Chemical Industry and Engineering Progress ›› 2021, Vol. 40 ›› Issue (5): 2613-2623.DOI: 10.16085/j.issn.1000-6613.2020-1283
• Materials science and technology • Previous Articles Next Articles
HUANG Guanhua(), LIU Xuyan, FANG Chenxi, GU Qingfeng, LEI Hao
Received:
2020-07-07
Online:
2021-05-24
Published:
2021-05-06
Contact:
HUANG Guanhua
通讯作者:
黄冠华
作者简介:
黄冠华(1981—),女,博士,讲师,研究方向为生物功能材料。E-mail:基金资助:
CLC Number:
HUANG Guanhua, LIU Xuyan, FANG Chenxi, GU Qingfeng, LEI Hao. Methods and application of magnetic hollow microsphere prepared from bio-template[J]. Chemical Industry and Engineering Progress, 2021, 40(5): 2613-2623.
黄冠华, 刘序彦, 房晨曦, 顾庆峰, 雷浩. 生物模板法制备磁性中空微球的方法和应用[J]. 化工进展, 2021, 40(5): 2613-2623.
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制备技术 | 模板组成 | 微球组成 | 制备方法 | 微球构型 | 参考文献 |
---|---|---|---|---|---|
软模板法 | 酵母 | Fe 掺杂CeO2 | 共沉淀+高温炭化 | 壳磁型 | [ |
松花粉 | MgFe2O4/γ-Fe2O3 | 高温炭化+水热碳化 | 壳磁型 | [ | |
松花粉 | ZnFe2O4/MgAl-LDH | 高温炭化+水热碳化 | 壳磁型 | [ | |
油菜花粉 | ZSM-5/SiO2/Fe3O4 | 共沉淀+高温炭化 | 多磁壳型 | [ | |
自模板法 | 微藻 | Fe3O4+生物炭 | 高温炭化 | 壳磁型 | [ |
微藻 | Fe3O4+生物炭 | 水热碳化+高温炭化 | 壳磁型 | [ | |
微藻 | Fe3O4+生物炭 | 水热碳化 | 多磁核型 | [ | |
蒲公英花粉 | CoFeO4 | 水热碳化 | 多磁核型 | [ | |
微藻 | Fe3O4+微藻 | 吸附 | 磁壳型 | [ | |
微藻 | Fe3O4+微藻 | 吸附+共沉淀 | 磁壳型 | [ | |
微藻 | 石墨烯+Fe3O4+生物炭+微藻 | 吸附+共沉淀 | 磁壳型 | [ | |
灵芝孢子 | 生物炭+ Fe3O4 | 高温炭化+共沉淀 | 磁壳型 | [ |
制备技术 | 模板组成 | 微球组成 | 制备方法 | 微球构型 | 参考文献 |
---|---|---|---|---|---|
软模板法 | 酵母 | Fe 掺杂CeO2 | 共沉淀+高温炭化 | 壳磁型 | [ |
松花粉 | MgFe2O4/γ-Fe2O3 | 高温炭化+水热碳化 | 壳磁型 | [ | |
松花粉 | ZnFe2O4/MgAl-LDH | 高温炭化+水热碳化 | 壳磁型 | [ | |
油菜花粉 | ZSM-5/SiO2/Fe3O4 | 共沉淀+高温炭化 | 多磁壳型 | [ | |
自模板法 | 微藻 | Fe3O4+生物炭 | 高温炭化 | 壳磁型 | [ |
微藻 | Fe3O4+生物炭 | 水热碳化+高温炭化 | 壳磁型 | [ | |
微藻 | Fe3O4+生物炭 | 水热碳化 | 多磁核型 | [ | |
蒲公英花粉 | CoFeO4 | 水热碳化 | 多磁核型 | [ | |
微藻 | Fe3O4+微藻 | 吸附 | 磁壳型 | [ | |
微藻 | Fe3O4+微藻 | 吸附+共沉淀 | 磁壳型 | [ | |
微藻 | 石墨烯+Fe3O4+生物炭+微藻 | 吸附+共沉淀 | 磁壳型 | [ | |
灵芝孢子 | 生物炭+ Fe3O4 | 高温炭化+共沉淀 | 磁壳型 | [ |
制备技术 | 模板组成 | 制备方法 | 微球组成 | 参考文献 |
---|---|---|---|---|
硬模板法 | ||||
非生物模板 | SiO2 | 碱液蚀溶 | γ-Fe2O3/TiO2 | [ |
Fe3O4/CaCO3 | 酸液蚀溶 | Fe3O4/PMMA | [ | |
软模板法 | ||||
生物模板 | 油菜花粉 | 共沉淀+高温炭化 | ZSM-5/SiO2/Fe3O4 | [ |
非生物模板 | 十二烷基磺酸钠,聚乙烯吡咯烷酮 | 高温炭化 | (Co,Ce)-TiO2-SiO2/NiFe2O4 | [ |
聚苯乙烯 | 高温煅烧 | Fe3O4/SiO2 | [ | |
十八烷基三甲氧基硅烷 | 水热碳化 | γ-Fe2O3/SiO2 | [ | |
硬模板法+软模板法 | ||||
非生物模板 | SiO2,十八烷基三甲氧基硅烷 | 碱液蚀溶+高温炭化 | Fe3O4/SiO2 | [ |
自模板法 | ||||
生物模板 | 微藻 | 高温炭化 | Fe3O4+生物炭 | [ |
非生物模板 | SiO2 | 共沉淀 | SiO2/MeFe2O4 | [ |
制备技术 | 模板组成 | 制备方法 | 微球组成 | 参考文献 |
---|---|---|---|---|
硬模板法 | ||||
非生物模板 | SiO2 | 碱液蚀溶 | γ-Fe2O3/TiO2 | [ |
Fe3O4/CaCO3 | 酸液蚀溶 | Fe3O4/PMMA | [ | |
软模板法 | ||||
生物模板 | 油菜花粉 | 共沉淀+高温炭化 | ZSM-5/SiO2/Fe3O4 | [ |
非生物模板 | 十二烷基磺酸钠,聚乙烯吡咯烷酮 | 高温炭化 | (Co,Ce)-TiO2-SiO2/NiFe2O4 | [ |
聚苯乙烯 | 高温煅烧 | Fe3O4/SiO2 | [ | |
十八烷基三甲氧基硅烷 | 水热碳化 | γ-Fe2O3/SiO2 | [ | |
硬模板法+软模板法 | ||||
非生物模板 | SiO2,十八烷基三甲氧基硅烷 | 碱液蚀溶+高温炭化 | Fe3O4/SiO2 | [ |
自模板法 | ||||
生物模板 | 微藻 | 高温炭化 | Fe3O4+生物炭 | [ |
非生物模板 | SiO2 | 共沉淀 | SiO2/MeFe2O4 | [ |
制备技术 | 模板来源 | 生产工艺 | 模板去除率 | 产品构型 | 环境保护 | 生物兼容性 |
---|---|---|---|---|---|---|
生物模板法 | ||||||
软模板法 | 自然界(受限) | 简单 | 高 | 好控制 | 好 | 好 |
自模板法 | 自然界(受限) | 简单 | — | 好控制 | 好 | 好 |
非生物模板法 | 无机和有机材料(不受限) | 较复杂 | 一般 | 不好控制 | 差 | 待评估 |
制备技术 | 模板来源 | 生产工艺 | 模板去除率 | 产品构型 | 环境保护 | 生物兼容性 |
---|---|---|---|---|---|---|
生物模板法 | ||||||
软模板法 | 自然界(受限) | 简单 | 高 | 好控制 | 好 | 好 |
自模板法 | 自然界(受限) | 简单 | — | 好控制 | 好 | 好 |
非生物模板法 | 无机和有机材料(不受限) | 较复杂 | 一般 | 不好控制 | 差 | 待评估 |
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