中文
Earlier issues
Announcement
More
Progress in Chemistry 2010, Vol. 22 Issue (06): 1094-1101 Previous Articles   Next Articles

• Invited Article •

Research Progress in Supramolecular Metallogels

Chen Kai; Jin Xin; Tang Liming**   

  1. (Laboratory of Advanced Materials, Department of Chemical Engineering, Tsinghua University, Beijing 100084, China)
  • Received: Revised: Online: Published:
  • Contact: Tang Liming E-mail:tanglm@tsinghua.edu.cn;tanglm@mail.tsinghua.edu.cn
PDF ( 2311 ) Cited
Export

EndNote

Ris

BibTeX

Supramolecular gels have evolved into a class of smart/functional nanomaterials with extensive application potentials recently. Most supramolecular gels studied today employ hydrogen bonding or molecular stacking as the driving force for gelation. Despite the major role that metal coordination plays in supramolecular chemistry, the use of metal-ligand interactions in the area of supramolecular gels has been somewhat neglected until very recently. Supramolecular gels including metal ions can capitalize on the unique richness of the attributes of metal ions such as photo-electronic, catalytic, redox, which stimulates research in this area. In this review, the basic concepts of metallogels are first given, and then detailed examples are presented to relate the molecular structures especially the complexing groups, metal ions used to the properties and functions of the gels, which are divided into two categories: gelator based metallogels and coordination polymer gels. Moreover, abnormal gelation behaviors in metallogels will be briefed.

Contents
1 Definition of supramolecular metallogel
2 Classification of supramolecular metallogels
2.1 Metallogels based on gelators
2.2 Metallogels based on coordination polymers
3 Abnormal gelation behaviors of metallogels
4 Conclusions

Key words: supramolecular metallogel, coordination, structure

CLC Number: 

[1] Jianfeng Yan, Jindong Xu, Ruiying Zhang, Pin Zhou, Yaofeng Yuan, Yuanming Li. Nanocarbon Molecules — the Fascination of Synthetic Chemistry [J]. Progress in Chemistry, 2023, 35(5): 699-708.
[2] Yan Bao, Jiachen Xu, Ruyue Guo, Jianzhong Ma. High-Sensitivity Flexible Pressure Sensor Based on Micro-Nano Structure [J]. Progress in Chemistry, 2023, 35(5): 709-720.
[3] Yixue Xu, Shishi Li, Xiaoshuang Ma, Xiaojin Liu, Jianjun Ding, Yuqiao Wang. Surface/Interface Modulation Enhanced Photogenerated Carrier Separation and Transfer of Bismuth-Based Catalysts [J]. Progress in Chemistry, 2023, 35(4): 509-518.
[4] Yue Yang, Ke Xu, Xuelu Ma. Catalytic Mechanism of Oxygen Vacancy Defects in Metal Oxides [J]. Progress in Chemistry, 2023, 35(4): 543-559.
[5] Niu Wenhui, Zhang Da, Zhao Zhengang, Yang Bin, Liang Feng. Development of Na-Based Seawater Batteries: “Key Components and Challenges” [J]. Progress in Chemistry, 2023, 35(3): 407-420.
[6] Yang Guodong, Yuan Gaoqian, Zhang Jingzhe, Wu Jinbo, Li Faliang, Zhang Haijun. Porous Electromagnetic Wave Absorbing Materials [J]. Progress in Chemistry, 2023, 35(3): 445-457.
[7] Jiang Haoyang, Xiong Feng, Qin Mulin, Gao Song, He Liuruyi, Zou Ruqiang. Conductive Phase Change Materials (PCMs) for Electro-to-Thermal Energy Conversion, Storage and Utilization [J]. Progress in Chemistry, 2023, 35(3): 360-374.
[8] Xiaojun Liu, Lang Qin, Yanlei Yu. Light-Driven Handedness Inversion of Cholesteric Liquid Crystals [J]. Progress in Chemistry, 2023, 35(2): 247-262.
[9] Xuan Li, Jiongpeng Huang, Yifan Zhang, Lei Shi. 1D Nanoribbons of 2D Materials [J]. Progress in Chemistry, 2023, 35(1): 88-104.
[10] Chao Ji, Tuo Li, Xiaofeng Zou, Lu Zhang, Chunjun Liang. Two-Dimensional Perovskite Photovoltaic Devices [J]. Progress in Chemistry, 2022, 34(9): 2063-2080.
[11] Chunyi Ye, Yang Yang, Xuexian Wu, Ping Ding, Jingli Luo, Xianzhu Fu. Preparation and Application of Palladium-Copper Nano Electrocatalysts [J]. Progress in Chemistry, 2022, 34(9): 1896-1910.
[12] Xu Zhang, Lei Zhang, Shanen Huang, Zhifang Chai, Weiqun Shi. Preparation of Salt-Inclusion Materials in High-Temperature Molten Salt System and Their Potential Application [J]. Progress in Chemistry, 2022, 34(9): 1947-1956.
[13] Shunxin Gu, Qin Jiang, Pengfei Shi. Antitumor Activity and Application of Luminescent Iridium(Ⅲ) Complexes [J]. Progress in Chemistry, 2022, 34(9): 1957-1971.
[14] Leyi Wang, Niu Li. Relation Among Cu2+, Brønsted Acid Sites and Framework Al Distribution: NH3-SCR Performance of Cu-SSZ-13 Formed with Different Templates [J]. Progress in Chemistry, 2022, 34(8): 1688-1705.
[15] Meng Wang, He Song, Yewen Li. Three Dimensional Self-Assembled Blue Phase Liquid Crystalline Photonic Crystal [J]. Progress in Chemistry, 2022, 34(8): 1734-1747.