Enhanced detection of aromatic oxidation products using NO3 - chemical ionization mass spectrometry with limited nitric acid.

IF 2.8 Q3 ENVIRONMENTAL SCIENCES
Olga Garmash, Avinash Kumar, Sakshi Jha, Shawon Barua, Noora Hyttinen, Siddharth Iyer, Matti Rissanen
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Abstract

Nitrate ion-based chemical ionization mass spectrometry (NO3 --CIMS) is widely used for detection of highly oxygenated organic molecules (HOMs). HOMs are known to participate in molecular clustering and new particle formation and growth, and hence understanding the formation pathways and amounts of these compounds in the atmosphere is essential. However, the absence of analytical standards prevents robust quantification of HOM concentrations. In addition, nitrate-based ionization is usually very selective towards the most oxygenated molecules and blind to less oxygenated compounds hindering the investigation of molecular formation pathways. Here, we explore varying concentrations of nitric acid reagent gas in the sheath flow of a chemical ionization inlet as a method for detecting a wider range of oxidation products in laboratory-simulated oxidation of benzene and naphthalene. When the concentration of reagent nitric acid is reduced, we observe an increase in signals of many oxidation products for both precursors suggesting that they are not detected at the collision limit. The sensitivity of naphthalene oxidation products is enhanced to a larger extent than that of benzene products. This enhancement in sensitivity has a negative relationship with molecular oxygen content, the oxygen-to-carbon ratio, the oxidation state of carbon, and lowered volatility. In addition, the sensitivity enhancement is lower for species that contain more exchangeable H-atoms, particularly for accretion products. While more experimental investigations are needed for providing the relationship between enhancement ratios and instrumental sensitivities, we suggest this method as a tool for routine check of collision-limited sensitivities and enhanced detection of lower-oxygenated species.

利用 NO3 - 有限硝酸化学电离质谱法增强对芳香族氧化产物的检测。
基于硝酸根离子的化学电离质谱(NO3-CIMS)被广泛用于检测高含氧有机分子(HOMs)。众所周知,高含氧有机分子参与分子聚类和新粒子的形成与生长,因此了解这些化合物在大气中的形成途径和数量至关重要。然而,由于缺乏分析标准,无法对 HOM 的浓度进行可靠的量化。此外,基于硝酸盐的电离通常对含氧量最高的分子具有很强的选择性,而对含氧量较低的化合物则视而不见,这阻碍了对分子形成途径的研究。在此,我们探讨了在化学电离进气口的鞘流中加入不同浓度的硝酸试剂气体的方法,以便在实验室模拟苯和萘的氧化过程中检测更广泛的氧化产物。当试剂硝酸的浓度降低时,我们观察到这两种前体的许多氧化产物的信号增加,这表明它们在碰撞极限时没有被检测到。萘氧化产物的灵敏度比苯产物的灵敏度更高。灵敏度的提高与分子氧含量、氧碳比、碳的氧化态和挥发性降低呈负相关。此外,对于含有更多可交换 H 原子的物种,尤其是增殖产物,灵敏度的提高幅度较低。虽然还需要更多的实验研究来提供增强比和仪器灵敏度之间的关系,但我们建议将此方法作为常规检查碰撞限制灵敏度和增强低氧物种检测的工具。
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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CiteScore
2.90
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0.00%
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