纳米多孔4H-SiC骨架上的三维石墨烯：一种用于食品传感应用的新型材料。

IF 3.3 2区农林科学 Q1 AGRICULTURE, MULTIDISCIPLINARY

Journal of the Science of Food and Agriculture Pub Date : 2025-02-01 Epub Date: 2023-11-27 DOI:10.1002/jsfa.13118

Stefano Veronesi, Ylea Vlamidis, Letizia Ferbel, Carmela Marinelli, Chiara Sanmartin, Isabella Taglieri, Georg Pfusterschmied, Markus Leitgeb, Ulrich Schmid, Fabio Mencarelli, Stefan Heun

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引用次数: 0

摘要

背景：传感器对挥发性有机化合物敏感，因此能够监测食物的保存状态，这是非常珍贵的，因为它们的工作原理是无损的，可以避免与食物直接接触，确保卫生条件。特别是，酸败的监测将解决食品储存中普遍存在的问题。结果：本文讨论的传感器是利用石墨烯的新型三维排列来生产的，石墨烯生长在先前通过化学蚀刻多孔化的晶体碳化硅（SiC）晶片上。这种方法允许非常高的表面体积比。此外，传感器表面的结构具有大量的边缘、悬空边界和活性位点，这使得传感器在化学坚固的骨架上具有化学活性，特别是对氢化分子具有化学活性。通过测量四线配置中的传感器电阻来读取传感器与这些化合物的相互作用。传感器性能已经在三个榛子样本上进行了评估：声音榛子、变质榛子和蝽榛子。电阻变化约∆R= 0.13± 已检测到声音和受损榛子之间的0.02Ω。结论：我们的测量结果证实了传感器区分声音和受损榛子的能力。传感器信号稳定数天，为使用该传感器监测脂肪和食品的储存状态提供了可能。这篇文章受版权保护。保留所有权利。

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Three-dimensional graphene on a nano-porous 4H-silicon carbide backbone: a novel material for food sensing applications.

Background: Sensors that are sensitive to volatile organic compounds, and thus able to monitor the conservation state of food, are precious because they work non-destructively and allow avoiding direct contact with the food, ensuring hygienic conditions. In particular, the monitoring of rancidity would solve a widespread issue in food storage.

Results: The sensor discussed here is produced utilizing a novel three-dimensional arrangement of graphene, which is grown on a crystalline silicon carbide wafer previously porousified by chemical etching. This approach allows a very high surface-to-volume ratio. Furthermore, the structure of the sensor surface features a large number of edges, dangling bounds, and active sites, which make the sensor, on a chemically robust skeleton, chemically active, particularly to hydrogenated molecules. The interaction of the sensor with such compounds is read out by measuring the sensor resistance in a four-wire configuration. The sensor performance has been assessed on three hazelnut samples: sound, spoiled, and stink bug hazelnuts. A resistance variation of about ∆R = 0.13 ± 0.02 Ω between sound and damaged hazelnuts has been detected.

Conclusions: Our measurements confirm the ability of the sensor to discriminate between sound and damaged hazelnuts. The sensor signal is stable for days, providing the possibility to use this sensor for the monitoring of the storage state of fats and foods in general. © 2023 Society of Chemical Industry.

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来源期刊

Journal of the Science of Food and Agriculture 工程技术-农业综合

CiteScore

8.10

自引率

4.90%

发文量

634

审稿时长

3.1 months

期刊介绍： The Journal of the Science of Food and Agriculture publishes peer-reviewed original research, reviews, mini-reviews, perspectives and spotlights in these areas, with particular emphasis on interdisciplinary studies at the agriculture/ food interface. Published for SCI by John Wiley & Sons Ltd. SCI (Society of Chemical Industry) is a unique international forum where science meets business on independent, impartial ground. Anyone can join and current Members include consumers, business people, environmentalists, industrialists, farmers, and researchers. The Society offers a chance to share information between sectors as diverse as food and agriculture, pharmaceuticals, biotechnology, materials, chemicals, environmental science and safety. As well as organising educational events, SCI awards a number of prestigious honours and scholarships each year, publishes peer-reviewed journals, and provides Members with news from their sectors in the respected magazine, Chemistry & Industry . Originally established in London in 1881 and in New York in 1894, SCI is a registered charity with Members in over 70 countries.