Your search keyword '"design strategy"' showing total 6 results

1. Hydrogen‐Bonded Organic Frameworks as an Appealing Platform for Luminescent Sensing.

Author

Xiong, Zhile, Xiang, Shengchang, Lv, Yuanchao, Chen, Banglin, and Zhang, Zhangjing

Subjects

*POLLUTANTS, *POROUS materials, *INTERMOLECULAR interactions, *HYDROGEN bonding, *SENSES

Abstract

Hydrogen‐bonded organic frameworks (HOFs), a novel subclass of porous crystalline materials self‐assembled from organic linkers through hydrogen bonding and other intermolecular interactions, have emerged as an exciting platform for developing multifunctional materials. Recently, luminescent HOF sensors have drawn considerable attention due to their unique advantages, such as hydrogen‐bonding flexibility, inherent luminescent centers in organic linkers, ease of functionalization, low density and toxicity, and good stability. However, a comprehensive study on the design strategies, functionalities, and applications of HOFs in sensing is lacking. In this review, the uniqueness and development of luminescent sensing HOFs are outlined. The design principles and strategies to enable the sensing performance are summarized, including the pre‐design of luminescent organic linkers and post‐modification with additional luminescent species. The state‐of‐the‐art advances in diverse sensing applications are overviewed, such as the detection of chemical pollutants, biomolecules, gases, and physical factors like temperature and mechanical forces. Moreover, the current challenges and corresponding potential avenues are discussed. This review aims to inspire more innovative research on the fabrication of advanced HOFs for luminescent sensing functions. [ABSTRACT FROM AUTHOR]

Published

2024

2. Smart Skin‐Adhesive Patches: From Design to Biomedical Applications.

Author

Wong, Siu Hong Dexter, Deen, G. Roshan, Bates, Jeffrey S., Maiti, Chiranjit, Lam, Ching Ying Katherine, Pachauri, Abhishek, AlAnsari, Renad, Bělský, Petr, Yoon, Jinhwan, and Dodda, Jagan Mohan

Subjects

*TRANSDERMAL medication, *WOUND healing, *ADHESIVES, *MEDICAL care, *MEDICAL technology, *HYDROGELS, *SKIN permeability, *DIGITAL technology

Abstract

With the advancement of medical and digital technologies, smart skin adhesive patches have emerged as a key player for complex medical purposes. In particular, skin adhesive patches with integrated electronics have created an excellent platform for monitoring health conditions and intelligent medication. However, the efficient design of the adhesive patches is still challenging as it requires a strong combination of network structure, adhesion, physical properties, and biocompatibility. To design an assimilated device, one must have a deep knowledge of various skin adhesive patches. This article provides a comprehensive review of the recent advances in skin‐adhesive patches, including hydrogel‐based adhesive patches, transdermal patches, and electronic skin (E‐skin) patches, for various biomedical applications such as wound healing, drug delivery, biosensing, and health monitoring. Furthermore, the key challenges, implementable strategies, and future designs that can potentially provide researchers in designing innovative multipurpose smart skin patches are discussed. These advanced approaches are promising for managing the health and fitness of patients who require regular medical care. [ABSTRACT FROM AUTHOR]

Published

2023

3. Organic Cathode Materials for Sodium‐Ion Batteries: From Fundamental Research to Potential Commercial Application.

Author

Zhang, Hang, Gao, Yun, Liu, Xiao‐Hao, Yang, Zhuo, He, Xiang‐Xi, Li, Li, Qiao, Yun, Chen, Wei‐Hua, Zeng, Rong‐Hua, Wang, Yong, and Chou, Shu‐Lei

Subjects

*SODIUM ions, *ELECTROACTIVE substances, *ELECTRODE performance, *REDUCTION potential, *STORAGE batteries, *ELECTRODES

Abstract

Organic electroactive compounds hold great potential to act as cathode material for organic sodium‐ion batteries (OSIBs) because of their environmental friendliness, sustainability, and high theoretical capacity. Although some organic electrodes have been developed with good performance, their practical application is still obstructed by some inherent drawbacks such as low conductivity and solubility in organic electrolytes. In addition, research on OSIBs has been mainly focused on the performance of electrodes on the material level and neglected the trade‐off relationship between the high redox potentials and specific capacities. Almost all organic cathodes used in OSIBs lack the ability to be charged first in half‐cells because of the absence of detachable sodium ions, resulting in low attractiveness when assembling full cells with hard carbon as anode. Here, this review presents several existing reaction mechanisms in OSIBs and designs of organic cathode materials. Furthermore, strategies are proposed in order to provide guidelines for improving their performance according to some critical parameters (output voltage, specific capacity, and cycle life) in potential practical OSIBs, and some accounts of organic materials assembled in full cells are summarized. Finally, the challenges and prospects of organic electrodes for OSIBs are also discussed in this review. [ABSTRACT FROM AUTHOR]

Published

2022

4. Recent Progress in Advanced Organic Electrode Materials for Sodium‐Ion Batteries: Synthesis, Mechanisms, Challenges and Perspectives.

Author

Yin, Xiuping, Sarkar, Samrat, Shi, Shanshan, Huang, Qiu‐An, Zhao, Hongbin, Yan, Liuming, Zhao, Yufeng, and Zhang, Jiujun

Subjects

*ELECTRIC batteries, *ELECTRODES, *ENERGY storage, *MOLECULAR structure, *LITHIUM-ion batteries

Abstract

Rechargeable sodium‐ion batteries (SIBs) are considered attractive alternatives to lithium‐ion batteries for next‐generation sustainable and large‐scale electrochemical energy storage. Organic sodium‐ion batteries (OSIBs) using environmentally benign organic materials as electrodes, which demonstrate high energy/power density and good structural designability, have recently attracted great attention. Nevertheless, the practical applications and popularization of OSIBs are generally restricted by the intrinsic disadvantages related to organic electrodes, such as their low conductivity, poor stability, and high solubility in electrolytes. Here, the latest research progress with regard to electrode materials of OSIBs, ranging from small molecules to organic polymers, is systematically reviewed, with the main focus on the molecular structure design/modification, the electrochemical behavior, and the corresponding charge‐storage mechanism. Particularly, the challenges faced by OSIBs and the effective design strategies are comprehensively summarized from three aspects: function‐oriented molecular design, micromorphology regulation, and construction of organic–inorganic composites. Finally, the perspectives and opportunities in the research of organic electrode materials are discussed. [ABSTRACT FROM AUTHOR]

Published

2020

5. Sodium‐Ion Batteries: Recent Progress in Advanced Organic Electrode Materials for Sodium‐Ion Batteries: Synthesis, Mechanisms, Challenges and Perspectives (Adv. Funct. Mater. 11/2020).

Author

Yin, Xiuping, Sarkar, Samrat, Shi, Shanshan, Huang, Qiu‐An, Zhao, Hongbin, Yan, Liuming, Zhao, Yufeng, and Zhang, Jiujun

Subjects

*ELECTRIC batteries, *ELECTRODES, *PROGRESS, *MATERIALS, *MOLECULAR structure

Abstract

Sodium-Ion Batteries: Recent Progress in Advanced Organic Electrode Materials for Sodium-Ion Batteries: Synthesis, Mechanisms, Challenges and Perspectives (Adv. Funct. Keywords: design strategy; electrode material; organic material; progress; sodium-ion battery Design strategy, electrode material, organic material, progress, sodium-ion battery. [Extracted from the article]

Published

2020

6. Cation-Anion Interaction-Directed Molecular Design Strategy for Mechanochromic Luminescence

Author

Shuaijun Yang, Feijie Song, Xingyan Liu, Jingbo Lan, Dan Xiao, Jingsong You, Gaocan Li, Di Wu, and Jie Wu

Subjects

Carbon chain, Mechanochromic luminescence, Materials science, Design elements and principles, Nanotechnology, Design strategy, Condensed Matter Physics, Electronic, Optical and Magnetic Materials, Ion, Biomaterials, chemistry.chemical_compound, chemistry, Electrochemistry, Molecular stacking, Pyridinium, Luminescence

Abstract

Mechanofluorochromic materials have great potential for a wide variety of applications such as sensors, memory devices, motion systems, security systems, and so forth. However, only few design principles have been disclosed, which greatly impedes the growth of mechanofluorochromic dyes. Here, a strategy of molecular design for mechanochromic luminescence is reported, based on the cation–anion interaction-directed switching of molecular stacking. On the basis of this strategy, a series of common N-heteroaromatic onium fluorophores such as imidazolium, 1,2,4-triazolium, triazolopyridinium, benzoimidazolium, γ-carbolinium, and pyridinium salts have been designed and proved to have striking reversible mechanofluorochromic behaviors. The simple attachment of a non-fluorescent imidazolium unit to the pyrene scaffold through a flexible carbon chain can even trigger the mechanofluorochromic phenomenon, which gives a consummate interpretation that the cation–anion interaction can be considered as an important general tool to design organic mechanochromic luminescent materials.

Published

2013