Broadside-Coupled Split Ring Resonators as a Model Construct for Passive Wireless Sensing

Passive and wireless Radio-Frequency (RF) sensors are a unique, enabling modality for emerging applications in environmental sensing. These sensors exhibit several key features that may unlock new functionalities in complex environments: sensors are composed of zero electronic components, are wirelessly interrogated even in opaque media, and structures are often inherently biocompatible. Such capabilities make it unique in the realm of sensing architectures. Here, the broadside-coupled, split-ring resonator is studied as a compact and versatile model structure for RF sensing (of potentially mechanical and biochemical environments). A new analytical model is derived to assess resonator behavior-these yield a rapid, first-order approximation of the resonator resonant frequency or sensitivity. Finally, experimental investigations into how sensors may be optimally designed, sized, and interrogated to enhance sensitivity or spectral intensity are performed. These studies encompass a wide variety of potential dimensional and dielectric modifications that may be relevant to emerging sensors. Last, hydrogel polymeric sensors are synthesized and studied to assess how practical sensors may deviate in response from expectations. Such investigations lay the groundwork for how such sensing architectures may be adapted to fit application needs. Broadside-coupled, split-ring resonators are investigated as versatile and compact model structures for RF sensing. A new analytical model is derived to assess resonator behavior, alongside experimental investigations into how sensors may be optimally designed, sized, and interrogated to enhance sensitivity or spectral intensity. These studies encompass a variety of dimensional and dielectric properties relevant to emerging sensors. image