（1）期刊论文

[20] G. Zhang, Y. Xu, Y. Sun, X. Ye, L. Du^*, and H. Xu. Fabrication of Janus composite membranes with a gradient pore structure based on melt electrowriting and solution electrospinning for directional water transport, Langmuir, 2023, 39, 7891-7900.

[19] H. Xu, and L. Du. Sustainable medical materials printed by melt electrowriting: A mini-review, Current Opinion in Biomedical Engineering, 2023, 27, 100464.

[18] H. Lu, Y. Sun, Y. Chen, L. Nie, L. Yang, L. Du^*, and H. Xu. The effects of voltage configurations on print accuracy in melt electrowriting, Materials Letters, 2023, 334, 133738.

[17] X. Chen, Q. Zhang, Y. Wang, J. Meng, M. Wu, H. Xu*, L. Du*, and X. Yang. Fabrication and characterization of electrospun poly(caprolactone)/tannic acid scaffold as an antibacterial wound dressing, Polymers, 2023, 15, 593.

[16] L. Du, Y. Xu, H. Xu, X. Ye, and Y. Li. Highly directional water transport membrane made from a hybrid manufacturing approach: unleashing the power of melt electrowriting, Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2022, 641, 128486.

[15] L. Du, L. Yang, B. Xu, L. Nie, H. Lu, J. Wu, H. Xu, and Y. Lou. Melt electrowritten poly(caprolactone) lattices incorporated with silver nanoparticles for directional water transport antibacterial wound dressings, New Journal of Chemistry, 2022, 46, 13565.

[14] L. Du, L. Nie, L. Zhang, H. Lu, L. Yang, H. Xu, and J. Hou. Enhancing the printing accuracy of melt electrowritten fibers deposited on aluminum foils, Materials Letters, 2022, 321, 132397.

[13] H. Xu, I. Liashenko, A. Lucchetti, L. Du, Y. Dong, D. Zhao, J. Meng, H. Yamane, and P. D. Dalton. Designing with circular arc toolpaths to increase the complexity of melt electrowriting, Advanced Materials Technologies, 2022, 7, 2101676.

[12] H. Xu, S. Yagi, S. Ashour, L. Du, M. E. Hoque, and L. Tan. A review on current nanofiber technologies: electrospinning, centrifugal spinning, and electro-centrifugal spinning, Macromolecular Materials and Engineering, 2022, 308, 2200502.

[11] T. Xu, J. Gu, J. Meng, L. Du, A. Kumard, and H. Xu. Melt electrowriting reinforced composite membrane for controlled drug release, Journal of the Mechanical Behavior of Biomedical Materials, 2022, 132, 105277.

[10] Y. Yang, Y. Jiang, Q. Zhang, F. Zou, and L. Du*. A mixed faster R-CNN and positioning coordinates method for recognition of suit button arrangement with small sample sizes, International Journal of Clothing Science and Technology, 2022, 34, 532-548.

[9]    Z. Shen, J. Yang, H. Lu, F. Zou, and L. Du*. Study on the effects of knitted fabric parameters on fragrance retention performance, Fibers and Polymers, 2021, 22, 3222-3231.

[8]    Y. Lv, Z. Xu, and L. Du*. Visible-light-driven conversion of organic compounds over WO₃-based microtubes with mesoporous-walled structure, New Journal of Chemistry, 2020, 44, 6206-6212.

[7]    L. Du, F. Wang, J. Yang, Z. Shen, W. Zhao, F. Zou, H. Zhu, and S. Xu. Effect of fabric parameters on fragrance retention, Industria Textila, 2020, 71, 550-556.

[6]    L. Du, H. Xu, Y. Zhang, and F. Zou. Electrospun composite nanofibre fabrics containing green reduced Ag nanoparticles as an innovative type of antimicrobial insole, RSC Advances, 2019, 9, 2244-2251.

[5]    Y. Zhang, T. Li, F. Zou, C. Yu, and L. Du*. Facile fabrication of functional bra cup by an automated dispensing system, Industria Textila, 2019, 70, 421-425.

[4]    L. Du, H. Xu, Y. Zhang, and F. Y. Zou. Facile fabrication of ascorbyl palmitate loaded polycaprolactone/ silver nanoparticles embedded polyvinyl alcohol hybrid membranes as active wound dressings via dual-spinneret electrospinning, RSC Advances, 2017, 7, 31310-31318.

[3]    L. Du, H. Xu, Y. Zhang, and F. Zou. Electrospinning of polycaprolatone nanofibers with DMF additive: the effect of solution proprieties on jet perturbation and fiber morphologies, Fibers and Polymers, 2016, 17, 751-759.

[2]    L. Du, H. Xu, T. Li, Y. Zhang, and F. Zou. Fabrication of silver nanoparticle/polyvinyl alcohol/polycaprolactone hybrid nanofibers nonwovens by two-nozzle electrospinning for wound dressing, Fibers and Polymers, 2016, 17, 1995-2005.

[1]    L. Du, I. Tabata, and K. Hirogaki. A new nanoporous aramid fiber aerogel, Sen’i Gakkaishi, 2014, 70, 197-202.

（2）发明专利

[6]    杜磊, 张国萍, 徐煜, 杨柳, 沈鸿雅, 一种具有梯度孔结构的单向导湿微纳米纤维膜及其制备方法, ZL 202210316065.1 [P], 授权时间: 2023-05-29.

[5]    杜磊, 鲁华丽, 聂隆萍, 孙小童, 一种基于熔体近场直写的曲面接收方法及纺丝装置, ZL 202210314222.5 [P], 授权时间: 2023-03-24.

[4]    杜磊, 鲁华丽, 一种近场直写喷丝头装置, ZL 202110614106.0 [P], 授权时间: 2022-07-12.

[3]    杜磊, 杨柳, 一种基于近场直写与溶液电纺技术的双层单向导湿微纳米纤维膜的制备方法, ZL 202110615375.9 [P], 授权时间: 2022-11-11.

[2]    杜磊, 徐煜, 王文召, 李涛, 邹奉元, 一种梯度结构多层微纳米纤维复合敷料的制备方法, ZL 201910425173.0 [P], 授权时间: 2020-07-24.

[1]    杜磊, 沈卓颖, 王富香, 杨佳利, 一种基于电子鼻技术的织物留香持久性能定量表征方法, ZL 202010143570.1 [P], 授权时间: 2022-11-11.