Your search keyword '"Huang, Yiwan"' showing total 4 results

1. Synthesis and Characterisation of Hemihydrate Gypsum–Polyacrylamide Composite: A Novel Inorganic/Organic Cementitious Material.

Author

Chen, Yuan, Mi, Zerui, Yang, Jiatong, Zheng, Xuan, Wang, Huihu, Record, Marie-Christine, Boulet, Pascal, Wang, Juan, Albina, Jan-Michael, and Huang, Yiwan

Subjects

POLYACRYLAMIDE, COMPOSITE materials, X-ray diffraction, FLEXURAL strength, COMPRESSIVE strength, SLURRY, ACRYLAMIDE

Abstract

This study combined inorganic α-hemihydrate gypsum (α-HHG) with organic polyacrylamide (PAM) hydrogel to create a novel α-HHG/PAM composite material. Through this facile composite strategy, this fabricated material exhibited a significantly longer initial setting time and higher mechanical strength compared to α-HHG. The effects of the addition amount and the concentration of PAM precursor solution on the flowability of the α-HHG/PAM composite material slurry, initial setting time, and mechanical properties of the hardened specimens were investigated. The structural characteristics of the composite material were examined using XRD, FE-SEM, and TGA. The results showed that the initial setting time of the α-HHG/PAM composite material was 25.7 min, which is an extension of 127.43% compared to that of α-HHG. The flexural strength and compressive strength of the oven-dried specimens were 23.4 MPa and 58.6 MPa, respectively, representing increases of 34.73% and 84.86% over values for α-HHG. The XRD, FE-SEM, and TGA results all indicated that the hydration of α-HHG in the composite material was incomplete. The incompleteness is caused by the competition between the hydration process of inorganic α-HHG and the gelation process of the acrylamide molecules for water, which hinders some α-HHG from entirely reacting with water. The enhanced mechanical strength of the α-HHG/PAM composite material results from the tight interweaving and integrating of organic and inorganic networks. This study provides a concise and efficient approach to the modification research of hemihydrate gypsum. [ABSTRACT FROM AUTHOR]

Published

2024

2. Mechanical enhancement of graphene oxide-filled chitosan-based composite hydrogels by multiple mechanisms.

Author

Huang, Yiwan, Xiao, Longya, Zhou, Ju, Li, Xuefeng, Liu, Jianxin, and Zeng, Ming

Subjects

*ENERGY dissipation, *POLYACRYLAMIDE, *HYDROGELS, *COLLOIDS, *CHITOSAN

Abstract

Chitosan (CS) has become a favorable choice for synthesizing hydrogels due to its hydrophilic and biocompatible nature. However, achieving robust CS-based hydrogels remains challenging. Herein, we propose a multiple mechanisms-based network design for mechanical enhancement in CS-based double-network (DN) composite hydrogels. In the DN composite gels, graphene oxide-filled CS-based network serves as the first network and polyacrylamide network is the second network. The multi-structure of the first network enhances its energy dissipation capacity; when combining with the second network to form DN structure, the coupling effect between the multiple mechanisms-based networks allows for much more energy dissipation, enabling synergistic enhancement in mechanical properties of the DN composite gels. By regulating the mechanics, we further explore the role of the individual networks. The results indicate that both the individual networks are essential: The first network primarily contributes to the energy dissipation, while the second network plays a role to the synergistic enhancement in the DN composite gels. This work provides an effective reinforcing strategy for CS-based composite hydrogels. [ABSTRACT FROM AUTHOR]

Published

2020

3. Chemical structure and remarkably enhanced mechanical properties of chitosan-graft-poly(acrylic acid)/polyacrylamide double-network hydrogels.

Author

Zeng, Ming, Feng, Zijian, Huang, Yiwan, Liu, Jianxin, Ren, Jie, Xu, Qingyu, and Fan, Liren

Subjects

CHEMICAL structure, MECHANICAL properties of polymers, CHITOSAN, POLYACRYLIC acid, POLYACRYLAMIDE, HYDROGELS, GRAFT copolymers

Abstract

The novel double-network (DN) hydrogels were prepared using the chitosan- g-poly(acrylic acid) as the first network, and polyacrylamide as the second. The effects of the concentrations of the second network on chemical structure, intermolecular interactions and mechanical properties for the DN gels were investigated. The DN hydrogels had decreased swelling capacities and significantly improved glassy modulus and strength with the increase of the acrylamide concentration, owing to the enhanced intermolecular interaction and physical entanglement, and reduced molecular motion. It is worth noting that DN hydrogels with 5.50 mol/L acrylamide content had the greatest mechanical strength and still relatively high water content (~82 wt%), resulting from the effectiveness of the intermolecular penetration and intermolecular interactions between two independent polymer networks. Therefore, the reported novel chitosan-based DN hydrogels exhibit good potentials in some applications, for example biomedical engineering applications. [ABSTRACT FROM AUTHOR]

Published

2017

4. Super Bulk and Interfacial Toughness of Amylopectin Reinforced PAAm/PVA Double‐Network Hydrogels via Multiple Hydrogen Bonds.

Author

Zhang, Yikun, Li, Dapeng, Huang, Yiwan, Long, Shijun, Li, Haiyan, and Li, Xuefeng

Subjects

AMYLOPECTIN, HYDROGEN bonding, BULK solids, HYDROGELS, POLYVINYL alcohol, POLYACRYLAMIDE, FLEXIBLE electronics, TENSILE strength

Abstract

A simple, multiple‐hydrogen‐bond approach to fabricating physically crosslinked, Amylopectin reinforced polyacrylamide/poly(vinyl alcohol) (Amy/PAAm/PVA) double‐network (DN) hydrogels with super toughness in bulk and at solid interfaces is reported. The Amy/PAAm/PVA DN hydrogels exhibit high tensile strength (854.1 kPa), high extensibility (≈eight times), high bulk toughness (4094.8 kJ m−3), good self‐recovery property (≈92% of self‐recovery at room temperature), and strong adhesion to nonporous glass surfaces (≈158 kPa). Such tough and adhesive DN hydrogels have great potential for various applications in engineering artificial soft tissues, flexible electronics, and wearable devices. [ABSTRACT FROM AUTHOR]

Published

2020