用于 3D 打印微型超级电容器和微型电池的二维 (2D) 材料

G. Saeed, T. Kang, Jin Suk Byun, D. Min, Jun Su Kim, S. Sadavar, H. Park
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引用次数: 0

摘要

二维(2D)材料显示出一系列独特的物理/化学特性,被认为是制造多种应用领域微结构材料的潜在基石。突出的应用领域包括从先进电子器件到微型电化学储能装置(EESD)。在此,我们对三维(3D)打印微型超级电容器和微型电池的二维驱动微型电极的设计和微细加工的最新进展进行了全面而深入的综述。首先,我们系统地讨论了立体光刻、熔融沉积建模、喷墨打印和直接墨水写入等各种微制造技术的优缺点。接下来,我们重点介绍了揭示二维材料特性与挤压驱动三维打印工艺之间关系的关键参数,以开发多功能、可持续的 EESD。详细讨论了用于构建超级电容器(如双电层电容器(EDLC)、伪电容器和混合电容器)和电池(如锂基系统和下一代系统,如钠离子电池和锌离子电池)微电极的二维材料及其与所获得的三维打印架构相关的突出电化学贡献。为了促进二维材料驱动的高性能微尺度 EESD 的发展,还讨论了相关的挑战和未来的研究机会。
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Two-dimensional (2D) materials for 3D printed micro-supercapacitors and micro-batteries
Two-dimensional (2D) materials display a unique set of physical/chemical properties and are considered potential building blocks for the manufacturing of microstructured materials for a number of applications. Prominent applications range from advanced electronics to miniaturized electrochemical energy storage devices (EESDs). Herein, we present a comprehensive and critical review of the recent developments in design and microfabrication of 2D-driven microscale electrodes for three-dimensional (3D)-printed micro-supercapacitors and micro-batteries. Firstly, we systematically discuss the advantages and disadvantages associated with various microfabrication techniques such as stereolithography, fused deposition modeling, inkjet printing, and direct ink writing. Next, key parameters disclosing the relationship between the characteristics of 2D-based materials and extrusion-driven 3D printing process for the development of versatile and sustainable EESDs are highlighted. 2D materials utilized for the construction of microelectrodes for supercapacitors (e.g., electric double layer capacitors (EDLCs), pseudocapacitors, and hybrid capacitors) and batteries (e.g., Li-based systems and next-generation systems, e.g., sodium-ion batteries and zinc-ion batteries) along with their prominent electrochemical contributions in relation to obtained 3D-printed architectures are discussed in detail. To promote the development of 2D materials-driven high-performance microscale EESDs, the relevant challenges and future research opportunities are also addressed.
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