Xiangfang Peng
About
Xiangfang Peng is a scholar working on Polymers and Plastics, Biomaterials and Biomedical Engineering.
According to data from OpenAlex, Xiangfang Peng has authored 223 papers receiving a total of 9.7k indexed citations (citations by other indexed papers that have themselves been cited), including 138 papers in Polymers and Plastics, 108 papers in Biomaterials and 79 papers in Biomedical Engineering. Recurrent topics in Xiangfang Peng's work include biodegradable polymer synthesis and properties (77 papers), Polymer Foaming and Composites (74 papers) and Electrospun Nanofibers in Biomedical Applications (41 papers). Xiangfang Peng is often cited by papers focused on biodegradable polymer synthesis and properties (77 papers), Polymer Foaming and Composites (74 papers) and Electrospun Nanofibers in Biomedical Applications (41 papers). Xiangfang Peng collaborates with scholars based in China, United States and Iran. Xiangfang Peng's co-authors include Lih‐Sheng Turng, Hao‐Yang Mi, Xin Jing, Tairong Kuang, An Huang, Max R. Salick, Lihong Geng, Zhixiang Cui, Dajiong Fu and Lingqian Chang and has published in prestigious journals such as Advanced Materials, Nature Communications and ACS Nano.
In The Last Decade
Xiangfang Peng
217 papers receiving 9.6k citations
Hit Papers
Peers — A (Enhanced Table)
Peers by citation overlap · career bar shows stage (early→late) cites · hero ref
| Name | h | Career | Trend | Papers | Cites | |||||
|---|---|---|---|---|---|---|---|---|---|---|
| Xiangfang Peng China | 52 | 4.2k | 4.1k | 3.7k | 1.7k | 926 | 223 | 9.7k | ||
| Yongjin Li China | 50 | 4.7k 1.1× | 3.5k 0.8× | 2.9k 0.8× | 1.8k 1.1× | 470 0.5× | 302 | 9.0k | ||
| Piming Ma China | 60 | 3.9k 0.9× | 5.0k 1.2× | 3.2k 0.9× | 1.9k 1.1× | 883 1.0× | 258 | 10.4k | ||
| Weifu Dong China | 50 | 2.7k 0.6× | 3.3k 0.8× | 2.3k 0.6× | 1.8k 1.1× | 680 0.7× | 239 | 8.0k | ||
| Yves Grohens France | 55 | 3.9k 0.9× | 3.8k 0.9× | 2.4k 0.6× | 2.3k 1.4× | 741 0.8× | 275 | 9.5k | ||
| Hao‐Yang Mi China | 51 | 3.6k 0.9× | 3.3k 0.8× | 4.9k 1.3× | 819 0.5× | 1000 1.1× | 195 | 8.7k | ||
| Lih‐Sheng Turng United States | 61 | 5.1k 1.2× | 6.0k 1.5× | 4.7k 1.3× | 1.0k 0.6× | 587 0.6× | 275 | 12.0k | ||
| Mingqing Chen China | 51 | 2.8k 0.7× | 2.9k 0.7× | 2.1k 0.6× | 2.3k 1.4× | 972 1.0× | 325 | 8.4k | ||
| Gan‐Ji Zhong China | 50 | 3.5k 0.8× | 3.5k 0.9× | 2.6k 0.7× | 1.4k 0.9× | 1.0k 1.1× | 228 | 7.5k | ||
| Qingwen Wang China | 56 | 5.8k 1.4× | 3.5k 0.9× | 4.2k 1.1× | 1.1k 0.7× | 1.0k 1.1× | 340 | 11.2k | ||
| Bin Fei Hong Kong | 56 | 3.8k 0.9× | 2.7k 0.7× | 2.7k 0.7× | 2.4k 1.4× | 1.3k 1.5× | 243 | 10.3k |
Countries citing papers authored by Xiangfang Peng
Since
Specialization
Citations
This map shows the geographic impact of Xiangfang Peng's research. It shows the number of citations coming from papers published by authors working in each country. You can also color the map by specialization and compare the number of citations received by Xiangfang Peng with the expected number of citations based on a country's size and research output (numbers larger than one mean the country cites Xiangfang Peng more than expected).
Fields of papers citing papers by Xiangfang Peng
Since
Specialization
Physical SciencesHealth SciencesLife SciencesSocial Sciences
This network shows the impact of papers produced by Xiangfang Peng. Nodes represent research fields, and links connect fields that are likely to share authors. Colored nodes show fields that tend to cite the papers produced by Xiangfang Peng. The network helps show where Xiangfang Peng may publish in the future.
Co-authorship network of co-authors of Xiangfang Peng
This figure shows the co-authorship network connecting the top 25 collaborators of Xiangfang Peng. A scholar is included among the top collaborators of Xiangfang Peng based on the total number of citations received by their joint publications. Widths of edges represent the number of papers authors have co-authored together. Node borders signify the number of papers an author published with Xiangfang Peng. Xiangfang Peng is excluded from the visualization to improve readability, since they are connected to all nodes in the network.
All Works
1.
Zhou, Minghao, et al.. (2025). Synergistic Effects of Chain Extender and Poly(Methyl Methacrylate) on the Foaming Behavior of High‐Performance Poly(butylene Succinate) Foams. Advanced Engineering Materials. 27(19).
2.
Chen, Tingjie, Gang Zhao, Zhaoxing Lin, et al.. (2025). Multifunctional plant fiber sponge integrated with polypyrrole and magnetic Fe₃O₄ nanoparticles for enhanced all-weather crude oil spill cleanup via photothermal and magnetic-thermal synergy. Industrial Crops and Products. 236. 121955–121955.
3.
Peng, Shuqiang, Yuheng Wang, Li Cai, et al.. (2025). Photothermal dual-cure 3D printing of mechanically robust microphase-separated hydrophobic ionic conductive elastomers. Composites Communications. 56. 102387–102387.
4.
Chen, Tingjie, Xia Chen, Yi Zhang, et al.. (2025). Biodegradable, Stretchable, and Self‐Healing Starch‐Based Hydrogel with Intelligent Multi‐Bond Network Facilitated by MXene Nanosheets for Multifunctional Wearable Electronics. Advanced Materials. 38(2). e12267–e12267.
5.
Huang, An, Siyong Gu, Zhenyu Yang, et al.. (2024). Flexible, Lightweight, and Hydrophobic TPU /CNT Nanocomposite Foam With Different Surface Microstructures for High‐Performance Wearable Piezoresistive Sensors. Journal of Polymer Science. 63(3). 709–723.
6.
Zhu, Wendong, Yangyang Zhang, Lihong Geng, et al.. (2024). Self-assembly polysaccharide network regulated hydrogel sensors with toughness, anti-freezing, conductivity and wide working conditions. Chemical Engineering Journal. 497. 154409–154409.
7.
Peng, Shuqiang, Jie Chen, Xinxin Zheng, et al.. (2023). Vat photopolymerization 3D printing of transparent, mechanically robust, and self-healing polyurethane elastomers for tailored wearable sensors. Chemical Engineering Journal. 463. 142312–142312.
8.
Huang, An, et al.. (2023). Lightweight, porous, stretchable nanocomposite foams with sandwich-like and bimodal cell structure by supercritical fluids-assisted processing for flexible strain sensor. The Journal of Supercritical Fluids. 204. 106112–106112.
9.
Wu, Jianming, et al.. (2023). Constructing triple-network cellulose nanofiber hydrogels with excellent strength, toughness and conductivity for real-time monitoring of human movements. Carbohydrate Polymers. 321. 121282–121282.
10.
Huang, An, et al.. (2023). A unique, flexible, and porous pressure sensor with enhanced sensitivity and durability by synergy of surface microstructure and supercritical fluid foaming. Applied Surface Science. 618. 156661–156661.
11.
Huang, An, et al.. (2023). Improved Energy Harvesting Ability of Single-Layer Binary Fiber Nanocomposite Membrane for Multifunctional Wearable Hybrid Piezoelectric and Triboelectric Nanogenerator and Self-Powered Sensors. ACS Nano. 18(1). 691–702.
12.
Qin, Zipeng, Gang Zhao, Yaoyang Zhang, et al.. (2023). A Simple and Effective Physical Ball‐Milling Strategy to Prepare Super‐Tough and Stretchable PVA@MXene@PPy Hydrogel for Flexible Capacitive Electronics. Small. 19(45). e2303038–e2303038.
13.
Huang, An, et al.. (2022). Supercritical Fluids-Assisted Processing Using CO2 Foaming to Enhance the Dispersion of Nanofillers in Poly(butylene succinate)-Based Nanocomposites and the Conductivity. Journal of Polymers and the Environment. 30(7). 3063–3077.
14.
Huang, An, Bin Tan, Fangjuan Wu, et al.. (2022). Facial Preparation of Segregated Poly(butylene succinate)/Carbon Nanotubes Composite Foams with Superior Conductive Properties via Synergistic Effect of High Pressure Solid Phase Molding and Supercritical Fluid Foaming. Macromolecular Materials and Engineering. 307(11).
15.
Huang, An, et al.. (2021). Novel PTFE/CNT composite nanofiber membranes with enhanced mechanical, crystalline, conductive, and dielectric properties fabricated by emulsion electrospinning and sintering. Composites Science and Technology. 214. 108980–108980.
16.
Cheng, Jiaqi, Jiahui Wu, Zhixiang Cui, et al.. (2020). Highly Efficient Removal of Methylene Blue Dye from an Aqueous Solution Using Cellulose Acetate Nanofibrous Membranes Modified by Polydopamine. ACS Omega. 5(10). 5389–5400.
17.
Li, Lengwan, Matthias M. L. Arras, Tianyu Li, et al.. (2019). Alternating crystalline lamellar structures from thermodynamically miscible poly(ε-caprolactone) H/D blends. Polymer. 175. 320–328.
18.
Peng, Xiangfang, et al.. (2019). Fabrication of Poly(lactic acid)/Silkworm Excrement Composite with Enhanced Crystallization, Toughness and Biodegradation Properties. Journal of Polymers and the Environment. 28(1). 295–303.
19.
Jing, Xin, Hao‐Yang Mi, Xiangfang Peng, & Lih‐Sheng Turng. (2016). Matrigel immobilization on the shish-kebab structured poly(ε-caprolactone) nanofibers for skin tissue engineering. AIP conference proceedings. 1713. 80006–80006.
20.
Peng, Jun, et al.. (2011). Study of Microcellular Injection Molding with Expandable Thermoplastic Microsphere. International Polymer Processing. 26(3). 249–255.
Rankless uses publication and citation data sourced from OpenAlex, an open and comprehensive bibliographic database. While OpenAlex provides broad and valuable coverage of the global research landscape, it—like all bibliographic datasets—has inherent limitations. These include incomplete records, variations in author disambiguation, differences in journal indexing, and delays in data updates. As a result, some metrics and network relationships displayed in Rankless may not fully capture the entirety of a scholar's output or impact.
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