近五年发表SCI/EI论文90余篇，在Advanced Materials，Advanced Functional Materials, Advanced Fiber Materials, Small, Chemical Engineering Journal, RSC, ACS, Elsevier等期刊每年均有论文发表，涉及研究领域有生态染色，功能性织物组织结构设计，油水分离，雾水收集，热湿舒适性，柔性电极、电容器，光催化材料，水循环回收利用材料等。

[1]Du P, et al. Coral-inspired passive radiative cooling textiles toward extreme environments [J]. Materials Today, 2026, 93: . (IF: 22)

[2]Li C, et al. Asymmetric Wetting Membrane Based on Oriented Multichannel Fiber Bundles and Hydrovoltaic Effect for Simultaneous Oil Collection and Self-Powered Monitoring [J]. Advanced Functional Materials, 2026, no. 34: e31148. (IF: 19.0)

[3]Hou K, et al. Dyeing and life cycle assessment of Porel modified polyester [J]. Journal of Cleaner Production, 2025, 525, 146512. (IF: 11.1)

[4]Wang J, et al. In-situ fouling mitigation and purification of complex oily wastewater durable superhydrophilic catalytic separation membrane based on salting-out effect [J]. Journal of Membrane Science, 2026, 749, 125463. (IF: 10.5)

[5]Zhao L, et al. Constructing electro-Fenton PVDF membrane with Fe/Cu doped CNTs using lignin as green dispersant for efficient dye removal efficiency and sustainable antifouling and self-cleaning performance [J]. Separation and Purification Technology, 2026, 136782. (IF: 8.1)

[6]Zhao K, et al. Bioinspired Polyacrylate Coating with Moth-Eye Nanostructures for Enhanced Color Depth of Polyester Fabric [J]. ACS Applied Polymer Materials, 2026, 8(2), 1212-1218. (IF: 5.0)

[7]Ding Y, et al. Bioinspired Core–Shell Latex for Enhanced Depth of Shade in Polyester Fabric [J]. Langmuir, 2026, 42(15), 10348-10355. (IF: 3.9)

[8]Ji Y, et al. Molecular-enabled lithium-locking for stable sorption-based atmospheric water harvesting [J]. Energy & Environmental Science, 2025, 7, 18(16), 8077-8087. (IF: 30.8)

[9]Du P, et al. Transpiration-Inspired Radiative Cooling Metafabric for Efficient Personal Thermal and Moisture Management [J]. Advanced Materials, 2025, 0(0): e73241. (IF: 26.8)

[10]Zhang J, et al. Molecularly Copper-Coordinated Cellulose Heterogeneous Wettability Surface Induced Efficient Fog Harvesting [J]. Advanced Fiber Materials, 2025, 10, 1-14. (IF: 21.3)

[11]Li X, et al. Bio-inspired Tough Metafiber with Hierarchical Photonic Structures for Durable Passive Radiative Thermal Management [J]. Advanced Fiber Materials, 2025, 2, 7(2), 607-619. (IF: 21.3)

[12]Li X, et al. Lizard Scale-Inspired Asymmetric Solar-Confined Textiles Enabling Scalable Bi-directional Thermoregulation [J]. Advanced Fiber Materials, 2025, 8(2): 813-824. (IF: 21.3)

[13]Lin X, et al. 3D patterned fabric-based wearable micro-supercapacitor operating at high voltage by electrostatic actuation [J]. npj Flexible Electronics, 2025, 9(1): 60. (IF: 15.5)

[14]Wang J, et al. An asymmetric personal thermal management textile integrating multienergy-coupled heating with flame-retardant thermal-moisture regulation [J]. Chemical Engineering Journal, 2025, 9, 523, 168289. (IF: 13.2)

[15]Wang J, et al. Dual-strategy anti-fouling based on hydrogel-coated catalytic separation membrane material [J]. Chemical Engineering Journal, 2025, 7, 521, 166483. (IF: 13.2)

[16]Zeng C, et al. Dual-wettability gradient fabric with grooved high-thermal-conductivity surface for textile-based fog harvesting [J]. Chemical Engineering Journal, 2025, 1, 519, 165498. (IF: 13.2)

[17]Chen Y, et al. Thermally enhanced condensation and hydrophilicity-blocking strategy for textile-based fog harvesting [J]. Chemical Engineering Journal, 2025, 3, 510, 161525. (IF: 13.2)

[18]Li C, et al. Fabric-based composite membrane for simultaneous emulsion separation and self-powered real-time monitoring [J]. Journal of Hazardous Materials, 2025, 7, 496, 139261. (IF: 11.3)

[19]Dyeing and life cycle assessment of Porel modified polyester [J]. Journal of Cleaner Production, 2025, 525: 146512. (IF: 10.0)

[20][Ji Y, et al. Interface molecular mineralization enables green, scalable fabrication of MOF-fabric composites [J]. Journal of Cleaner Production, 2025, 2, 496, 145094. (IF: 10)

[21]Jin K, et al. A smart gating microfiltration membrane to break aperture adaptability limit for industrial oily wastewater treatment [J]. Journal of Membrane Science, 2025, 1, 719, 123762. (IF: 9)

[22]Peng W, et al. Dual-Functional Evaporator: Synergistic Seawater Purification via Photothermal Evaporation and Microplastic Adsorption [J]. ACS Applied Materials & Interfaces, 2025, 7, 17(30), 43740-43749. (IF: 8.2)

[23]Wang J, et al. Janus Textile for Multifunctional Personal Thermal Management via Dual Photothermal--Electrothermal Conversion [J]. ACS Applied Materials & Interfaces, 2025, 5, 17(23), 34569-34581. (IF: 8.2)

[24]Song L, et al. Facile fabrication of tear-film-inspired durable hyaluronic acid hydrogel films for persistent anti-fogging [J]. Progress in Organic Coatings, 2025, 7, 208, 109537. (IF: 7.3)

[25]Yu H J, et al. A comprehensive, environmentally friendly, transparent cellulose hydrophilic anti-fog coating with excellent water resistance, coordinated multifunctionality and outstanding durability [J]. Progress in Organic Coatings, 2025, 5, 206, 109369. (IF: 7.3)

[26]Shi Y, et al. Design of Janus fabric membranes with asymmetric wettability and controllable pore size for on-demand separation of oily wastewater [J]. Journal of Environmental Chemical Engineering, 2025, 7, 13(5), 118224. (IF: 7.2)

[27]Wang J, et al. pH-responsive fiber membrane with high flux and photocatalytic performance for oily wastewater [J]. Journal of Environmental Chemical Engineering, 2025, 1, 13(1), 115322. (IF: 7.2)

[28] Zhao H, et al. Multi-scenario durable hydrophilic/hydrophobic poly (HEAA-co-BA-co-BPA) anti-fogging coating [J]. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2025, 4, 720, 137069. (IF: 5.4)

[29]Ji Y, Yang W, Li X, et al. Nanoscale Drag Reduction Effect Enables Efficient Fog Harvesting [J]. Advanced Functional Materials. 2024:2411083. （IF:18.5）

[30]Ji Y，Yang W，Li X，et al. A Molecular Confine-Induced Charged Fiber for Fog Harvesting [J].Advanced Fiber Materials (2024), 1-14.（IF:17.2）

[31]Du P, Zhao X, Zhan X，et al. A High‐Performance Passive Radiative Cooling Metafabric with Janus Wettability and Thermal Conduction [J]. Small (2024) :2403751. (IF:13.0)

[32]Y Ji, Y Chang, K Hou，et al. Study on the dyeing and moisture absorption and quick-drying performance of Porel spandex core-spun yarns, The Journal of The Textile Institute, 2024, 1-8.（IF:1.5）

[33]Y Chang, K Hou, Y Ji，et al. Optimisation of cationic dye dyeing process of Porel fabrics using response surface methodology, Coloration Technology, 2024.（IF：2.0）

[34]Y Ji, X Li, K Hou，et al. Research Progress and Development Trend of Textile Auxiliaries, Fibers and Polymers, 2024, 25(5), 1569-1601.（IF：2.2）

[35]B Yu, K Hou, Z Fan，et al.Design fiber-based membrane with interfacial wettability rapidly regulated behavior by pH for oily wastewater high-efficient treatment, Progress in Organic Coatings, 2024, 189, 108326.（IF：6.5）

[36]Z Fan, Y Wang, W Zhao，et al.Unidirectional water transport fabric with nanoscale Hydrophilic/hydrophobic pattern for personal moisture and thermal management, Chemical Engineering Journal, 2024, 480, 148204. （IF：13.3）

[37]Y Yang, L Zeng, X Li，et al. Hydrophilic/hydrophobic poly(AA-co-BA-co-BPA) anti-fog coating with excellent water resistance and self-healing properties, Progress in Organic Coatings, 2024, 187, 108071.（IF：6.5）

[38]X Li, Y Ji, Z Fan，et al. Asymmetrical Emissivity and Wettability in Stitching Treble Weave Metafabric for Synchronous Personal Thermal-Moisture Management, Small, 2023, 19(29), 2300297.（IF：13.0）

[39] Y Ji, W Yang, X Li，et al. Thermodynamically Induced Interfacial Condensation for Efficient Fog Harvesting, Small, 2023, 19(46), 2304037.（IF：13.0）

[40] Y Luo, Z Cai, L Pei，et al. Low temperature non-aqueous dyeing of wool fiber with reactive dyes: A sustainable and eco-friendly method, Journal of Cleaner Production, 2023, 432, 139803.（IF：9.7）

[41] K Hou, H Ma, H Zhao，et al. Fabrication of sandwich-structured infrared camouflaged and flexible anti-aging composite for thermal management, Ceramics International, 2023, 49(18), 30304-30311.（IF：5.1）

[42] K Hou, K Jin, Z Fan，et al. Facile fabrication of fabric-based membrane for adjustable oil-in-water emulsion separation, suspension filtration and dye removal, Separation and Purification Technology, 2023, 323, 124467.（IF：8.1）

[43] Z Fan, M Hu, K Hou，et al. Fabrication of Hydrophobic Poly(vinylidene fluoride) Membranes with Manipulated Micromorphology and Enhanced Strength, Langmuir, 2023, 39(25), 8629-8637.（IF：3.7）

[44] K Jin, K Hou, J Wang，et al. Composite membranes with multifunctionalities for processing textile wastewater: Simultaneous oil/water separation and dye, Separation and Purification Technology, 2023, 320, 124176.（IF：8.1）

[45] Y Luo, J Wang, Z Cai，et al. Different Dyeing Properties in Nonaqueous Dyeing Systems for Various Wool Fibers, Fibers and Polymers, 2023, 24(6), 2017-2025.（IF：2.2）

[46] H Zhao, Z Fan, C Jia, Z Cai，et al.One-way water transport and enhanced heating and cooling for cotton fabrics, Cellulose, 2023, 30(5), 3351-3361.（IF：4.9）

[47] K Hou, Y Ji, Y Chang，et al.Characterization of Porel Fiber Structure and Thermal-Wet Comfort of its Fabrics, Fibers and Polymers, 2023, 24(7), 2557-2564.（IF：2.2）

[48] 赵红;季成龙;蔡再生. 基于纳米氮化硼吸湿凉爽弹力针织物的开发, 针织工业, 2023, (07), 50-55.

[49] X Huang, K Jin, K Hou，et al.A Weaving Method to Prepare Double-Layer Janus Fabric for Oil-Water Separation, Fibers and Polymers, 2022, 23(13), 3624-3637.（IF：2.2）

[50] Y Luo, L Zhu, L Pei，et al.Sustainable silk dyeing in a silicon non-aqueous dyeing system with Reactive Red 195: salt-free and less alkali, Textile Research Journal, 2022, 92(23-24), 4921-4932.（IF：0.6）

[51] Y Luo, S Zhai, L Pei，et al. Environment-Friendly High-Efficiency Continuous Pad Dyeing of Non-Shrinkable Wool Fabric by the Silicon Fixation Method without Auxiliary Chemicals, ACS Sustainable Chemistry & Engineering, 2022, 10(11), 3557-3566.（IF：7.1）

[52] Y Li, S Zhai, W Dong，et al. Preparation of cationic viscose and its salt-free dyeing using reactive dye, Coloration Technology, 2022, 138(4), 378-387.（IF：1.8）

[53] H Yang, K Jin, H Wang，et al. Facile preparation of a high-transparency zwitterionic anti-fogging poly(SBMA-co-IA) coating with self-healing property, Progress in Organic Coatings, 2022, 165, 106764.（IF：6.5）

[54] S Zhai, Y Li, W Dong，et al. Cationic cotton modified by 3-chloro-2-hydroxypropyl trimethyl ammonium chloride for salt-free dyeing with high levelling performance, Cellulose, 2022, 29(1), 633-646.（IF：4.9）

[55] M Luo, C Yao, S Zhai，et al. Design and preparation of mixed special wettability fabrics based on backed weave for separation of light oil/water/heavy oil mixtures, Journal of Industrial Textiles, 2022, 51(8), 1312-1329.（IF：1.5）

[56] 李一东;张腾飞;蔡再生 回毛坯布组成成分的定性、定量分析技术,产业用纺织品, 2022, 40(03), 44-48.

[57] X Chen, Y Chen, S Lv，et al. New type of borneol-based fluorine-free superhydrophobic antibacterial polymeric coating, Designed Monomers and Polymers, 2021, 24(1), 145-155.（IF：1.8）

[58] K Jin, Y Zhao, Z Fan，et al. A facile and green route to fabricate fiber-reinforced membrane for removing oil from water and extracting water under slick oil, Journal of Hazardous Materials, 2021, 416, 125697.（IF：12.2）

[59] S Wang, H Wang, Z Fan，et al. Facile preparation of a high-transparency anti-fogging/frost-resisting poly(AMPS-co-AA) coating with self-healing property, Progress in Organic Coatings, 2021, 151, 106053.（IF：6.5）

[60] M Zhou, A Bahi, Y Zhao，et al. Enhancement of charge transport in interconnected lignin-derived carbon fibrous network for flexible battery-supercapacitor hybrid device, Chemical Engineering Journal, 2021, 409, 128214.（IF：13.3）

[61] X Chen, Q Nie, Y Shao，et al. TiO2 nanoparticles functionalized borneol-based polymer films with enhanced photocatalytic and antibacterial performances, Environmental Technology & Innovation, 2021, 21, 101304.（IF：6.7）

[62] 黄西琴;范追追;蔡再生 特殊浸润性三层织物的设计及其单向导湿性能研究, 产业用纺织品, 2021, 39(12), 7-14.

[63] 李凯;杜强;赵亚萍;蔡再生 铁氧化物/生物质衍生多孔碳复合材料的制备及其电化学性能研究, 产业用纺织品, 2021, 39(11), 43-49.

[64] 李悦;董伟伟;王梦婷;蔡再生 黏胶织物的阳离子改性及活性染料无盐染色工艺, 产业用纺织品, 2021, 39(10), 40-45.

[65] 姚程健;邹尾容;范追追；王斯伟;蔡再生 UV聚合制备PSBMA超亲水涂层及其防雾、自清洁性能表征, 产业用纺织品, 2021, 39(08), 44-53.

[66] 靳凯丽;蔡再生 柔性超级电容器用织物基复合电极的制备及其性能研究, 产业用纺织品, 2021, 39(05), 38-44.

[67] 范追追;翟世雄;蔡再生 高性能单向导湿织物的制备研究, 针织工业, 2021, (01), 34-38.

[68] M Zhou, S Zhai, T Song，et al. Chemically and Physically Modified Flame-Retardant Silicone-Acrylic Emulsion Adhesive for Electrostatic Flocking, Journal of Inorganic and Organometallic Polymers and Materials, 2020, 30(11), 4342-4349.（IF：4.0）

[69] W Dong, M Zhou, Y Li，et al.Low-salt dyeing of cotton fabric grafted with pH-responsive cationic polymer of Polyelectrolyte 2-(N,N-dimethylamino)ethyl methacrylate, Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2020, 594, 124573.（IF：4.9）

[70] S Zhai, Z Fan, K Jin，et al.Synthesis of zinc sulfide/copper sulfide/porous carbonized cotton nanocomposites for flexible supercapacitor and recyclable photocatalysis with high performance, Journal of Colloid and Interface Science, 2020, 575, 306-316.（IF：9.4）

[71] Z Fan, H Zhao, M Zhou，et al.Three-dimensional Transport Fabrics with Ultrafast Water Transporting and Diffusion Inspired by River-Diversion, Materials Letters, 2020, 262, 127050.（IF：2.7）

[72] W Zou, Z Fan, S Zhai，et al.A multifunctional antifog, antifrost, and self-cleaning zwitterionic polymer coating based on poly(SBMA-co-AA), Journal of Coatings Technology and Research, 2020, 17(3), 765-776.（IF：2.3）

[73] L Li, Z Cai，et al.Flame-Retardant Performance of Transparent and Tensile-Strength-Enhanced Epoxy Resins, Polymers, 2020, 12(2), 317.（IF：4.7）

[74] X Chen, X Ye, L Lu，et al.Preparation of Cross-Linkable Waterborne Polyurethane-Acrylate Coating Films with Multifunctional Properties, Coatings, 2020, 10(1), 65.（IF：2.9）

[75] S Zhai, K Jin, M Zhou，et al.A novel high performance flexible supercapacitor based on porous carbonized cotton/ZnO nanoparticle/CuS micro-sphere, Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2020, 584, 124025.（IF：5.2）

[76] ZHOU M, LI X, ZHAO H, et al. Combined effect of nitrogen and oxygen heteroatoms and micropores of porous carbon frameworks from Schiff-base networks on their high supercapacitance [J]. Journal of Materials Chemistry A, 2018, 6(4): 1621-9. （IF: 10.66）

[77] LI X, WANG J, ZHAO Y, et al. Wearable solid-state supercapacitors operating at high working voltage with a flexible nanocomposite electrode [J]. ACS applied materials & interfaces, 2016, 8(39): 25905-14. （IF：8.69）

[78] LI X, ZHOU M, WANG J, et al. Flexible and internal series-connected supercapacitors with high working voltage using ultralight porous carbon nanofilms [J]. Journal of Power Sources, 2017, 342: 762-71. （IF：7.19）

[79] WANG J, LI X, GE F, et al. Carrier-Free and Low-Temperature Ultradeep Dyeing of Poly (ethylene terephthalate) Copolyester Modified with Sodium-5-sulfo-bis (hydroxyethyl)-isophthalate and 2-Methyl-1, 3-propanediol [J]. ACS Sustainable Chemistry & Engineering, 2016, 4(6): 3285-91. （IF:7.09）

[80] HAO D, YANG Y, XU B, et al. Bifunctional fabric with photothermal effect and photocatalysis for highly efficient clean water generation [J]. ACS Sustainable Chemistry & Engineering, 2018, 6(8): 10789-97. （IF:7.09）

[81] LI X, WANG J, GE F, et al. Facile fabrication of freestanding three-dimensional composites for supercapacitors [J]. Chemical Communications, 2016, 52(13): 2691-4. （IF: 6.12）

[82] JIN K, ZHOU M, ZHAO H, et al. Electrodeposited CuS nanosheets on carbonized cotton fabric as flexible supercapacitor electrode for high energy storage [J]. Electrochimica Acta, 2019, 295: 668-76. （IF: 5.26 ）

[83] SUN C, LI X, CAI Z, et al. Carbonized cotton fabric in-situ electrodeposition polypyrrole as high-performance flexible electrode for wearable supercapacitor [J]. Electrochimica Acta, 2019, 296: 617-26. （IF:5.26）

[84] SUN C, LI X, ZHAO J, et al. A freestanding polypyrrole hybrid electrode supported by conducting silk fabric coated with PEDOT:PSS and MWCNTs for high-performance supercapacitor [J]. Electrochimica Acta, 2019, 317: 42-51. （IF: 5.26）

[85] LI X, SUN （IF：2.2）C, CAI Z, et al. High-performance all-solid-state supercapacitor derived from PPy coated carbonized silk fabric [J]. Applied Surface Science, 2019, 473: 967-75. （IF: 4.93）

[86] CHEN Y, GE F, GUANG S, et al. Low-cost and large-scale flexible SERS-cotton fabric as a wipe substrate for surface trace analysis [J]. Applied Surface Science, 2018, 436: 111-6. （IF: 4.93）

[87] HAO D, YANG Y, XU B, et al. Efficient solar water vapor generation enabled by water-absorbing polypyrrole coated cotton fabric with enhanced heat localization [J]. Applied Thermal Engineering, 2018, 141: 406-12. （IF: 4.58）

[88] CHEN Y, GE F, GUANG S, et al. Self-assembly of Ag nanoparticles on the woven cotton fabrics as mechanical flexible substrates for surface enhanced Raman scattering [J]. Journal of Alloys and Compounds, 2017, 726: 484-9. （IF: 4.12）

[89] LIU C, CAI Z, ZHAO Y, et al. Potentiostatically synthesized flexible polypyrrole/multi-wall carbon nanotube/cotton fabric electrodes for supercapacitors [J]. Cellulose, 2016, 23(1): 637-48. （IF: 4.11）

[90] BO Y, ZHAO Y, CAI Z, et al. Facile synthesis of flexible electrode based on cotton/polypyrrole/multi-walled carbon nanotube composite for supercapacitors [J]. Cellulose, 2018, 25(7): 4079-91. （IF: 4.11）

[91] SUN C, ZHAO J, GUO Z, et al. A Novel Method to Fabricate Nitrogen and Oxygen Co‐Doped Flexible Cotton‐Based Electrode for Wearable Supercapacitors [J]. ChemElectroChem, 2019, 6(15): 4049-58. （IF: 3.87）