Your search keyword '"Joseph Sedlar"' showing total 5 results

1. Processes contributing to cloud dissipation and formation events on the North Slope of Alaska

Author

Joseph Sedlar, Hagen Telg, and Adele L. Igel

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, Advection, Dissipation, 010502 geochemistry & geophysics, Atmospheric sciences, 01 natural sciences, lcsh:QC1-999, Latitude, Aerosol, lcsh:Chemistry, Atmosphere, Stratification (seeds), Lidar, lcsh:QD1-999, Environmental science, lcsh:Physics, Air mass, 0105 earth and related environmental sciences

Abstract

Clear-sky periods across the high latitudes have profound impacts on the surface energy budget and lower atmospheric stratification; however an understanding of the atmospheric processes leading to low-level cloud dissipation and formation events is limited. A method to identify clear periods at Utqiaġvik (formerly Barrow), Alaska, during a 5-year period (2014–2018) is developed. A suite of remote sensing and in situ measurements from the high-latitude observatory are analyzed; we focus on comparing and contrasting atmospheric properties during low-level (below 2 km) cloud dissipation and formation events to understand the processes controlling clear-sky periods. Vertical profiles of lidar backscatter suggest that aerosol presence across the lower atmosphere is relatively invariant during the periods bookending clear conditions, which suggests that a sparsity of aerosol is not frequently a cause for cloud dissipation on the North Slope of Alaska. Further, meteorological analysis indicates two active processes ongoing that appear to support the formation of low clouds after a clear-sky period: namely, horizontal advection, which was dominant in winter and early spring, and quiescent air mass modification, which was dominant in the summer. During summer, the dominant mode of cloud formation is a low cloud or fog layer developing near the surface. This low cloud formation is driven largely by air mass modification under relatively quiescent synoptic conditions. Near-surface aerosol particles concentrations changed by a factor of 2 around summer formation events. Thermodynamic adjustment and increased aerosol presence under quiescent atmospheric conditions are hypothesized as important mechanisms for fog formation.

Published

2021

2. The free troposphere as a potential source of arctic boundary layer aerosol particles

Author

Joseph Sedlar, Michael Tjernström, Julien Savre, Caroline Leck, Adele L. Igel, and Annica M. L. Ekman

Subjects

010504 meteorology & atmospheric sciences, 010502 geochemistry & geophysics, Atmospheric sciences, 01 natural sciences, Particle transport, The arctic, Aerosol, Troposphere, Boundary layer, Geophysics, Arctic, Climatology, General Earth and Planetary Sciences, Environmental science, Meteorology & Atmospheric Sciences, Potential source, Physics::Atmospheric and Oceanic Physics, 0105 earth and related environmental sciences

Abstract

This study investigates aerosol particle transport from the free troposphere to the boundary layer in the summertime high Arctic. Observations from the Arctic Summer Cloud Ocean Study field campaign show several occurrences of high aerosol particle concentrations above the boundary layer top. Large-eddy simulations suggest that when these enhanced aerosol concentrations are present, they can be an important source of aerosol particles for the boundary layer. Most particles are transported to the boundary layer by entrainment. However, it is found that mixed-phase stratocumulus clouds, which often extend into the inversion layer, also can mediate the transport of particles into the boundary layer by activation at cloud top and evaporation below cloud base. Finally, the simulations also suggest that aerosol properties at the surface sometimes may not be good indicators of aerosol properties in the cloud layer.

Published

2017

3. The Arctic Summer Cloud Ocean Study (ASCOS) : Overview and experimental design

Author

Martin Graus, M. Martin, B. Sierau, Carlton D. Rauschenberg, Armin Hansel, Q. Gao, M. Westberg, L. Di Liberto, Michael Tjernström, M. Szczodrak, Joseph Sedlar, P. O. G. Persson, Erik Swietlicki, E. Granath, G. de Leeuw, Mónica V. Orellana, Petri Vaattovaara, Johan Knulst, D. Orsini, Markus Müller, Zoran Ristovski, C. R. Wheeler, Ian M. Brooks, N. Wahlberg, Matthew D. Shupe, Rachel Y.-W. Chang, Caroline Leck, Jan W. Bottenheim, S. Sjogren, Thorsten Mauritsen, Jussi Paatero, Olaf Stetzer, Paul E. Johnston, Barbara Brooks, Andrew J. Hind, Leif Backlin, Cathryn E. Birch, Sarah J. Norris, Andreas Held, Patricia A. Matrai, S. de la Rosa, Anders Sirevaag, and Jost Heintzenberg

Subjects

Arctic sea ice decline, summer, surface flux, Atmospheric Science, Mathematics and natural scienses: 400::Geosciences: 450::Meteorology: 453 [VDP], aerosol, Meteorologi och atmosfärforskning, Mesoscale meteorology, data set, cloud microphysics, Environment, Atmospheric sciences, arctic environment, lcsh:Chemistry, Matematikk og naturvitenskap: 400::Geofag: 450::Meteorologi: 453 [VDP], Arctic, Urban Development, Arctic Ocean, Sea ice, Cloud condensation nuclei, 14. Life underwater, Built Environment, cloud condensation nucleus, climate modeling, Physics, geography, geography.geographical_feature_category, concentration (composition), Earth / Environmental, CAS - Climate, Air and Sustainability, Arctic ice pack, lcsh:QC1-999, Arctic geoengineering, lcsh:QD1-999, 13. Climate action, Meteorology and Atmospheric Sciences, surface energy, Climatology, Climate model, energy budget, Fram Strait, ELSS - Earth, Life and Social Sciences, lcsh:Physics

Abstract

The climate in the Arctic is changing faster than anywhere else on earth. Poorly understood feedback processes relating to Arctic clouds and aerosol–cloud interactions contribute to a poor understanding of the present changes in the Arctic climate system, and also to a large spread in projections of future climate in the Arctic. The problem is exacerbated by the paucity of research-quality observations in the central Arctic. Improved formulations in climate models require such observations, which can only come from measurements in situ in this difficult-to-reach region with logistically demanding environmental conditions. The Arctic Summer Cloud Ocean Study (ASCOS) was the most extensive central Arctic Ocean expedition with an atmospheric focus during the International Polar Year (IPY) 2007–2008. ASCOS focused on the study of the formation and life cycle of low-level Arctic clouds. ASCOS departed from Longyearbyen on Svalbard on 2 August and returned on 9 September 2008. In transit into and out of the pack ice, four short research stations were undertaken in the Fram Strait: two in open water and two in the marginal ice zone. After traversing the pack ice northward, an ice camp was set up on 12 August at 87°21' N, 01°29' W and remained in operation through 1 September, drifting with the ice. During this time, extensive measurements were taken of atmospheric gas and particle chemistry and physics, mesoscale and boundary-layer meteorology, marine biology and chemistry, and upper ocean physics. ASCOS provides a unique interdisciplinary data set for development and testing of new hypotheses on cloud processes, their interactions with the sea ice and ocean and associated physical, chemical, and biological processes and interactions. For example, the first-ever quantitative observation of bubbles in Arctic leads, combined with the unique discovery of marine organic material, polymer gels with an origin in the ocean, inside cloud droplets suggests the possibility of primary marine organically derived cloud condensation nuclei in Arctic stratocumulus clouds. Direct observations of surface fluxes of aerosols could, however, not explain observed variability in aerosol concentrations, and the balance between local and remote aerosols sources remains open. Lack of cloud condensation nuclei (CCN) was at times a controlling factor in low-level cloud formation, and hence for the impact of clouds on the surface energy budget. ASCOS provided detailed measurements of the surface energy balance from late summer melt into the initial autumn freeze-up, and documented the effects of clouds and storms on the surface energy balance during this transition. In addition to such process-level studies, the unique, independent ASCOS data set can and is being used for validation of satellite retrievals, operational models, and reanalysis data sets., Atmospheric Chemistry and Physics, 14 (6), ISSN:1680-7375, ISSN:1680-7367

Published

2014

4. Vertical profiling of aerosol particles and trace gases over the central Arctic Ocean during summer

Author

S. Sjogren, Erik Swietlicki, Joseph Sedlar, Markus Müller, Michael Tjernström, Sarah J. Norris, Piotr Kupiszewski, Martin Graus, Barbara Brooks, Caroline Leck, and Armin Hansel

Subjects

Drift ice, Atmospheric Science, geography, geography.geographical_feature_category, Planetary boundary layer, Meteorologi och atmosfärforskning, Atmospheric sciences, Arctic ice pack, lcsh:QC1-999, Aerosol, Arctic geoengineering, lcsh:Chemistry, lcsh:QD1-999, Arctic, Meteorology and Atmospheric Sciences, Climatology, Sea ice, Cloud condensation nuclei, Environmental science, lcsh:Physics

Abstract

Unique measurements of vertical size-resolved aerosol particle concentrations, trace gas concentrations and meteorological data were obtained during the Arctic Summer Cloud Ocean Study (ASCOS, www.ascos.se), an International Polar Year project aimed at establishing the processes responsible for formation and evolution of low-level clouds over the high Arctic summer pack ice. The experiment was conducted from on board the Swedish icebreaker Oden, and provided both ship- and helicopter-based measurements. This study focuses on the vertical helicopter profiles and onboard measurements obtained during a three-week period when Oden was anchored to a drifting ice floe, and sheds light on the characteristics of Arctic aerosol particles and their distribution throughout the lower atmosphere. Distinct differences in aerosol particle characteristics within defined atmospheric layers are identified. Within the lowermost couple hundred metres, transport from the marginal ice zone (MIZ), condensational growth and cloud processing develop the aerosol population. During two of the four representative periods defined in this study, such influence is shown. At altitudes above about 1 km, long-range transport occurs frequently. However, only infrequently does large-scale subsidence descend such air masses to become entrained into the mixed layer in the high Arctic, and therefore long-range transport plumes are unlikely to directly influence low-level stratiform cloud formation. Nonetheless, such plumes can influence the radiative balance of the planetary boundary layer (PBL) by influencing formation and evolution of higher clouds, as well as through precipitation transport of particles downwards. New particle formation was occasionally observed, particularly in the near-surface layer. We hypothesize that the origin of these ultrafine particles could be in biological processes, both primary and secondary, within the open leads between the pack ice and/or along the MIZ. In general, local sources, in combination with upstream boundary-layer transport of precursor gases from the MIZ, are considered to constitute the origin of cloud condensation nuclei (CCN) particles and thus be of importance for the formation, Atmospheric Chemistry and Physics, 13 (24), ISSN:1680-7375, ISSN:1680-7367

Published

2013

5. The vertical distribution of thin features over the Arctic analysed from CALIPSO observations. Part I: Optically thin clouds

Author

Colin Jones, Karl-Göran Karlsson, Joseph Sedlar, Ali Omar, Michael Tjernström, Abhay Devasthale, and Manu Anna Thomas

Subjects

Atmospheric Science, Ice cloud, 010504 meteorology & atmospheric sciences, Cloud top, Cloud fraction, Cloud physics, 010501 environmental sciences, Atmospheric sciences, 01 natural sciences, Layer thickness, Aerosol, The arctic, Atmosphere, Troposphere, Arctic, Liquid water content, Climatology, Cloud base, Environmental science, Geology, 0105 earth and related environmental sciences

Abstract

Influx of aerosols from the mid-latitudes has a wide range of impacts on the Arctic atmosphere. In this study, the capability of the CALIPSO-CALIOP instrument to provide accurate observations of aerosol layers is exploited to characterize their vertical distribution, probability density functions (PDFs) of aerosol layer thickness, base and top heights, and optical depths over the Arctic for the 4-yr period from June 2006 to May 2010. It is shown that the bulk of aerosols, from about 65% in winter to 45% in summer, are confined below the lowermost kilometer of the troposphere. In the middle troposphere (3-5 km), spring and autumn seasons show slightly higher aerosol amounts compared to other two seasons. The relative vertical distribution of aerosols shows that clean continental aerosol is the largest contributor in all seasons except in summer, when layers of polluted continental aerosols are almost as large. In winter and spring, polluted continental aerosols are the second largest contributor to the total number of observed aerosol layers, whereas clean marine aerosol is the second largest contributor in summer and autumn. The PDFs of the geometrical thickness of the observed aerosol layers peak about 400-700 m. Polluted continental and smoke aerosols, which are associated with the intrusions from mid-latitudes, have much broader distributions of optical and geometrical thicknesses, suggesting that they appear more often optically thicker and higher up in the troposphere.

Published

2011