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Displacement Sensor with Inherent Read-Out Circuit Using Water-Gated Field Effect Transistor (WG-FET)

机译：具有固有读出电路的位移传感器，采用采用水门效应效应晶体管（WG-FET）

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摘要

This paper presents, for the first time, a displacement sensor with inherent read-out circuit using an inverter built with WG-FET that has 16-nm-thick single crystalline silicon film. In WG-FET, electrical double layer (EDL) capacitances are formed at water/silicon and water/top gate interfaces. These two capacitances and the resistance of the de-ionized (DI) water droplet build a first order RC network. Propagation delay of an inverter built with WG-FET depends on this RC constant. When the distance between top gate and silicon film changes, EDL capacitances remain the same, but resistance of the DI-water droplet changes. Accordingly, propagation delay of the inverter changes linearly with this distance. Increasing the distance from 400 µm to 1200 µm changes low-to-high propagation delay tplh of the inverter from 1.08 ms to 1.36 ms and high-to-low propagation delay tphl from 0.48 ms to 0.56 ms, which yields sensitivities of 0.35 µs/µm and 0.1 µs/µm, respectively.

机译：本文首次呈现出具有固有读出电路的位移传感器，使用具有具有16-Nm厚的单晶硅膜的WG-FET构建的逆变器。在WG-FET中，在水/硅和水/顶部栅极接口处形成电双层（EDL）电容。这两个电容和去离子（DI）水滴的电阻构建了一阶RC网络。用WG-FET构建的逆变器的传播延迟取决于该RC常数。当顶部栅极和硅膜之间的距离变化时，EDL电容保持不变，但DI水滴的电阻变化。因此，逆变器的传播延迟随该距离线性地改变。将400μm至1200μm的距离增加变化逆变器的低高到高传播延迟TPLH从1.08 ms到1.36ms，高到低传播延迟TPH1，从0.48 ms到0.56ms，产生0.35μs/的敏感性/ μm和0.1μs/μm。

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Ozan Ertop; Bedri Gurkan Sonmez; Senol Mutlu;
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年度 2018
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正文语种 eng
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专利

1. Displacement Sensor with Inherent Read-Out Circuit Using Water-Gated Field Effect Transistor (WG-FET) [J] . Ozan Ertop, Bedri Gurkan Sonmez, Senol Mutlu Proceedings . 2018,第13期

机译：带水闸场效应晶体管（WG-FET）的具有固有读出电路的位移传感器
2. Realization and AC modeling of electronic circuits with water-gated field effect transistors (WG-FETs) based on gate probe distance [J] . Sonmez Bedri Gurkan, Ertop Ozan, Mutlu Senol Journal of Micromechanics and Microengineering . 2018,第11期

机译：基于闸门探头距离的浇筑场效应晶体管（WG-FET）实现与交流建模
3. Investigation of the Salt Concentration Dependence of Water-Gated Field Effect Transistors (WG-FET) Using 16-nm-Thick Single Crystalline Si Film [J] . Ertop Ozan, Sonmez Bedri Gurkan, Mutlu Senol Proceedings . 2017,第4期

机译：使用16nm厚单晶硅膜的水控场效应晶体管（WG-FET）的盐浓度依赖性研究
4. Improved Gain and Bandwidth of Water-Gated Field Effect Transistor (WG-FET) Circuits Using Solutions with Higher Ion Concentration [C] . Ozan Ertop, Bahadir Donmez, Senol Mutlu 2019 20th International Conference on Solid-State Sensors, Actuators and Microsystems amp; Eurosensors XXXIII . 2019

机译：使用更高离子浓度的解决方案改善了水控场效应晶体管（WG-FET）电路的增益和带宽
5. A Low-cost Planar Inkjet-printed Carbon Nanotube Field Effect Transistor for Sensor and Circuit Applications [D] . Islam, Md Toriqul. 2019

机译：用于传感器和电路应用的低成本平面喷墨印刷碳纳米管场效应晶体管
6. Modelling and Realization of a Water-Gated Field Effect Transistor (WG-FET) Using 16-nm-Thick Mono-Si Film [O] . Bedri Gurkan Sonmez, Ozan Ertop, Senol Mutlu -1

机译：使用16nm厚的单晶硅膜的水控场效应晶体管（WG-FET）的建模和实现
7. Water-Gated n‑Type Organic Field-Effect Transistors for Complementary Integrated Circuits Operating in an Aqueous Environment [O] . Rossella Porrazzo, Alessandro Luzio, Sebastiano Bellani, 2017

机译：用于在水环境中工作的互补集成电路的水门式n型有机场效应晶体管

Displacement Sensor with Inherent Read-Out Circuit Using Water-Gated Field Effect Transistor (WG-FET)

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