From Single Nanowires to Smart Systems: Different Ways to Assess Food Quality

Chemistry Proceedings Pub Date : 2021-07-05 DOI:10.3390/csac2021-10605

M. Tonezzer, F. Biasioli, F. Gasperi

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Abstract

Recently, low-dimensional (1D, 2D) nanostructured materials have been attracting more and more interest as building blocks for innovative systems. Metal oxide nanowires are one of the most widely used materials for solid-state gas sensors, as they are simple to make, inexpensive, and sensitive to a wide range of gases and volatiles. Unfortunately, their broad sensitivity has a price to pay, which is very low selectivity. Fortunately, this flaw is not a problem for all applications. Where the boundary conditions are defined and “simple” (only the presence of a target gas is expected, without any interfering gases), a single traditional chemiresistor may be the best choice, while in cases where the variables are many, it is better to use an intelligent system. In this paper, we will show a resistive sensor based on a single SnO2 nanowire which, working at three temperatures (200, 250, and 300 °C), is able to detect tens of ppb of ammonia (30 ppb at 300 °C). The limit of detection (LoD) was calculated as 3 N/S, where N is the standard deviation of the sensor signal in air and S is the sensor sensitivity. We will show that the performance of this nanosensor is excellent and can be used in various applications, including agri-food quality monitoring. We will demonstrate that the SnO2 nanowire in a thermal gradient can act as a nano-electronic nose thanks to machine learning algorithms. The single nanowire-based sensor can estimate the total viable count with an error of 2.32% on mackerel fish samples stored at room temperature (25 °C) and in a fridge (4 °C). The integration of such a small (less than one square mm) and cheap device into the food supply chain would greatly reduce waste and the frequency of food poisoning.

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从单纳米线到智能系统:评估食品质量的不同方法

近年来，低维(一维、二维)纳米结构材料作为创新系统的构建模块越来越引起人们的兴趣。金属氧化物纳米线是固态气体传感器中应用最广泛的材料之一，因为它们制作简单，价格低廉，对各种气体和挥发物都很敏感。不幸的是，它们的广泛敏感性需要付出代价，那就是非常低的选择性。幸运的是，这个缺陷不是所有应用程序都存在的问题。在边界条件明确且“简单”(只期望目标气体存在，没有任何干扰气体)的情况下，单个传统化学电阻器可能是最佳选择，而在变量很多的情况下，最好使用智能系统。在本文中，我们将展示一种基于单根SnO2纳米线的电阻传感器，该传感器在三种温度(200,250和300°C)下工作，能够检测数十ppb的氨(300°C时为30 ppb)。检测限(LoD)计算为3 N/S，其中N为传感器信号在空气中的标准差，S为传感器灵敏度。我们将证明这种纳米传感器的性能优异，可以用于各种应用，包括农业食品质量监测。我们将证明，由于机器学习算法，在热梯度下的SnO2纳米线可以作为纳米电子鼻。单纳米线传感器可以在室温(25°C)和冰箱(4°C)下估计鲭鱼的总活菌数，误差为2.32%。将这样一个小(不到一平方毫米)的廉价设备整合到食品供应链中，将大大减少浪费和食物中毒的频率。

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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Chemistry Proceedings

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