Observed aerosol‐layer depth at Station Nord in the high Arctic

Gryning, Sven‐Erik; Batchvarova, Ekaterina; Floors, Rogier; Münkel, Christoph; Sørensen, Lise Lotte; Skov, Henrik

doi:10.1002/joc.8027

Cited by 3 publications

(2 citation statements)

References 64 publications

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“…Moreover, at the Ny-Ålesund site, a CL51 Vaisala ceilometer, operating at 910 nm using a pulsed InGaAs laser, is located, which produces lidar backscatter profiles nominally up to a 15 km altitude. Even though the data quality of this instrument is lower than that of a Raman lidar, ceilometers of this type have been used to derive backscatter profiles from boreal forest fires [37] or Arctic aerosols [38]. However, absorption by water vapor needs to be considered at this wavelength [39].…”

Section: Instrumentsmentioning

confidence: 99%

Improvement of Aerosol Coarse-Mode Detection through Additional Use of Infrared Wavelengths in the Inversion of Arctic Lidar Data

Böckmann,

Ritter,

Graßl

2024

Remote Sensing

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An Nd:YAG-based Raman lidar provides a mature technology to derive profiles of the optical properties of aerosols over a wide altitude range. However, the derivation of micro-physical parameters is an ill-posed problem. Hence, increasing the information content of lidar data is desirable. Recently, ceilometers and wind lidar systems, both operating in the near-infrared region, have been successfully employed in aerosol research. In this study, we demonstrate that the inclusion of additional backscatter coefficients from these two latter instruments clearly improves the inversion of micro-physical parameters such as volume distribution function, effective radius, or single-scattering albedo. We focus on the Arctic aerosol and start with the typical volume distribution functions of Arctic haze and boreal biomass burning. We forward calculate the optical coefficients that the lidar systems should have seen and include or exclude the backscatter coefficients of the ceilometer (910 nm) and wind lidar data (1500 nm) to analyze the value of these wavelengths in their ability to reproduce the volume distribution function, which may be mono- or bimodal. We found that not only the coarse mode but also the properties of the accumulation mode improved when the additional wavelengths were considered. Generally, the 1500 nm wavelength has greater value in correctly reproducing the aerosol properties.

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Section: Instrumentsmentioning

confidence: 99%

Improvement of Aerosol Coarse-Mode Detection through Additional Use of Infrared Wavelengths in the Inversion of Arctic Lidar Data

Böckmann,

Ritter,

Graßl

2024

Remote Sensing

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“…Trajectories of 168-hour length were calculated, arriving at 50 m above ground level, for every hour from 2007 to 2019. The trajectory starting height of 50 m was selected as a compromise between capturing air masses that are representative of our sampling site due to very low boundary layers in the Arctic (Gryning et al, 2023) and avoiding trajectories intercepting the surface, which can produce unrepresentative trajectories (Stohl, 1998). The trajectory length was chosen to avoid the uncertainty associated with extremely long trajectory calculations.…”

Section: Back Trajectory Analysismentioning

confidence: 99%

On the dynamics of ozone depletion events at Villum Research Station in the High Arctic

Pernov,

Hjorth,

Sørensen

et al. 2024

Preprint

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Abstract. Ozone depletion events (ODEs) occur every spring in the Arctic and have implications for the atmospheric oxidizing capacity, radiative balance, and mercury oxidation. Here we comprehensively analyze ozone, ODEs, and their connection to meteorological and air mass history variables through statistical analyses, back-trajectories, and machine learning (ML) from observations at Villum Research Station, Station Nord, Greenland. We show that the ODE frequency and duration peak in May followed by April and March, which is likely related to air masses spending more time over sea ice and increases in radiation from March to May. Back-trajectories indicate that, as spring progresses, ODE air masses spend more time within the mixed layer and the geographic origins move closer to Villum. ODE frequency and duration are increasing during May (low confidence) and April (high confidence), respectively. Our analysis revealed that ODEs are favorable under sunny, calm conditions with air masses arriving from northerly wind directions with sea ice contact. The ML model was able to reproduce the ODE occurrence and illuminated that radiation, time over sea ice, and temperature were the most important variables for modeling ODEs during March, April, and May, respectively. Several variables displayed threshold ranges for contributing to the positive prediction of ODEs vs Non-ODEs, notably temperature, radiation, wind direction, time spent over sea ice, and snow. Our ML methodology provides a framework for investigating and comparing the environmental drivers of ODEs between different Arctic sites and can be applied to other atmospheric phenomena (e.g., atmospheric mercury depletion events).

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Ice-nucleating particles in northern Greenland: annual cycles, biological contribution and parameterizations

et al. 2023

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Abstract. Ice-nucleating particles (INPs) can initiate ice formation in clouds at temperatures above −38 ∘C through heterogeneous ice nucleation. As a result, INPs affect cloud microphysical and radiative properties, cloud lifetime, and precipitation behavior and thereby ultimately the Earth's climate. Yet, little is known regarding the sources, abundance and properties of INPs, especially in remote regions such as the Arctic. In this study, 2-year-long INP measurements (from July 2018 to September 2020) at Villum Research Station in northern Greenland are presented. A low-volume filter sampler was deployed to collect filter samples for offline INP analysis. An annual cycle of INP concentration (NINP) was observed, and the fraction of heat-labile INPs was found to be higher in months with low to no snow cover and lower in months when the surface was well covered in snow (> 0.8 m). Samples were categorized into three different types based only on the slope of their INP spectra, namely into summer, winter and mix type. For each of the types a temperature-dependent INP parameterization was derived, clearly different depending on the time of the year. Winter and summer types occurred only during their respective seasons and were seen 60 % of the time. The mixed type occurred in the remaining 40 % of the time throughout the year. April, May and November were found to be transition months. A case study comparing April 2019 and April 2020 was performed. The month of April was selected because a significant difference in NINP was observed during these two periods, with clearly higher NINP in April 2020. In parallel to the observed differences in NINP, also a higher cloud-ice fraction was observed in satellite data for April 2020, compared to April 2019. NINP in the case study period revealed no clear dependency on either meteorological parameters or different surface types which were passed by the collected air masses. Overall, the results suggest that the coastal regions of Greenland were the main sources of INPs in April 2019 and 2020, most likely including both local terrestrial and marine sources.

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Observed aerosol‐layer depth at Station Nord in the high Arctic

Cited by 3 publications

References 64 publications

Improvement of Aerosol Coarse-Mode Detection through Additional Use of Infrared Wavelengths in the Inversion of Arctic Lidar Data

Improvement of Aerosol Coarse-Mode Detection through Additional Use of Infrared Wavelengths in the Inversion of Arctic Lidar Data

On the dynamics of ozone depletion events at Villum Research Station in the High Arctic

Ice-nucleating particles in northern Greenland: annual cycles, biological contribution and parameterizations

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