, 132732.

[17]功能化MXene在锂硫电池中应用研究进展. 材料导报. 2024, 38(12), 22100251.

[18] NC-Co3O4 Polyhedron Embedded MultifunctionalSeparator Based on Structural Engineering Towards Stable and DurableLithium-sulfur Battery. Journal of Alloys and Compounds. 2023, 968, 171969.

[19] Graphene quantum dots as sulfiphilic and lithiophilic mediatortoward high stability and durable life lithium-sulfur batteries. Journal ofEnergy Chemistry. 2023, 85, 254–266.

[20] Advances in the density functional theory (DFT) calculation oflithium-sulfur battery cathodes. Materials Today Communications. 2023, 36, 106814.

[21] Interfacial mechanochemical reaction synthesizes alkynyl porouscarbon to firm cyclic lithium-sulfur batteries. Journal of ElectroanalyticalChemistry. 2023, 934, 117309.

[22] Eucommia leaf residue-derived hierarchical porous carbon by KCl andCaCl2 Co-auxiliary activation for lithium sulfur batteries.Materials Characterization.  2023, 195, 112522.

[23] 双金属MOFs及其衍生物在电化学储能领域中的应用. 化学进展. 2022, 34(2) : 460-473.

[24] A stabilized polyacrylonitrile-encapsulated matrix on a nanolayeredvanadium-based cathode material facilitating the K-storage performance. ACSApplied Materials & Interfaces. 2022, 14: 14243-14252.

[25] Hierarchical multi-channels conductive framework constructed withrGO modified natural biochar for high sulfur areal loading self-supportingcathode of lithium-sulfur batteries. Chemical Engineering Journal Advances. 2022,9,  100209.

[26] Self-formed carbon layer on calcium Metal-organic framework and rGOcomposite with High-stable K-storage performance in K-ion batteries. AppliedSurface Science, 2022, 571, 151387.

[27] Lightweight freestanding hollow carbon fiber interlayer for highperformance lithium-sulfur batteries. International Journal of Energy Research.2022，46(4), 5296-5305.

[28] 锂硫电池电纺非电极材料改性的进展. 电池. 2022, 52(6), 703-707.

[29] Metal–organic framework derived Fe3O4/C/rGOcomposite as an anode material in lithium‑ion batteries. Ionics. 2021, 27(8):3281-3289.

[30] 二维金属有机框架材料的制备及其应用. 化工进展. 2021, 40(11), 6195-6210.

已授权国家发明专利：（本人第一）

[1]   一种铁基生物质碳复合隔膜及其制备方法和基于其的锂硫电池；专利号：ZL 2022 1 0080962.7

[2]   一种自支撑电极及其制备方法及一种锂硫电池；专利号：ZL 202111605024.6

[3]   锂硫电池自支撑电极 MOFs@碳纸复合材料的制备方法及应用；专利号：ZL 202110193698.3

[4]   一种锂硫电池用自支撑结构的隔膜及其制备方法；专利号：ZL 202110328179.3

[5]   一种电化学法制备石墨烯量子点溶液的方法；专利号：ZL 202110296659.6

[6]   一种原位硫、氮共掺杂生物质碳纳米片的制备方法；专利号：ZL 201811210945.0

[7]   一种微爆法制备石墨烯量子点的方法；专利号：ZL 201811157734.5

[8]   一种利用鱼鳞制备分级多孔碳材料的方法；专利号：ZL 201811209896.9

[9]   一种石墨烯/硫正极片的电化学制备方法；专利号：ZL 201810389 083.6

[10] 一种用于锂硫电池的无粘结剂正极片制备方法；专利号：ZL 201810389109.7

[11] 一种利用头发基制备分级多孔碳材料的方法；专利号：ZL 201811209884.6

[12] 微波法制备N,S共掺杂石墨烯锂硫电池正极材料的方法；专利号：ZL 2016 10079713.0

[13] 微波液相法制备掺杂石墨烯锂硫电池正极材料的方法；专利号：ZL 20161 0079316.3

[14] 一种含有添加剂Co3O4的锂硫电池正极材料及制备方法；专利号：ZL 20161 0079319.7

[15] 一种含有添加剂MgxNi(1-x)O的锂硫电池正极材料及制备方法；专利号：ZL 201610079714.5

[16] 类石墨烯掺杂锂离子电池硅酸铁锂复合正极材料制备方法；专利号：ZL 2014 1 0136971.9

[17] 一种类石墨烯结构的导电碳材料的制备方法；专利号：ZL 2014 1 0134804.0