Organic cocrystals: From high‐performance molecular materials to multi‐functional applications

Aggregate Pub Date : 2024-07-02 DOI:10.1002/agt2.626
Yuqing Ding, Yan Zhao, Yunqi Liu
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Abstract

Advancements in organic electronics are propelling the development of new material systems, where organic materials stand out for their unique benefits, including tunability and cost‐effectiveness. Organic single crystals stand out for their ordered structure and reduced defects, enhancing the understanding of the relationship between structure and performance. Organic cocrystal engineering builds upon these foundations, exploring intermolecular interactions within multicomponent‐ordered crystalline materials to combine the inherent advantages of single‐component crystals. However, the path to realizing the full potential of organic cocrystals is fraught with challenges, including structural mismatches, unclear cocrystallization mechanisms, and unpredictable property alterations, which complicate the effective cocrystallization between different molecules. To deepen the understanding of this promising area, this review introduces the mechanism of organic cocrystal formation, the various stacking modes, and different growth techniques, and highlights the advancements in cocrystal engineering for multifunctional applications. The goal is to provide comprehensive guidelines for the cocrystal engineering of high‐performance molecular materials, thereby expanding the applications of organic cocrystals in the fields of optoelectronics, photothermal energy, and energy storage and conversion.

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有机共晶体:从高性能分子材料到多功能应用
有机电子技术的进步推动了新型材料系统的发展,其中有机材料因其独特的优势而脱颖而出,包括可调性和成本效益。有机单晶因其有序的结构和较少的缺陷而脱颖而出,加深了人们对结构与性能之间关系的理解。有机共晶工程建立在这些基础之上,探索多组分有序晶体材料中的分子间相互作用,从而将单组分晶体的固有优势结合起来。然而,实现有机共晶全部潜力的道路充满挑战,包括结构不匹配、共晶机制不明确以及不可预测的性质改变,这些都使不同分子间的有效共晶变得复杂。为了加深对这一前景广阔的领域的理解,本综述介绍了有机共晶体的形成机理、各种堆积模式和不同的生长技术,并重点介绍了用于多功能应用的共晶体工程的进展。目的是为高性能分子材料的共晶工程提供全面的指导,从而拓展有机共晶在光电、光热、能量存储和转换等领域的应用。
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