Narrow Results

The proposed study presents an electromagnetic (EM) energy harvesting and density sensor application based on a perfect metamaterial absorber (MA) in microwave frequency regime. In order to verify the absorption behavior of the structure, its absorption behavior is experimentally tested along with the energy harvesting and sensing abilities. The absorption value is experimentally found 0.9 at the resonance frequency of 4.75 GHz. In order to harvest the EM energy, chips resistors are used. In addition, the suggested model is analyzed for its dependency on polarization angles. The results show that the perfect MA can be easily and efficiently used for EM energy harvesting applications. Moreover, as an additional feature of the model, we also realized a density sensor application. It can be seen that this structure can be used as a multi-functional device and configured for many other sensing applications.

We have designed and developed a metamaterial (MTM)-based multipurpose sensor structure capable of sensing moisture, liquid (ethyl alcohol-ethanol-in our case) density in pure water and the concrete aging. The structure is composed of a rectangular shape MTM cell resonator which can be adjusted to any desired frequency range depending on the application area and the material to be sensed. The material is put into a plastic rectangular pipe placed in a hole located in the middle of the structure. Depending on the response of the proposed model to the electromagnetic properties of the material under test (MUT), overall resonance frequency shifts providing the information to accurately estimate the soil moisture, concrete age and density rate of the sensed liquid samples in real time. The resonance frequency has been carefully chosen so that the MUT has a linear variation in its electromagnetic response behaviors. It is aimed for future studies to adjust the structure for designing a portable multipurpose sensor device and even adjust it to smart phones and sense the materials by simply using smart phones and a small amount of sample in high efficiency.