Vertical Gradient of Size-Resolved Aerosol Compositions over the Arctic Reveals Cloud Processed Aerosol in-Cloud and above Cloud

Lata, Nurun Nahar; Cheng, Zezhen; Dexheimer, Darielle; Zhang, Damao; Mei, Fan; China, Swarup

doi:10.1021/acs.est.2c09498

Cited by 7 publications

(3 citation statements)

References 66 publications

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“…We investigated the elemental composition, morphology, and size of the particles using computer controlled scanning electron microscope (CCSEM, FEI Quanta Environmental) coupled with the energy-dispersive X-ray (EDX) spectrometer. , CCSEM-EDX was operated at 20 kV and 480 pA current at 293 K and under vacuum conditions (2 × 10 –6 Torr), potentially resulting in the loss of some volatile compounds. The particles detected by the X-ray were subsequently categorized into eight distinct groups, which are illustrated in Figure S4.…”

Section: Methodsmentioning

confidence: 99%

“…Colocated particle samples for micro-spectroscopy analysis were collected via a sioutas cascade impactor (sioutasSKC) at 9 L/ min (Model B1B-090 V12AN-00, Parker Hannifin), similar to previously reported implementations. 54 Particles were collected on four different stages: A, B, C, and D. All the microspectroscopy analyses were performed on stage D particles, which has a 50% cut-off particle diameter 0.15 μm. Stage D is chosen for its good sample loading in comparison to stages A, B, and C. Microspectroscopy samples were stored at room temperature.…”

Section: Sample Collectionmentioning

confidence: 99%

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Chemical Insights into the Molecular Composition of Organic Aerosols in the Urban Region of Houston, Texas

Gautam,

Vandergrift,

Lata

et al. 2024

ACS EST Air

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Molecular functional groups, such as organosulfates (CHOS) and organonitrates (CHNO) are important tracers for field observations of secondary organic aerosols (SOA). While CHOS and CHNO are prevalent in the atmosphere, there is a lack of knowledge regarding daily and day- and night-time variations in these species in the urban atmosphere. Meteorological factors such as wind speed/direction, relative humidity (RH), and temperature can influence the formation of CHOS/CHNO. To investigate these trends, we utilized multimodal chemical imaging and advanced high resolution mass spectrometry techniques to acquire particle speciation and molecular formulas (MFs) associated with day and night sampling periods. Back trajectory analyses revealed the oceanic influence of southern wind airmasses in later June sampling periods with organic fractions <10%. Conversely, northern winds in early June sampling periods contributed to the episodic emergence of extremely low volatile organics (ELVOCs) and organic factions up to 41%. The observed unique MFs to June 3 (223 MFs) and to June 4 (144 MFs) were largely found to be of biogenic rather than anthropogenic origin. Our findings reveal episodic prevalence and temporal distribution of SOA constituents across the urban region of Houston, Texas.

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Section: Methodsmentioning

confidence: 99%

Section: Sample Collectionmentioning

confidence: 99%

Chemical Insights into the Molecular Composition of Organic Aerosols in the Urban Region of Houston, Texas

Gautam,

Vandergrift,

Lata

et al. 2024

ACS EST Air

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“…The POPS is a lightweight (550 g) optical particle counter measuring particle number and particle size distribution in the range of 115 nm -3.37 µm at a 1-second time resolution. POPS was designed to be used on mobile platforms and has already been deployed with success on radiosonde balloons (Yu et al, 2017(Yu et al, , 2019Kloss et al, 2020), tethered balloons (de Boer et al, 2018;Creamean et al, 2021;Pilz et al, 2022;Mei et al, 2022;Walter et al, 2023;Lata et al, 2023), fixed-wing UAVs (Telg et al, 2017;Kezoudi et al, 2021;Mei et al, 2022;DeFelice et al, 2023), and other multirotor UAVs (Liu et al, 2021;Brus et al, 2021).…”

Section: Measurement Uavmentioning

confidence: 99%

Two new multirotor UAVs for glaciogenic cloud seeding and aerosol measurements within the CLOUDLAB project

Miller,

Ramelli,

Fuchs

et al. 2023

Preprint

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Abstract. Uncrewed Aerial Vehicles (UAVs) have become widely used in a range of atmospheric science research applications. Because of their small size, flexible range of motion, adaptability, and low cost, multirotor UAVs are especially well-suited for probing the lower atmosphere. However, their use so far has been limited to conditions outside of clouds, first because of the difficulty of flying beyond visual line of sight, and second because of the challenge of flying in icing conditions in supercooled clouds. Here, we present two UAVs for cloud microphysical research: one UAV (the measurement UAV) equipped with a Portable Optical Particle Spectrometer (POPS) and meteorological sensors to probe the aerosol and meteorological properties in the boundary layer, and one UAV (the seeding UAV) equipped with seeding flares to produce a plume of particles that can initiate ice in supercooled clouds. A propeller heating mechanism on both UAVs allows for operating in supercooled clouds with icing conditions. These UAVs are an integral part of the CLOUDLAB project in which glaciogenic cloud seeding of supercooled low stratus clouds is utilized for studying aerosol-cloud interactions and ice crystal formation and growth. In this paper, we first show validations of the POPS onboard the measurement UAV, demonstrating that the rotor turbulence has a negligible effect on aerosol measurements. We exemplify its applicability for profiling the planetary boundary layer, as well as for sampling and characterizing aerosol plumes, in this case, the seeding plume. We explain the different flight patterns that are possible for both UAVs, namely horizontal or vertical leg patterns or hovering, with an extensive and flexible parameter space for designing the flight patterns according to our scientific goals. Finally, we show two examples of seeding experiments: first characterizing an out-of-cloud seeding plume with the measurement UAV flying horizontal transects through the plume, and second, characterizing an in-cloud seeding plume with downstream measurements with POPS on a tethered balloon. Particle concentrations and size distributions of the seeding plume from the experiments reveal that we can successfully produce and measure the seeding plume, both in-cloud and out-of-cloud. The methods presented here will be useful for probing the lower atmosphere, for characterizing aerosol plumes, and for deepening our cloud microphysical understanding through cloud seeding experiments, all of which have the potential to benefit the atmospheric science community.

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Scanning transmission X-ray microscopy at the Advanced Light Source

Feggeler

Levitan

Marcus

et al. 2023

Journal of Electron Spectroscopy and Related Phenomena

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Vertical Gradient of Size-Resolved Aerosol Compositions over the Arctic Reveals Cloud Processed Aerosol in-Cloud and above Cloud

Cited by 7 publications

References 66 publications

Chemical Insights into the Molecular Composition of Organic Aerosols in the Urban Region of Houston, Texas

Chemical Insights into the Molecular Composition of Organic Aerosols in the Urban Region of Houston, Texas

Two new multirotor UAVs for glaciogenic cloud seeding and aerosol measurements within the CLOUDLAB project

Scanning transmission X-ray microscopy at the Advanced Light Source

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