用于一氧化碳检测的掺杂过渡金属的氮化硼：一种前景广阔的空气净化纳米传感器

IF 1.6 4区工程技术 Q3 INSTRUMENTS & INSTRUMENTATION Sensor Review Pub Date : 2024-03-25 DOI:10.1108/sr-01-2024-0066

Fatemeh Mollaamin, Majid Monajjemi

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引用次数: 0

摘要

目的本研究旨在探讨用过渡金属装饰的氮化硼纳米笼（BNNc）捕捉空气中有毒气体一氧化碳（CO）的潜力。设计/方法/途径在掺入钛（Ti）、钒（V）、铬（Cr）、钴（Co）、铜（Cu）和锌（Zn）原子的情况下，对氮化硼纳米笼进行了建模，这些原子可以提高氮化硼纳米笼的气体感应能力。本研究采用 CAM-B3LYP-D3/EPR-3 和 LANL2DZ 理论水平进行计算。研究结果核四极共振数据表明，原始 BNNc 上的 Cu 掺杂或 Co 掺杂具有较高的巴德电荷与电势之间的波动，可作为气体吸附过程中接受电子倾向最高的合适选择。此外，核磁共振波谱研究发现，在 CO 分子吸附过程中，（Ti、V、Cr、Co、Cu、Zn）-BNNc 上掺杂原子的电子接受率可按以下顺序排列：Cu>Co>>Cr>Zn˜V>Ti，这表明了 Ti、V、Cr、Co、Cu、Zn 和 CO 之间共价键的强度。事实上，一氧化碳气体分子的吸附会在（Ti、V、Cr、Co、Cu、Zn）-BNNc 上引入自旋极化，这表明这些表面可用作磁清除表面，作为气体检测器。根据红外光谱对吸附在（Ti、V、Cr、Co、Cu、Zn）-BNNc 上的 CO 分子的吸附的吉布斯自由能表明，对于 CO 中给定数量的碳供体位点，由于掺杂了 Ti、V、Cr、Co、Cu、Zn 原子而形成的复合物的稳定性可视为原创性/价值这项研究通过材料建模方法和用过渡金属装饰纳米材料，有望推出新型高效纳米传感器，应用于一氧化碳的选择性传感。

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Boron nitride doped with transition metals for carbon monoxide detection: a promising nanosensor for air cleaning

Purpose

This study aims to investigate the potential of the decorated boron nitride nanocage (BNNc) with transition metals for capturing carbon monoxide (CO) as a toxic gas in the air.

Design/methodology/approach

BNNc was modeled in the presence of doping atoms of titanium (Ti), vanadium (V), chromium (Cr), cobalt (Co), copper (Cu) and zinc (Zn) which can increase the gas sensing ability of BNNc. In this research, the calculations have been accomplished by CAM–B3LYP–D3/EPR–3, LANL2DZ level of theory. The trapping of CO molecules by (Ti, V, Cr, Co, Cu, Zn)–BNNc has been successfully incorporated because of binding formation consisting of C → Ti, C → V, C → Cr, C → Co, C → Cu, C → Zn.

Findings

Nuclear quadrupole resonance data has indicated that Cu-doped or Co-doped on pristine BNNc has high fluctuations between Bader charge versus electric potential, which can be appropriate options with the highest tendency for electron accepting in the gas adsorption process. Furthermore, nuclear magnetic resonance spectroscopy has explored that the yield of electron accepting for doping atoms on the (Ti, V, Cr, Co, Cu, Zn)–BNNc in CO molecules adsorption can be ordered as follows: Cu > Co >> Cr > Zn ˜ V> Ti that exhibits the strength of the covalent bond between Ti, V, Cr, Co, Cu, Zn and CO. In fact, the adsorption of CO gas molecules can introduce spin polarization on the (Ti, V, Cr, Co, Cu, Zn)–BNNc which specifies that these surfaces may be used as magnetic-scavenging surface as a gas detector. Gibbs free energy based on IR spectroscopy for adsorption of CO molecules adsorption on the (Ti, V, Cr, Co, Cu, Zn)–BNNc have exhibited that for a given number of carbon donor sites in CO, the stabilities of complexes owing to doping atoms of Ti, V, Cr, Co, Cu, Zn can be considered as: CO →Cu–BNNc >> CO → Co–BNNc > CO → Cr–BNNc > CO → V–BNNc > CO → Zn–BNNc > CO → Ti–BNNc.

Originality/value

This study by using materials modeling approaches and decorating of nanomaterials with transition metals is supposed to introduce new efficient nanosensors in applications for selective sensing of carbon monoxide.

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来源期刊

Sensor Review 工程技术-仪器仪表

CiteScore

3.40

自引率

6.20%

发文量

审稿时长

3.7 months

期刊介绍： Sensor Review publishes peer reviewed state-of-the-art articles and specially commissioned technology reviews. Each issue of this multidisciplinary journal includes high quality original content covering all aspects of sensors and their applications, and reflecting the most interesting and strategically important research and development activities from around the world. Because of this, readers can stay at the very forefront of high technology sensor developments. Emphasis is placed on detailed independent regular and review articles identifying the full range of sensors currently available for specific applications, as well as highlighting those areas of technology showing great potential for the future. The journal encourages authors to consider the practical and social implications of their articles. All articles undergo a rigorous double-blind peer review process which involves an initial assessment of suitability of an article for the journal followed by sending it to, at least two reviewers in the field if deemed suitable. Sensor Review’s coverage includes, but is not restricted to: Mechanical sensors – position, displacement, proximity, velocity, acceleration, vibration, force, torque, pressure, and flow sensors Electric and magnetic sensors – resistance, inductive, capacitive, piezoelectric, eddy-current, electromagnetic, photoelectric, and thermoelectric sensors Temperature sensors, infrared sensors, humidity sensors Optical, electro-optical and fibre-optic sensors and systems, photonic sensors Biosensors, wearable and implantable sensors and systems, immunosensors Gas and chemical sensors and systems, polymer sensors Acoustic and ultrasonic sensors Haptic sensors and devices Smart and intelligent sensors and systems Nanosensors, NEMS, MEMS, and BioMEMS Quantum sensors Sensor systems: sensor data fusion, signals, processing and interfacing, signal conditioning.