传递函数和传输测量的佩雷斯差分迁移率分析仪（DMA）在适度鞘流率

IF 3.9 3区环境科学与生态学 Q2 ENGINEERING, CHEMICAL

Journal of Aerosol Science Pub Date : 2025-01-17 DOI:10.1016/j.jaerosci.2025.106534

Yiliang Liu , Michel Attoui , Sebastian Holm , Arttu Yli-Kujala , Runlong Cai , Yang Chen , Juha Kangasluoma

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引用次数: 0

摘要

新开发的佩雷斯差分迁移率分析仪（DMA）为病毒颗粒和类似大小的颗粒提供高尺寸分辨率。在本研究中，我们测量了它在中等护套流速（从20到100 L min - 1）下的传递函数和传输，以扩展其在更大尺寸颗粒测量中的应用。两个DMA - Perez Fat DMA和Perez Thin DMA，首先使用四庚基溴化铵单体（THA +）在鞘层流速范围为100到400 L min - 1下进行校准。随后，构建了串联Perez DMA装置。以前的DMA在高护套/气溶胶流速比下操作，以高分辨率对尺寸在10至30 nm之间的金属颗粒进行分类。后一种直接子宫内膜切除术是在中等鞘流量下进行的，范围从20到100 L min毒血症1。假设由前一种DMA分类的颗粒是单分散的，并用于校准后一种DMA。实测的10 nm粒子传递函数仅比理论传递函数略宽，Perez Thin DMA的展宽因子为fσ = 1.39， Perez Fat DMA的展宽因子为1.28。Perez Thin DMA比Perez Fat DMA具有更高的分辨率。对于20nm颗粒，Perez Thin DMA在护套/气溶胶流速比为20/2时实现了超过8的尺寸分辨率，当比率增加到100/5时超过11。10-30 nm粒子的穿透效率高于72.6%，其中Fat DMA的穿透效率高于Thin DMA。在较高的护套流速下，穿透效率下降，可能是由于较小的流动湍流和DMA出口电场的变化导致了颗粒损失。校准后，Perez Fat DMA适用于测量线发生器中产生的金属颗粒的尺寸分布和充电特性。在中等护套流速下，Perez dma可提供更大的尺寸测量范围、更高的尺寸分辨率和出色的穿透效率。

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Transfer function and transmission measurements of the Perez differential mobility analyzer (DMA) at moderate sheath flow rates

The newly developed Perez Differential Mobility Analyzer (DMA) provides high size resolution for viral particles and similarly sized particles. In this study, we measured its transfer function and transmission at moderate sheath flow rates (from 20 to 100 L min⁻¹) to extend its application for the measurement of broader sized particles. Two DMAs—a Perez Fat DMA and a Perez Thin DMA, were first calibrated using tetraheptylammonium bromide monomer (THA⁺) at sheath flow rates ranging from 100 to 400 L min⁻¹. Subsequently, a tandem Perez DMA setup was constructed. The former DMA was operated at high sheath/aerosol flow rate ratios to classify metal particles sized between 10 and 30 nm with a high resolution. The latter DMA was operated at moderate sheath flow rates ranging from 20 to 100 L min⁻¹. Particles classified by the former DMA were assumed monodispersed and used to calibrate the latter one. The measured transfer function for 10 nm particles was only slightly broader than the theoretical transfer function, with broadening factors of f_σ = 1.39 for the Perez Thin DMA and 1.28 for the Perez Fat DMA. The Perez Thin DMA exhibited higher resolutions than the Perez Fat DMA. For 20 nm particles, the Perez Thin DMA achieved a size resolution exceeding 8 at a sheath/aerosol flow rate ratio of 20/2 and over 11 when the ratio increased to 100/5. The penetration efficiencies of 10–30 nm particles were higher than 72.6%, with the Perez Fat DMA having higher penetration efficiencies than the Perez Thin DMA. Decreasing penetration efficiencies were observed under higher sheath flow rates, likely due to minor flow turbulence and changes in the electric field at the DMA outlet, which contributed to particle losses. After calibration, the Perez Fat DMA was adapted to measure the size distributions and charging properties of metal particles produced in a wire generator. At moderate sheath flow rates, Perez DMAs provide an extended size measurement range, high size resolution, and excellent penetration efficiency.

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来源期刊

Journal of Aerosol Science 环境科学-工程：化工

CiteScore

8.80

自引率

8.90%

发文量

127

审稿时长

35 days

期刊介绍： Founded in 1970, the Journal of Aerosol Science considers itself the prime vehicle for the publication of original work as well as reviews related to fundamental and applied aerosol research, as well as aerosol instrumentation. Its content is directed at scientists working in engineering disciplines, as well as physics, chemistry, and environmental sciences. The editors welcome submissions of papers describing recent experimental, numerical, and theoretical research related to the following topics: 1. Fundamental Aerosol Science. 2. Applied Aerosol Science. 3. Instrumentation & Measurement Methods.