Ion Mobility-Mass Spectrometry with a Radial Opposed Migration Ion and Aerosol Classifier (ROMIAC)

Mui, Wilton; Thomas, Daniel A.; Downard, Andrew; Beauchamp, J. L.; Seinfeld, John H.; Flagan, Richard C.

doi:10.1021/ac400580u

Cited by 14 publications

(21 citation statements)

References 47 publications

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“…This Radial, Opposed-Migration, Ion and Aerosol Classifier (ROMIAC) enables measurement of ions and particles well into the lownanometer regime, with resolution that has enabled mobility separation of peptide stereoisomers (Mui et al 2013). Here, we describe the use of threedimensional finite element simulations in modeling the performance of an instrument capable of probing a wide range (» 600 £) of mobilities (1 to 20 nm in diameter) at select fixed flow rates, and with R as high as »20.…”

Section: Advancing Nanometer Particle Classificationmentioning

confidence: 99%

“…In this study, we have, therefore, undertaken the design and development of a radial-flow OMAC. This instrument ultimately has important applications for molecular separations as well as for aerosols; it was first applied to molecular ion classification, including the separation of peptide stereoisomers (Mui et al 2013). Hence, it has been labeled the radial opposed migration ion and aerosol classifier (ROMIAC).…”

Section: Desired Featuresmentioning

confidence: 99%

“…Preliminary measurements were conducted in which ROMIAC1 had either 325-mesh or 200-mesh electrodes, with little difference in transmission efficiency observed; these measurements were also conducted with ROMIAC1 with 500-mesh (25% open area) electrodes, both without and with a hole cut in the outlet electrode (so that particles would not pass through a screen to exit through the outlet port), which also showed little difference in transmission efficiency (see the online supplementary information). The residence time for particles in the ROMIAC is estimated at »0.7 s based on an assumed Q a D 1 lpm and the volumes of the tubing and classification region; measurements associated with, but not reported, in Mui et al (2013) suggested that a coupled ROMIACmass spectrometer showed response times of 90.5 s for a step increase in signal.…”

Section: Design Criteria and Prototype Specificationsmentioning

confidence: 99%

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Design, simulation, and characterization of a radial opposed migration ion and aerosol classifier (ROMIAC)

Mui

Mai

Downard

et al. 2017

Aerosol Science and Technology

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We present the design, simulation, and characterization of the radial opposed migration ion and aerosol classifier (ROMIAC), a compact differential electrical mobility classifier. We evaluate the performance of the ROMIAC using a combination of finite element modeling and experimental validation of two nearly identical instruments using tetra-alkyl ammonium halide mass standards and sodium chloride particles. Mobility and efficiency calibrations were performed over a wide range of particle diameters and flow rates to characterize ROMIAC performance under the range of anticipated operating conditions. The ROMIAC performs as designed, though performance deviates from that predicted using simplistic models of the instrument. The underlying causes of this nonideal behavior are found through finite element simulations that predict the performance of the ROMIAC with greater accuracy than the simplistic models. It is concluded that analytical performance models based on idealized geometries, flows, and fields should not be relied on to make accurate a priori predictions about instrumental behavior if the actual geometry or fields deviate from the ideal assumptions. However, if such deviations are accurately captured, finite element simulations have the potential to predict instrumental performance. The present prototype of the ROMIAC maintains its resolution over nearly three orders of magnitude in particle mobility, obtaining sub-20 nm particle size distributions in a compact package with relatively low flow rate operation requirements.

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Section: Advancing Nanometer Particle Classificationmentioning

confidence: 99%

Section: Desired Featuresmentioning

confidence: 99%

Section: Design Criteria and Prototype Specificationsmentioning

confidence: 99%

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Design, simulation, and characterization of a radial opposed migration ion and aerosol classifier (ROMIAC)

Mui

Mai

Downard

et al. 2017

Aerosol Science and Technology

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“…HEPA-filtered, particle-free, room air was directed into the charger and the ions exiting the charger were segregated according to their electrical mobility using a Radial Opposed Migration Ion and Aerosol Classifier, ROMIAC (Mui et al 2013;Mui et al 2017), with a TSI 3068 electrometer used for detecting the ions. The measurement covered the mobility range from 0.1 cm 2 V -1 s -1 to 5.9 cm 2 V -1 s -1 .…”

Section: Ion Mobility Distributionsmentioning

confidence: 99%

Charge distribution uncertainty in differential mobility analysis of aerosols

Leppä

Mui

Grantz

et al. 2017

Aerosol Science and Technology

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“…Other small-sized DMAs (Brunelli et al 2009;Mei et al 2011;Fern andez de la Mora and Kozlowski 2013;Mui et al 2013), operating at high sheath flow rates, are developed for sizing ions and particles in the diameters less than 10 nm. Parallel-plate DMAs with very short particle classification lengths and operated at high sheath flow rates were also reported in literature for ion sizing and the integration with mass spectrometers (Rus et al 2010;Larriba et al 2011).…”

Section: Introductionmentioning

confidence: 99%

Experimental evaluation of miniature plate DMAs (mini-plate DMAs) for future ultrafine particle (UFP) sensor network

Liu

Chen

2016

Aerosol Science and Technology

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Two iPhone-sized differential mobility analyzers (DMAs) in the parallel-plate configuration (i.e., miniplate DMAs) were designed and their performance was calibrated in this study in order to gain the instructive knowledge for the future mini-plate DMA design and to have a well-calibrated mini-plate DMA for the ultrafine particle (UFP) sensor network. The performance of mini-plate DMAs was calibrated using the tandem DMA (TDMA) technique. The experimental transfer functions of prototypes at different particle sizes and under various combinational conditions of aerosol and sheath flow rates were derived from the TDMA data. It is concluded that mini-plate DMAs performed reasonably well for UFP sizing. It was also found that the sizing resolution of mini-plate DMAs is closer to the aerosol-to-sheath flow rate ratio when the percentage of aerosol slit opening in length was increased (relative to the width of aerosol classification zone). A new concept of "effective sheath flow rate" was introduced to better interpret the experimental observation on the area and FWHM (full width at half maximum) data of measured DMA transfer functions. Based on the experimental data, we proposed a modified equation for mini-plate DMAs to better calculate the voltage required to size particles of a given electrical mobility.

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Ion Mobility-Mass Spectrometry with a Radial Opposed Migration Ion and Aerosol Classifier (ROMIAC)

Cited by 14 publications

References 47 publications

Design, simulation, and characterization of a radial opposed migration ion and aerosol classifier (ROMIAC)

Design, simulation, and characterization of a radial opposed migration ion and aerosol classifier (ROMIAC)

Charge distribution uncertainty in differential mobility analysis of aerosols

Experimental evaluation of miniature plate DMAs (mini-plate DMAs) for future ultrafine particle (UFP) sensor network

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