Microwave Diamond-based HBAR as Ultrathin Film Sensor. Pt Deposition

2020 Joint Conference of the IEEE International Frequency Control Symposium and International Symposium on Applications of Ferroelectrics (IFCS-ISAF) Pub Date : 2020-07-01 DOI:10.1109/IFCS-ISAF41089.2020.9234835

B. Sorokin, G. Kvashnin, N. Asafiev, K. Kravchuk, N. Luparev, A. Sotnikov

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引用次数: 1

Abstract

Sensory properties of diamond-based HBAR were investigated by means of the Al, Sc, Mo and Pt thin and ultrathin film deposition. First the operational frequency ∼20 GHz of a sensor having a comparatively high $Q$ factor was applied with an aim decreasing the relative measurement error and increasing the sensitivity. Sensitivity on Pt film deposition was estimated as 0.5 nm. Dependences of the overtone's frequency shift vs. film thickness could be differed from the linearly proportional ones. Such peculiarities were explained in terms of an acoustic impedance difference between the films and diamond substrate. Experimental results were in close accordance with FEM model data. Prototypes of sensory elements developed have the important advantages over all other types of acoustoelectronic sensors owing to operating the SHF band up to 20 GHz, high chemical and biological inertness of the working diamond surface, resistance to the temperature load, abrasive wear resistance, and the possibility of a multiple-time application. Investigated diamond-based 5th layered piezoelectric structure should be considered as a prospective platform creating a number of new generation sensors.

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微波金刚石基HBAR超薄膜传感器。Pt沉积

采用Al、Sc、Mo、Pt薄膜和超薄膜沉积的方法研究了金刚石基HBAR的感官性能。首先，应用具有较高Q因子的传感器的工作频率~ 20 GHz，目的是减少相对测量误差并提高灵敏度。Pt薄膜沉积的灵敏度估计为0.5 nm。泛音的频移与薄膜厚度的关系可以不同于线性比例的关系。这种特性可以用薄膜和金刚石衬底之间的声阻抗差异来解释。实验结果与有限元模型数据吻合较好。与所有其他类型的声电子传感器相比，所开发的传感元件原型具有重要的优势，因为其工作频率高达20 GHz，工作金刚石表面的化学和生物惰性高，耐温度负载，耐磨料磨损，以及多次应用的可能性。所研究的金刚石基第5层压电结构可以被认为是创建许多新一代传感器的有前途的平台。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2020 Joint Conference of the IEEE International Frequency Control Symposium and International Symposium on Applications of Ferroelectrics (IFCS-ISAF)

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