Your search keyword '"Ling, Fangwei"' showing total 4 results

1. Wide-range linear viscoelastic hydrogels with high mechanical properties and their applications in quantifiable stress-strain sensors

Author

Ma, Changshu, Wang, Yi, Jiang, Zuming, Cao, Zhenxing, Yu, Huiting, Huang, Guangsu, Wu, Qi, Ling, Fangwei, Zhuang, Zhumei, Wang, Huanan, Zheng, Jing, and Wu, Jinrong

Published

2020

2. Stereocomplex-type polylactide with remarkably enhanced melt-processability and electrical performance via incorporating multifunctional carbon black.

Author

Liu, Zhenwei, Ling, Fangwei, Diao, Xingyuan, Fu, Meirui, Bai, Hongwei, Zhang, Qin, and Fu, Qiang

Subjects

*POLYLACTIC acid, *CARBON-black, *PLASTICS engineering, *INJECTION molding, *THERMOMECHANICAL properties of metals, *ELECTROMAGNETIC interference

Abstract

As a popular "green" engineering plastic, stereocomplex-type polylactide (SC-PLA) exhibits great application potential in various fields owing to its outstanding physicochemical performance and durability. However, the applications of SC-PLA still face formidable challenges mostly associated with its inferior melt-processability (i.e., the weak melt memory effect to motivate exclusive SC crystallization and extremely low melt viscosity) and the lack of necessary functional features (e.g., electrical conductivity) in some cases. Herein, we devise a facile and robust strategy to overcome these obstacles by incorporating carbon black (CB) into equimolar poly(L-lactide)/poly(D-lactide) (PLLA/PDLA) blend. It is interesting to find that the CB particles can adsorb many PLLA/PDLA chain segments on their surface and such strongly adsorbed PLA segments could interact with PLA chains outside the surface to form physical junctions capable of stabilizing the PLLA/PDLA chain assemblies in the melt, finally inducing the exclusive SC formation during subsequent crystallization. Meanwhile, the CB particles can substantially enhance the melt viscosity of the blend (from 3.9 Pa s to 844.1 Pa s when measuring at 250 °C and 50 Hz). Because of the greatly improved melt-processability, the PLLA/PDLA/CB composites have been successfully processed into highly crystalline products with exclusive SC crystallites and excellent thermomechanical performance by injection molding. Additionally, the CB particles can endow the composite products with fascinating electrical conductivity (19.0 S/m) and electromagnetic interference shielding effectiveness (26.6 dB). This work could open up a promising avenue towards high-performance and multifunctional PLA engineering Bioplastic. Image 1 • CB particles are used to improve the melt-processability and electrical performance of SC-PLA. • The CB particles exhibit strong adsorbability for PLLA/PDLA chain segments. • The adsorbed PLA segments contribute to the greatly enhanced melt memory effect and melt viscosity. • The PLLA/PDLA/CB composites can be injection molded into products with exclusive SC crystallites. • The obtained products possess superb thermomechanical and electrical properties. [ABSTRACT FROM AUTHOR]

Published

2020

3. Stereocomplex-type polylactide with bimodal melting temperature distribution: Toward desirable melt-processability and thermomechanical performance.

Author

Liu, Zhenwei, Fu, Meirui, Ling, Fangwei, Sui, Guopeng, Bai, Hongwei, Zhang, Qin, and Fu, Qiang

Subjects

*TEMPERATURE distribution, *MANUFACTURING processes, *THERMOMECHANICAL properties of metals, *NUCLEATING agents, *CRYSTAL orientation, *BIODEGRADABLE plastics, *POLYLACTIC acid

Abstract

Recently, stereocomplex-type polylactide (SC-PLA) has generated growing interest because the unique SC crystals can provide drastic improvement in the heat/chemical resistances and durability of bio-derived and biodegradable PLA, exhibiting great potential to compete with some petroleum-derived engineering plastics in diverse applications. However, SC-PLA suffers from poor melt memory effect as well as significant thermal degradation after being completely melted at temperatures above 250 °C, which make it challenging to converse SC-PLA into useful products using versatile melt-processing technologies. With these challenges in mind, in this work, we propose a facile and practical strategy to fabricate SC-PLA products with exceptional thermomechanical properties through low-temperature melt-processing of SC-PLA powder with a bimodal melting temperature distribution. The results show that the melting temperature (T m) bimodality makes SC-PLA powder able to be easily injection molded at a relatively low temperature of 210 °C (between the two T m s) due to the selective melting of the low- T m SC-PLA component (SC- l PLA, ca. 20–40 wt%), indicating a good melt-processability. Meanwhile, the high- T m SC-PLA (SC- h PLA) component can directly deliver its desirable properties to the injection molded SC-PLA products. More importantly, during the injection molding process, the unmelted SC- h PLA particles can also induce the exclusive SC crystallization of the SC- l PLA melt as nucleating agent and greatly amplify the shear stress imposed on the melt as "rigid particles", finally generating numerous oriented SC structure in the SC- l PLA. Consequently, the injection molded SC- h PLA/SC- l PLA products exhibit impressively high tensile strength (74.3 MPa) and Vicat softening temperature (211.6 °C). Overall, this work presents an effective guidance for achieving desirable melt-processability of SC-PLA without sacrificing its thermomechanical properties and provides an industrial processing route towards high-performance SC-PLA products. Image 106841 • SC-PLA products were fabricated by low-temperature melt-processing of bimodal SC-PLA powder. • The melting temperature bimodality plays a key role in achieving balanced melt-processability and product performance. • The SC- l PLA component can provide the powder with good low-temperature melt-processability. • The SC- h PLA component can endow the melt-processed products with exceptional thermomechanical performance. • SC- h PLA induced exclusive SC formation and crystal orientation can also contribute to the enhanced performance. [ABSTRACT FROM AUTHOR]

Published

2019

4. Branching function of terminal phosphate groups of polyisoprene chain.

Author

Li, Shiqi, Tang, Maozhu, Huang, Cheng, Zhang, Rong, Wu, Jinrong, Ling, Fangwei, Xu, Yun-Xiang, and Huang, Guangsu

Subjects

*DIELECTRIC relaxation, *PHOSPHATES, *RUBBER, *IRON ions, *CONTACT angle

Abstract

The branching structure formed by α terminal of natural rubber (NR) was believed to be critical for its superior mechanical properties. However, it is challenging to unravel and mimic the relationship between the terminal structures and properties of NR due to the complexity of the system. Herein we synthesized a model compound containing phosphate groups at the end of the polyisoprene rubber to explore the role of α-terminal. After a series of tests, it is found that the phosphate groups formed branching points with or without iron ions. TEM test showed that sizes of aggregates formed by phosphate groups changed to be smaller after addition of FeCl 3. Water contact angle test verify the formation of branching structures. Rheology test showed that branching structures increased their storage modulus G' compared to linear polymer. The effects of phosphate groups aggregations on the chain dynamics were also investigated. Dielectric relaxation analysis indicated that the branching structure formed by phosphate groups confined the chain movement. All the above results help us to get a deeper understanding on the structural formation and function about α-terminal groups of NR. Image 1 • A model compound containing phosphate groups at the end of the polyisoprene chain was synthesized. • The branching structure formed by phosphate groups was confirmed. • The effects of branching structure on storage modulus and chain dynamics were investigated. [ABSTRACT FROM AUTHOR]

Published

2019