材料工程学院

林建德，男，中共党员，理学博士，副教授，福建省高层次人才C类（2024），中国化学会会员，中国化工学会会员。2023年6月毕业于厦门大学化学化工学院，获理学博士学位，2023年8月作为福建省教育科研类引进生入职福建农林大学材料工程学院能源工程系从事教学科研工作。主要从事计算能源材料、二次电池材料设计、电化学储能界面模型与方法等电化学和材料化学领域的基础研究与应用探索。目前累计发表SCI论文50余篇，其中以第一作者（含共一）/通讯作者身份在Angewandte Chemie International Edition、Advanced Energy Materials (2篇)、Coordination Chemistry Reviews、Energy Storage Materials、Nano Energy (2篇)、ACS Nano、ACS Energy Letters、Journal of Energy Chemistry、Advanced Science、Journal of Power Sources等高水平国际期刊发表SCI论文18篇，ESI高被引论文1篇，封面论文1篇，以共同作者身份在Nature Communications, Advanced Materials, Journal of the American Society等高水平国际期刊发表学术论文30余篇，总引2100余次，H-因子26，申请并获授权国家发明专利4项。

教育经历

2019.09-2023.06 厦门大学-化学化工学院/固体表面物理化学国家重点实验室，物理化学，理学博士

2016.09-2019.06 中南大学-材料科学与工程学院，材料科学与工程，工学硕士

2012.09-2016.06 中南大学-材料科学与工程学院，材料科学与工程，工学学士

工作经历

2023.08-至今, 福建农林大学材料工程学院

研究领域

能源材料第一性原理计算/分子动力学模拟、二次电池电极材料设计、电化学储能界面模型与方法、生物质基功能材料等

开授课程

（1）《电化学原理》（本科生）

（2）《锂离子电池》（本科生）

科研项目

[1] 福建省教育厅，福建省中青年教师教育科研项目（科技类）-重点项目，JZ240016, 2025-01-01至2027-12-31，10 万，在研，主持
[2] 福建省2023届教育科研引进生科研启动基金，20 万，在研，主持
[3] 国家自然科学基金委员会, 重大项目，代塑竹材聚集微元的高效仿生重组复合机制，课题2竹材聚集微元高效重组复合及劣化破坏失效机制，32494792，2025-01-01至2029-12-31，在研，参与
[4] 国家自然科学基金委员会, 重点项目, 22032004, 2021-01-01 至 2025-12-31, 300万元, 在研, 参与
[5] 福建省科技厅, 面上项目, 2024J01403, 2024-11-01至2027-11-01, 10万元, 在研, 参与
[6] 国家自然科学基金委员会, 面上项目, 51874362, 2019-01-01 至 2022-12-31, 60万元, 结题, 参与

论文著作

其它学术主页

ResearchGate：https://www.researchgate.net/profile/Jiande-Lin

Google Scholar：https://scholar.google.com/citations?hl=zh-CN&user=Jxg_1EwAAAAJ

近5年发表论文（*：通讯作者；#：共同第一作者）

[1] Li S, Lin J*, Wang H, Zhou S, Guo X*, Zhan X, Tao H, Hu H, He Z, Liao H, Zhan D, Zhang L*. Three-Dimensional Metal-Organic Frameworks with Selectively Activated Aromatic Rings for High-Capacity and High-Rate Lithium-Ion Storage. Angewandte Chemie International Edition, 2025: e202423186.

[2] Wang S#, Lin J#, Yuan Z, Luo L, Zhang W, He C, Zhao W. Tunable architecture of cobalt-nickel metal-organic framework/activated carbon composites for superior electrochemical performance in asymmetric supercapacitors. Journal of Colloid and Interface Science, 2025, 684: 647-657.

[3] Li G, Hua Z, Yang J, Hu H, Zheng J, Ma X*, Lin J*, Cao S*. Bamboo-A potential lignocellulosic biomass for preparation of hard carbon anode used in sodium ion battery. Biomass and Bioenergy, 2025, 194: 107673.

[4] Xiao YH, Ma ZW, Wu XW, Chen LK, Sajid Z, Devasenathipathy R, Lin JD*, Wu DY*, Tian ZQ. Theoretical Insight into the Transition-Metal-Embedded Boron Nitride-Doped Graphene Single-Atom Catalysts for Electrochemical Nitrogen Reduction Reaction. Journal of Physical Chemistry C, 2025, 129(4): 1930-1940.

[5] Xiao Y-H, Wu X-W, Chen L-K, Ma Z-W, Lin J-D*, Rajkumar D, Wu D-Y*, Tian Z-Q. A First Principle Study to Understand the Importance of Edge-exposed and Basal Plane Defective MoS2 Towards Nitrogen Reduction Reaction. ChemPhysChem, 2025: e202400866.

[6] Hu X, Liang S*, Lin J, Ren W, Fu S, Cao Z, Zhang T, Zhang L, Cao X*. Synergistic Configurational Entropy and Iron Vacancy Engineering in Na4Fe3(PO4)2P2O7 Cathode for High-Power-Density and Ultralong-Life Na-Ion Full Batteries. Advanced Energy Materials, 2025: 2404965.

[7] Zhan X, Pang X, Mao F, Lin J*, Li M, Zhao Y, Xu P, Xu Z*, Liao K, Zhang Q, Zhang L*. Interfacial Reconstruction Unlocks Inherent Ionic Conductivity of Li-La-Zr-Ta-O Garnet in Organic Polymer Electrolyte for Durable Room-Temperature All-Solid-State Batteries. Advanced Energy Materials, 2024, 14(42): 2402509.

[8] Zhou Y, Xu G, Lin J*, Zhu J, Pan J, Fang G, Liang S*, Cao X*. A multicationic-substituted configurational entropy-enabled NASICON cathode for high-power sodium-ion batteries. Nano Energy, 2024, 128: 109812.

[9] Chen LK, Xiao YH, Lin JD, Sajid Z, Zhou JZ, Wu DY, Tian ZQ. Adsorption Structures, Vibrational Raman Spectra and Chemical Binding Properties of Thioglycolic Acid on Cu(111) Surfaces: A DFT Study. ChemPhysChem, 2024, 25(15): e202400330.

[10] Zhan X, Li M, Zhao X, Wang Y, Li S, Wang W, Lin J, Nan Z-A, Yan J, Sun Z, Liu H, Wang F, Wan J, Liu J, Zhang Q, Zhang L. Self-assembled hydrated copper coordination compounds as ionic conductors for room temperature solid-state batteries. Nature Communications, 2024, 15: 1056.

[11] Fu A#, Lin J#, Zheng J, Wu D-Y, Zhang Z, Yan P, Su Y, Xu C, Hao J, Zheng H, Duan H, Ding Y, Yan J, Huang S, Liu C, Tang C, Fang X, Yang Y. Additive evolved stabilized dual electrode-electrolyte interphases propelling the high-voltage Li||LiCoO2 batteries up to 4.7 V. Nano Energy, 2024, 119: 109095.

[12] Cai Z-Y, Ma Z-W, Wu W-K, Lin J-D, Pei L-Q, Wang J-Z, Wu T-R, Jin S, Wu D-Y, Tian Z-Q. Stereoelectronic Switches of Single-Molecule Junctions through Conformation-Modulated Intramolecular Coupling Approaches. The Journal of Physical Chemistry Letters, 2023, 14(43): 9539-9547.

[13] Zhou Y, Xu G, Lin J, Zhang Y, Fang G, Zhou J, Cao X, Liang S. Reversible Multielectron Redox Chemistry in a NASICON-Type Cathode toward High-Energy-Density and Long-Life Sodium-Ion Full Batteries. Advanced Materials, 2023, 35(44): 2304428.

[14] Gu Y, You E-M, Lin J-D, Wang J-H, Luo S-H, Zhou R-Y, Zhang C-J, Yao J-L, Li H-Y, Li G, Wang W-W, Qiao Y, Yan J-W, Wu D-Y, Liu G-K, Zhang L, Li J-F, Xu R, Tian Z-Q, Cui Y, Mao B-W. Resolving nanostructure and chemistry of solid-electrolyte interphase on lithium anodes by depth-sensitive plasmon-enhanced Raman spectroscopy. Nature Communications, 2023, 14: 3536.

[15] Lu X, Zhao H, Qin Y, Matios E, Luo J, Chen R, Nan H, Wen B, Zhang Y, Li Y, He Q, Deng X, Lin J, Zhang K, Wang H, Xi K, Su Y, Hu X, Ding S, Li W. Building Fast Ion-Conducting Pathways on 3D Metallic Scaffolds for High-Performance Sodium Metal Anodes. ACS Nano, 2023, 17(11): 10665-10676.

[16] Chen B#, Huang H#, Lin J#, Zhu K, Yang L, Wang X, Chen J. Doping Engineering of M-N-C Electrocatalyst Based Membrane-Electrode Assembly for High-Performance Aqueous Polysulfides Redox Flow Batteries. Advanced Science, 2023, 10(16): e2206949.

[17] Wang D, Liang Z-H, Xiao Y-H, Lin J-D, Zhou J-Z, Wu D-Y. Influence of Adsorption of para-Aminothiophenol on Trap States and Recombination Kinetics at Plasmonic Ag-TiO2 Heterostructure Interfaces. ChemPhotoChem, 2023, 7(7): e202300025.

[18] Xiong W#, Lin J#, Wang H, Li S, Wang J, Mao Y, Zhan X, Wu D-Y, Zhang L. Construction of strong built-in electric field in binary metal sulfide heterojunction to propel high-loading lithium-sulfur batteries. Journal of Energy Chemistry, 2023, 81: 492-501.

[19] Cai Z-Y, Guan S-Y, Ma Z-W, Lin J-D, Devasenathipathy R, Wu D-Y, Mao B-W, Tian Z-Q. Switchable Organic Low-Loss Spin Filters Based on Gold-Viologen-Gold Molecular Junctions. The Journal of Physical Chemistry C, 2023, 127(8): 4251-4257.

[20] Xie X, Zhou S, Fang G, Lin J, Wan Y, Cao G, Pan A. Interface Engineering Enhances Pseudocapacitive Contribution to Alkali Metal Ion Batteries. ACS Applied Energy Materials, 2023, 6(3): 1877-1887.

[21] Liu X, Fu A, Lin J, Zou Y, Liu G, Wang W, Wu D-Y, Yang Y, Zheng J, Ye L. Constructing a Stabilized Cathode Electrolyte Interphase for High-Voltage LiCoO2 Batteries via the Phenylmaleic Anhydride Additive. ACS Applied Energy Materials, 2023, 6(3): 2001-2009.

[22] Fu A, Xu C, Lin J, Su Y, Zhang H, Wu D-Y, Zhang X, Xia M, Zhang Z, Zheng J, Yang Y. Enabling interfacial stability of LiCoO2 batteries at an ultrahigh cutoff voltage ≥ 4.65 V via a synergetic electrolyte strategy. Journal of Materials Chemistry A, 2023, 11(7): 3703-3716.

[23] Li S#, Lin J#, Chang B, Yang D, Wu D-Y, Wang J, Zhou W, Liu H, Sun S, Zhang L. Implanting single-atom N2-Fe-B2 catalytic sites in carbon hosts to stabilize high-loading and lean-electrolyte lithium-sulfur batteries. Energy Storage Materials, 2023, 55: 94-104.

[24] Fu CY, Wang YP, Lu CG, Zhou S, He Q, Hu YZ, Feng MY, Wan YL, Lin JD, Zhang YF, Pan AQ. Modulation of hydrogel electrolyte enabling stable zinc metal anode. Energy Storage Materials, 2022, 51: 588-598.

[25] Li S#, Lin JD#, Zhang YM, Zhang SL, Jiang T, Hu ZL, Liu JJ, Wu DY, Zhang L, Tian ZQ. Eight-Electron Redox Cyclohexanehexone Anode for High-Rate High-Capacity Lithium Storage. Advanced Energy Materials, 2022, 12(30): 2201347.

[26] Zou Y, Cheng Y, Lin J, Xiao Y, Ren F, Zhou K, Wang M-S, Wu D-Y, Yang Y, Zheng J. Boosting high voltage cycling of LiCoO2 cathode via triisopropanolamine cyclic borate electrolyte additive. Journal of Power Sources, 2022, 532: 231372.

[27] Fu A#, Lin J#, Zhang Z, Xu C, Zou Y, Liu C, Yan P, Wu D-Y, Yang Y, Zheng J. Synergistical Stabilization of Li Metal Anodes and LiCoO2 Cathodes in High-Voltage Li∥LiCoO2 Batteries by Potassium Selenocyanate (KSeCN) Additive. ACS Energy Letters, 2022, 7(4): 1364-1373.

[28] Rani KK, Devasenathipathy R, Wang J-Z, Hui X-Y, Lin J-D, Zhang Y-M, Zhao L-B, Zhou J-Z, Wu D-Y, Tian Z-Q. Plasmonic photoelectrochemical reactions on noble metal electrodes of nanostructures. Current Opinion in Electrochemistry, 2022, 34: 100985.

[29] Zou Y, Zhang J, Lin JD#, Wu DY, Yang Y, Zheng JM. Improving interfacial stability of high voltage LiCoO2-based cells with 4-methylmorpholine-2,6-dione additive. Journal of Power Sources, 2022, 524: 231049.

[30] Zhou S, Fu C, Chang Z, Zhang Y, Xu D, He Q, Chai S, Meng X, Feng M, Zhang Y, Lin J, Pan A. Conductivity gradient modulator induced highly reversible Li anodes in carbonate electrolytes for high-voltage lithium-metal batteries. Energy Storage Materials, 2022, 47: 482-490.

[31] Devasenathipathy R, Wang JZ, Xiao YH, Rani KK, Lin JD, Zhang YM, Zhan C, Zhou JZ, Wu DY, Tian ZQ. Plasmonic Photoelectrochemical Coupling Reactions of para-Aminobenzoic Acid on Nanostructured Gold Electrodes. Journal of the American Chemical Society, 2022, 144(9): 3821-3832.

[32] Fu A, Zhang Z, Lin J, Zou Y, Qin C, Xu C, Yan P, Zhou K, Hao J, Yang X, Cheng Y, Wu D-Y, Yang Y, Wang M-S, Zheng J. Highly stable operation of LiCoO2 at cut-off ≥ 4.6 V enabled by synergistic structural and interfacial manipulation. Energy Storage Materials, 2022, 46: 406-416.

[33] Yang L, Hao Y, Lin J, Li K, Luo S, Lei J, Han Y, Yuan R, Liu G, Ren B, Chen J. POM Anolyte for All-Anion Redox Flow Batteries with High Capacity Retention and Coulombic Efficiency at Mild pH. Advanced Materials, 2022, 34(7): 2107425.

[34] Yin B, He HY, Lin JD, Hong YR, Cheng BS, Zhu L, He HL, Ma MC, Wang JW. Bichannel design inspired by membrane pump: a rate booster for the conversion-type anode of sodium-ion battery. Journal of Materials Chemistry A, 2022, 10(7): 3373-3381.

[35] 彭辉远, 王家正, 刘佳, 于欢欢, 林建德, 吴德印, 田中群. 纳米结构金电极上对氨基苯硫酚的电化学反应过程研究. 电化学, 2022, 28(4): 2106281.

[36] Peng H-Y, Xiao Y-H, Yu H-H, Wang J-Z, Lin J-D, Devasenathipathy R, Liu J, Zou P-H, Zhang M, Zhou J-Z, Wu D-Y, Tian Z-Q. Electrochemical and Plasmonic Photochemical Oxidation Processes of para-Aminothiophenol on a Nanostructured Gold Electrode. The Journal of Physical Chemistry C, 2021, 125(45): 24849-24858.

[37] Xiao YH, Liu J, Lin JD, Yu HH, Pang R, Wu DY, Tian ZQ. Adsorption and Co‐adsorption of Chlorine and Water‐Chlorine Complexes on Au(111) Surfaces: First‐Principles DFT Study. ChemElectroChem, 2021, 8(21): 4072-4082.

[38] Li S#, Lin J#, Ding Y, Xu P, Guo X, Xiong W, Wu DY, Dong Q, Chen J, Zhang L. Defects Engineering of Lightweight Metal-Organic Frameworks-Based Electrocatalytic Membrane for High-Loading Lithium-Sulfur Batteries. ACS Nano, 2021, 15: 13803-13813.

[39] Yin B, Liang SQ, Yu DD, Cheng BS, Egun IL, Lin JD, Xie XF, Shao HZ, He HY, Pan AQ. Increasing Accessible Subsurface to Improving Rate Capability and Cycling Stability of Sodium-Ion Batteries. Advanced Materials, 2021, 33(37): 2100808.

[40] Li S#, Lin JD#, Xiong WM, Guo XY, Wu DY, Zhang QB, Zhu QL, Zhang L. Design principles and direct applications of cobalt-based metal-organic frameworks for electrochemical energy storage. Coordination Chemistry Reviews, 2021, 438: 213872.

科技成果

[1] 潘安强; 林建德; 一种具有玫瑰状二硫化钒/碳量子点复合材料及其制备方法和应用, 2020-12-25,中国, CN201810440772.5 (专利)

[2] 潘安强; 林建德; 一种五氧化二铌/碳双量子点纳米复合材料及其制备方法和应用, 2021-01-29, 中国, CN201810440760.2 (专利)

[3] 潘安强; 崔荣; 郝鹏飞; 林建德; 一种碳布生长V5.45S8单晶纳米片的制备方法及其应用, 2021-07- 23, 中国, CN201910511225.6 (专利)

[4] 潘安强; 崔荣; 郝鹏飞; 林建德; 一种LiCuVO4纳米纤维的制备方法及其产品与应用, 2022-04-08,中国, CN201910429913.8 (专利)