受散射过程的物理边界启发的高度指导性系统

2019 IEEE International Conference on Microwaves, Antennas, Communications and Electronic Systems (COMCAS) Pub Date : 2019-11-01 DOI:10.1109/COMCAS44984.2019.8957857

Iñigo Libera

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引用次数: 0

摘要

确定性能的物理边界是理解光-物质相互作用和设计达到这些理论极限的最佳设备的核心。在这里，我们扩展了之前的工作，推导了时间谐波散射过程的物理性能界限，包括总散射、总吸收、双基地散射和最小散射传感器，用于存在材料界面的系统的任意远场照明。导出的上界强调了散射指向性的加权函数作为所有上述散射过程理论上可实现的性能的主要限制因素。因此，我们的分析指出了在多种配置中使用高度指导性系统的潜在好处。

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Highly-directive systems inspired by physical bounds on scattering processes

The identification of physical bounds of performance is central to the understanding of light-matter interactions and the design of optimal devices that reach those theoretical limits. Here, we extend our previous work to derive physical bounds of performance for time-harmonic scattering processes, including total scattering, total absorption, bistatic scattering and minimal scattering sensors, for arbitrary far-field illumination of a system in the presence of a material interface. The derived upper bounds emphasize a weighted function of the scattering directivity as the main limiting factor in the theoretically achievable performance for all aforementioned scattering processes. Therefore, our analysis remarks the potential benefits of using highly-directive systems in multiple configurations.

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2019 IEEE International Conference on Microwaves, Antennas, Communications and Electronic Systems (COMCAS)

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