King Melissa E, Fonseca Guzman Maria V, Ross Michael B
Department of Chemistry, University of Massachusetts, Lowell, Lowell, MA 01854, USA.
Nanoscale. 2022 Jan 20;14(3):602-611. doi: 10.1039/d1nr06049j.
Plasmonic materials are promising for applications in enhanced sensing, energy, and advanced optical communications. These applications, however, often require chemical and physical functionality that is suited and designed for the specific application. In particular, plasmonic materials need to access the wide spectral range from the ultraviolet to the mid-infrared in addition to having the requisite surface characteristics, temperature dependence, or structural features that are not intrinsic to or easily accessed by the noble metals. Herein, we describe current progress and identify promising strategies for further expanding the capabilities of plasmonic materials both across the electromagnetic spectrum and in functional areas that can enable new technology and opportunities.
等离子体材料在增强传感、能源及先进光通信等应用领域具有广阔前景。然而,这些应用通常需要适合特定应用并经过专门设计的化学和物理功能。特别是,等离子体材料除了具备必要的表面特性、温度依赖性或结构特征(这些并非贵金属所固有或易于获得)外,还需要覆盖从紫外到中红外的宽光谱范围。在此,我们描述了当前的进展,并确定了一些有前景的策略,以进一步拓展等离子体材料在整个电磁光谱以及能催生新技术和新机遇的功能领域的能力。
