In situ enhancing thermal and mechanical properties of novel green WPAI nanocomposite membrane via artificially cultivated biomass-based diatom frustules

Shi, Yunu1; Li, Bin1,2; Jiang, Xiaofang1; Yu, Chuanyong3; Li, Tao1; Sun, Haoyang1; Chen, Shiwei1; Li, Dandan1; Sun, Dazhi1

2023-02-01

10.1007/s42114-022-00621-0

ADVANCED COMPOSITES AND HYBRID MATERIALS   影响因子和分区

2522-0128

2522-0136

Water-based polyamide-imide (WPAI) resin has received extensive attention due to its greenness, safety, and favorable comprehensive properties. However, its low degree of molecular chain crosslinking results in poor heat resistance and mechanical strength, which seriously restricts its application as a matrix material for composite membranes. In this work, WPAI composite membranes were fabricated via the incorporation of artificially cultured diatom frustules (DFs), a biomass-based silicon dioxide material with a 3D penetration network structure. The prepared DFs@WPAI nanocomposite membranes are a novel green water-based material, which notably minimizes the utilization of toxic organic solvents. Moreover, the DFs-5@WPAI nanocomposite membrane after systematic optimization of structure and composition exhibits superior thermal stability (maximum servicing temperature of 514C) and mechanical strength (especially hardness of 0.39 GPa), which is comparable to those of the organic solvent-based composite membranes. The strengthening mechanisms of the DFs@WPAI nanocomposite membranes are attributed to the dual effects of physical riveting and in-situ chemical bonding between the DFs and the WPAI resin.

Green water-based nanocomposite membrane Biomass-based diatom frustules 3D penetration network structure Physical riveting In situ chemical bonding

SCI

英语

第一 ; 通讯

Guangdong Pro-vincial Key Laboratory Program[2021B1212040001] ; Department of Science and Technology of Guangdong Province, the Shenzhen Science and Technology Innovation Committee[KQJSCX20180322152424539] ; Southern University of Science and Technology and Taili Energy Co. Ltd., and the Postdoctoral Research Foundation of China[2021M691399]

Science & Technology - Other Topics ; Materials Science

Nanoscience & Nanotechnology ; Materials Science, Composites

WOS:000909973100001

SPRINGERNATURE

Web of Science

1.Southern Univ Sci & Technol, Dept Mat Sci & Engn, Guangdong Prov Key Lab Funct Oxide Mat & Devices, Shenzhen 518055, Peoples R China
2.China Merchants Marine Equipment Res Inst Co Ltd, Shenzhen 518063, Peoples R China
3.Jinan Univ, Inst Adv Wear & Corros Resistant & Funct Mat, Guangzhou 510632, Peoples R China

Shi, Yunu,Li, Bin,Jiang, Xiaofang,et al. In situ enhancing thermal and mechanical properties of novel green WPAI nanocomposite membrane via artificially cultivated biomass-based diatom frustules[J]. ADVANCED COMPOSITES AND HYBRID MATERIALS,2023,6(1).

Shi, Yunu.,Li, Bin.,Jiang, Xiaofang.,Yu, Chuanyong.,Li, Tao.,...&Sun, Dazhi.(2023).In situ enhancing thermal and mechanical properties of novel green WPAI nanocomposite membrane via artificially cultivated biomass-based diatom frustules.ADVANCED COMPOSITES AND HYBRID MATERIALS,6(1).

Shi, Yunu,et al."In situ enhancing thermal and mechanical properties of novel green WPAI nanocomposite membrane via artificially cultivated biomass-based diatom frustules".ADVANCED COMPOSITES AND HYBRID MATERIALS 6.1(2023).