Rationally designed graphene channels for real‐time sodium ion detection for electronic tongue

Lee, Chung Won; Jun, Sang Eon; Kim, Seung Ju; Lee, Tae Hyung; Lee, Sol A; Jin, Can; Cho, Jin Hyuk; Choi, Shinyoung; Kim, Cheol‐Joo; Kim, Soo Young; Jang, Ho Won

doi:10.1002/inf2.12427

Cited by 11 publications

(2 citation statements)

References 70 publications

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“…From this perspective, carbon-based materials such as carbon nanotube (CNTs), graphene (Gr), and reduced graphene oxide (rGO) have been suggested as another candidate for chemoresistors owing to their flexibility, low operating temperature (RT–100 °C), and high chemical tunability. 22–27 Furthermore, TMDs such as MoS 2 , WS 2 , SnS 2 , and MoSe 2 have received significant attention as sensing materials for detection of NH 3 , H 2 S, and NO 2 . 28–31 Their 2D structures with high specific surface areas and abundant active edge sites enhance the adsorption of gas molecules, resulting in sensitive sensing performance.…”

Section: Chemoresistive Gas Sensors: Overviewmentioning

confidence: 99%

Food quality assessment using chemoresistive gas sensors: achievements and future perspectives

Park,

Lee,

et al. 2024

Sustainable Food Technol.

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Section: Chemoresistive Gas Sensors: Overviewmentioning

confidence: 99%

Food quality assessment using chemoresistive gas sensors: achievements and future perspectives

Park,

Lee,

et al. 2024

Sustainable Food Technol.

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“…Diverging from other existing FTJ, the noteworthy TER in this FTJ stemmed from a large change in the average barrier height (ABH), a consequence of the considerable Fermi level shift of graphene spontaneously induced by the polarization field of the CIPS. In contrast to metals or heavily doped semiconductors, monolayer graphene has a low quantum capacitance near the Dirac point [268], facilitating efficient tuning of the contact barrier height. In the ON state, the induced charge towards the graphene resulted in its relatively n-type doping, shifting the Fermi level above the Dirac point and leading to a reduced ABH.…”

Section: Non-volatile Memory Devicesmentioning

confidence: 99%

Ferroelectric tunnel junctions: promise, achievements and challenges

Park,

Lee,

Park

et al. 2024

J. Phys. D: Appl. Phys.

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Ferroelectric tunnel junctions (FTJs) have been the subject of ongoing research interest due to its fast operation based on the spontaneous polarization direction of ultrathin ferroelectrics and its simple two-terminal structure. Due to the advantages of FTJs, such as non-destructive readout, fast operation speed, low energy consumption, and high-density integration, they have recently been considered a promising candidate for non-volatile next-generation memory. These characteristics are essential to meet the increasing demand for high-performance memory in modern computing systems. In this review, we explore the basic principles and structures of FTJs and clarify the elements necessary for the successful fabrication and operation of FTJs. Then, we focus on the recent progress in perovskite oxide, fluorite, 2-dimensional van der Waals, and polymer-based FTJs and discuss ferroelectric materials expected to be available for FTJs use in the future. We highlight various functional device applications, including non-volatile memories, crossbar arrays, and synapses, utilizing the advantageous properties of ferroelectrics. Lastly, we address the challenges that FTJ devices currently face and propose a direction for moving forward.

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A Flexible Aptameric Graphene Field‐Effect Nanosensor Capable of Automatic Liquid Collection/Filtering for Cytokine Storm Biomarker Monitoring in Undiluted Sweat

Huang,

Li,

Liu

et al. 2023

Adv Funct Materials

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A wearable sensor capable of directly detecting cytokines in external secretions external to the human body is pivotal for gauging the intensity of the immune response and circumventing inflammatory storms, a significant clinical concern. The detection of low‐concentration cytokines is often hampered due to interference from impurities in secretions. Addressing this challenge, a wearable detection system is developed by integrating a Janus membrane with water auto‐collection/filtering capabilities, and aptamer‐modified graphene field‐effect transistor sensors, enabling the detection of low‐concentration cytokines in undiluted sweat samples. The Janus membrane can automatically filter external secretions and transport them to the sensor surface, effectively eliminating impurity interference and enhancing the sensor's detection capabilities. The device can sensitively detect cytokines (such as TNF‐α, a marker for inflammation and cancer) in undiluted sweat, with a detection range spanning 0.5 to 500 pM, and a detection limit reaching 0.31 pM. The ultra‐flexibility of the sensor is also verified, maintaining stable electrical properties even after enduring up to 50 extreme deformations. These findings indicate that the wearable detection system has the potential to realize low‐concentration cytokines monitoring in the sweat of inflammatory patients, to assist the healthcare system in controlling the body's immune status.

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Rationally designed graphene channels for real‐time sodium ion detection for electronic tongue

Cited by 11 publications

References 70 publications

Food quality assessment using chemoresistive gas sensors: achievements and future perspectives

Food quality assessment using chemoresistive gas sensors: achievements and future perspectives

Ferroelectric tunnel junctions: promise, achievements and challenges

A Flexible Aptameric Graphene Field‐Effect Nanosensor Capable of Automatic Liquid Collection/Filtering for Cytokine Storm Biomarker Monitoring in Undiluted Sweat

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