2026-03-17 ペンシルベニア州立大学(Penn State)
The team fit sensors built with their new field-effect transistor design onto integrated circuit boards, like the one pictured here, in order to test sensing accuracy and sensitivity. They found that their approach facilitates sensors that are not only responsive, but highly resistant to the signal drift issues that had faced previous designs. Credit: Jaydyn Isiminger / Penn State. Creative Commons
<関連情報>
- https://www.psu.edu/news/research/story/novel-sensing-technology-20-times-more-responsive-even-liquids
- https://www.nature.com/articles/s41699-026-00674-5
低ノイズ、ドリフト安定、および調整可能な化学センシングのためのアクティブデュアルゲートグラフェントランジスタ Active dual-gated graphene transistors for low-noise, drift-stable, and tunable chemical sensing
Vinay Kammarchedu,Heshmat Asgharian,Hossein Chenani & Aida Ebrahimi
npj 2D Materials and Applications Published:13 February 2026
DOI:https://doi.org/10.1038/s41699-026-00674-5 Unedited version
Abstract
Graphene field-effect transistors (GFETs) are among the most promising platforms for ultrasensitive chemical and biological sensing due to their high carrier mobility, large surface area, and low intrinsic noise. However, conventional single-gate GFETs in liquid environments suffer from severe limitations, including signal drift, charge trapping, and insufficient signal amplification. Here, we introduce a dual-gate GFET architecture that integrates a high-κ hafnium dioxide local back gate with an electrolyte top gate, coupled with real-time feedback biasing. This design enables capacitive signal amplification while simultaneously suppressing gate leakage and low-frequency noise. By systematically evaluating seven distinct operational modes, we identify the Differential Mode Fixed configuration as optimal, achieving up to 20× signal gain, >15× lower drift compared with gate-swept methods, and up to 7× higher signal-to-noise ratio across a diverse range of analytes, including neurotransmitters, volatile organic compounds, environmental contaminants, and proteins. We further demonstrate robust multichannel detection using a PCB-integrated GFET sensor array, underscoring the scalability and practicality of the platform for portable, high-throughput sensing. Together, these advances establish a versatile and stable sensing technology capable of real-time, label-free detection of molecular targets under ambient and physiological conditions, with broad applicability in health monitoring, food safety, agriculture, and environmental screening.
