Why Do Clouds Form at Different Heights
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Meteoric Aerosols in the Middle Atmosphere Linda Megner
Meteoric Aerosols in the Middle Atmosphere Linda Megner AKADEMISK AVHANDLING f¨orfilosofie doktorsexamen vid Stockholms universitet att framl¨aggasf¨oroffentlig granskning den 5 juni 2008 Meteoric Aerosols in the Middle Atmosphere Doctoral thesis Linda Megner ISBN 978-91-7155-676-9, pp. 1-32 c Linda Megner, Stockholm 2008 Stockholm University Department of Meteorology 10691 Stockholm Sweden Printed by Universitetsservice US-AB Stockholm 2008 Abstract Meteoroids entering the Earth’s atmosphere experience strong decelera- tion and ablate, whereupon the resulting material is believed to re-condense as smoke particles of nanometre size. These particles are thought to play a major role in middle atmospheric processes, effecting the charge and radia- tion balance, ice nucleation and chemistry. This thesis concerns the fate of the meteoric smoke in the Middle Atmosphere, and in particular its effect on the formation of ice phenomena such as noctilucent clouds (NLC), polar mesospheric summer echoes (PMSE) and polar stratospheric clouds (PSC). The potential role of NLC as tracer for mesospheric processes and variabil- ity has generated substantial interest in these clouds. Once their formation is understood they can provide an important tool for monitoring this remote and inaccessible region. Today, it is well established that NLC consists of water ice, but the nucleation of ice in such a dry region has long puzzled the middle atmosphere research community. Supersaturation is not considered high enough for homogeneous nucleation to occur, thus pre-existing condensa- tion nuclei are deemed necessary. Among the possible nuclei, smoke particles have long been considered the most likely. Generally, it has been believed that these particles exist in numbers of the order of thousands per cubic cen- timetre at the mesopause. -
Tomographic Views of the Middle Atmosphere from a Satellite Platform
Tomographic views of the middle atmosphere from a satellite platform Kristoffer Hultgren AKADEMISK AVHANDLING for¨ filosofie doktorsexamen vid Stockholms Universitet att framlaggas¨ for¨ offentlig granskning den 3 oktober 2014 Department of Meteorology Stockholm University Stockholm 2014 Cover image: Polar Mesospheric Clouds above Vallentuna, Sweden Photographer: P-M Hed´en,www.clearskies.se Tomographic views of the middle atmosphere from a satellite platform Doctoral thesis Kristoffer Hultgren ISBN 978-91-7447-974-4 © Kristoffer Hultgren, Stockholm, 2014 Stockholm University Department of Meteorology 106 91 Stockholm Sweden Printed by US-AB Stockholm, 2014 Summary The middle atmosphere is a very important part of the Earth system. Until recently, we did not realize the importance of the structure of this vaporous shell and of the fundamental role it plays in both creating and sustaining life on the planet. Thanks to the development and improvement of new sounding methods and techniques, our knowledge of the composition of the atmosphere has become more detailed than ever before. We have also learned how to reveal complex interactions between different species and how they react to the incoming solar radiation. The middle part of the Earth's atmosphere serves as a host for the Polar Mesospheric Clouds. These clouds consist of a thin layer of water-ice particles, only existing during the summer months and only close to the poles. These clouds can be used as a proxy for middle atmospheric dynamics. In order to fully utilize Polar Mesospheric Clouds as tracers for atmospheric variability and dynamics, we need to better understand their local properties. The Optical Spectrograph and Infra-Red Imager System (OSIRIS) is one of two instruments installed on the Odin satellite. -
Towards a Framework for Noctilucent Cloud Analysis
Preprints (www.preprints.org) | NOT PEER-REVIEWED | Posted: 7 October 2019 doi:10.20944/preprints201910.0061.v1 Peer-reviewed version available at Remote Sens. 2019, 11, 2743; doi:10.3390/rs11232743 Article Towards a framework for Noctilucent Cloud Analysis Puneet Sharma 1*, Peter Dalin 2 and Ingrid Mann 3, 1 Department of Engineering & Safety (IIS-IVT), The Arctic University of Norway; [email protected] 2 The Swedish Institute of Space Physics, Sweden; [email protected] 3 Department of Physics and Technology, The Arctic University of Norway, Tromsø; [email protected] * Correspondence: [email protected]; Abstract: In this paper, we present a framework to study the spatial structure of noctilucent clouds formed by ice particles in the upper atmosphere at mid and high latitude during summer. We study noctilucent cloud activity in optical images taken from three different locations and under different atmospheric conditions. In order to identify and distinguish noctilucent cloud activity from other objects in the scene, we employ linear discriminant analysis (LDA) with feature vectors ranging from simple metrics to higher-order local autocorrelation (HLAC), and histogram of oriented gradients (HOG). Finally, we propose a Convolutional Neural Networks (CNN) based method for the detection of noctilucent clouds. The results clearly indicate that the CNN based approach outperforms LDA based methods used in this article. Furthermore, we outline suggestions for future research directions to establish a framework that can be used for synchronizing the optical observations from ground based camera systems with echoes measured with radar systems like EISCAT in order to obtain independent additional information on the ice clouds. -
Bright Polar Mesospheric Clouds Formed by Main Engine Exhaust from the Space Shuttle's Final Launch
JOURNAL OF GEOPHYSICAL RESEARCH, VOL. 117, D19206, doi:10.1029/2012JD017638, 2012 Bright polar mesospheric clouds formed by main engine exhaust from the space shuttle’s final launch Michael H. Stevens,1 Stefan Lossow,2,3 Jens Fiedler,4 Gerd Baumgarten,4 Franz-Josef Lübken,4 Kristofer Hallgren,5,6 Paul Hartogh,5 Cora E. Randall,7 Jerry Lumpe,8 Scott M. Bailey,9 R. Niciejewski,10 R. R. Meier,11 John M. C. Plane,12 Andrew J. Kochenash,13 Donal P. Murtagh,14 and Christoph R. Englert1 Received 15 February 2012; revised 25 June 2012; accepted 14 August 2012; published 5 October 2012. [1] The space shuttle launched for the last time on 8 July 2011. As with most shuttle launches, the three main engines injected about 350 t of water vapor between 100 and 115 km off the east coast of the United States during its ascent to orbit. We follow the motion of this exhaust with a variety of satellite and ground-based data sets and find that (1) the shuttle water vapor plume spread out horizontally in all directions over a distance of 3000 to 4000 km in 18 h, (2) a portion of the plume reached northern Europe in 21 h to form polar mesospheric clouds (PMCs) that are brighter than over 99% of all PMCs observed in that region, and (3) the observed altitude dependence of the particle size is reversed with larger particles above smaller particles. We use a one-dimensional cloud formation model initialized with predictions of a plume diffusion model to simulate the unusually bright PMCs. -
Produced at Taxedo.Com U.S
produced at taxedo.com U.S. Standard Atmosphere 1976 Pressure [mbar] 10-4 10-3 10-2 10-1 1 10 102 103 110 100 90 80 70 60 50 Altitude [km] 40 30 P 20 10 0 U.S. Standard Atmosphere 1976 Pressure [mbar] 10-4 10-3 10-2 10-1 1 10 102 103 110 110 100 Thermosphere 100 90 90 Mesopause 80 80 70 Mesosphere 70 60 60 50 Stratopause 50 Altitude [km] 40 40 ozone 30 T Stratosphere 30 layer P 20 20 10 Tropopause 10 Troposphere 'weather' 0 0 180 200 220 240 260 280 300 Temperature [K] To a good approximation air can be treated as an ideal gas! Dalton's law: Mixing ratio: diffusion constant for inert species! important => "heterosphere" ~mesopause 80 HO2 CO2 Ar O2 N2 60 well-mixed 40 => "homosphere" Altitude (km) highly variable! 20 removal of water by precipitation! 0 -6 -5 -4 -3 -2 -1 0 10 10 10 10 10 10 10 Mixing ratio (mol/mol) adapted with changes from Bohren, Huffman and Clothiaux, 2010 as well as from Roedel and Wagner, 2011 'Janus' behavior of water Water is the most effective greenhouse gas! => heating! The Earth with clouds Robert A. Rohde, globalwarmingart.com: Atmospheric Transmission.png Water is also the greatest reflector of incoming sunlight => cooling Water cycle: ¤ dominant source: ¤ evaporation and evapotranspiration ¤ total atmospheric water mass: ~1.3x1016 kg ¤ loss rate: ¤ global mean precipitation rate is ~1000 mm per year =ˆ ~5.1x1017 kg/year ¤ mean atmospheric lifetime of a water molecule: total mass = H2O loss rate 1.3x1016 kg = 5.1x1017 kg/year = ~9 days! Other functions of water: ¤ energy transport (latent heat) => enhances vertical mixing of air ¤ cleansing agent for water-soluble trace gases ¤ cleansing agent for aerosol particles ¤ catalyst for heterogeneous chemical reactions => e.g. -
Contrail Formation in the Tropopause Region Caused by Emissions from an Ariane 5 Rocket
Progress in Propulsion Physics 8 (2016) 183-196 DOI: 10.1051/eucass/201608183 © Owned by the authors, published by EDP Sciences, 2016 CONTRAIL FORMATION IN THE TROPOPAUSE REGION CAUSED BY EMISSIONS FROM AN ARIANE 5 ROCKET Ch. Voigt1,2, U. Schumann1, and K. Graf1 1Deutsches Zentrum fur Luft- und Raumfahrt (DLR) Institut fur Physik der Atmosphare Oberpfa¨enhofen, Wessling D-82234, Germany 2Johannes-Gutenberg-Universitat Mainz Institut fur Physik der Atmosphare 21 Johannes-Joachim-Becher-Weg, Mainz D-55099, Germany Rockets directly inject water vapor and aerosol into the atmosphere, which promotes the formation of ice clouds in ice supersaturated lay- ers of the atmosphere. Enhanced mesospheric cloud occurrence has frequently been detected near 80-kilometer altitude a few days after rocket launches. Here, unique evidence for cirrus formation in the tropopause region caused by ice nucleation in the exhaust plume from an Ariane 5-ECA rocket is presented. Meteorological reanalysis data from the European Centre for Medium-Range Weather Forecasts show signif- icant ice supersaturation at the 100-hectopascal level in the American tropical tropopause region on November 26, 2011. Near 17-kilometer altitudes, the temperatures are below the SchmidtAppleman thresh- old temperature for rocket condensation trail formation on that day. Immediately after the launch from the Ariane 5-ECA at 18:39 UT (uni- versal time) from Kourou, French Guiana, the formation of a rocket con- trail is detected in the high resolution visible channel from the SEVIRI (Spinning Enhanced Visible and InfraRed Imager) on the METEOSAT- 9 satellite. The rocket contrail is transported to the south and its dis- persion is followed in SEVIRI data for almost 2 h. -
Noctilucent Clouds
August 7, 2016 @ Yaroslavl, Russia Noctilucent Clouds Noctilucent clouds are composed of tiny crystals of water ice up to 0.1 micron in diameter. They are the highest clouds in Earth's atmosphere, located in the mesosphere at altitudes of around 76 to 85 kilometres (47 to 53 mi). They are most commonly observed in the summer months at latitudes between 50° and 70° north and south of the equator. These clouds can be observed only when the Sun is below the horizon for the observer, but while the clouds are still in sunlight. Noctilucent clouds require water vapour, dust, and very cold temperatures to form. The sources of both the dust and the water vapour in the upper atmosphere are not known with certainty. The dust is believed to come from micrometeors, although particulates from volcanoes and dust from the troposphere are also possibilities. The moisture could be lifted through gaps in the tropopause, as well as forming from the reaction of methane with hydroxyl radicals in the stratosphere. NOCTILUCENT CLOUDS APPEAR OVER ANTARCTICA: This just in from NASA's AIM spacecraft: The sky above Antarctica is glowing electric blue. A ring of bright noctilucent clouds (NLCs) has formed around the South Pole, shown here in a Nov. 24, 2016, image taken by the spacecraft's Cloud Imaging and Particle Size (CIPS) Instrument: Southern Hemisphere Noctilucent Clouds "This season started on Nov. 17th, and is tied with 2013 for the earliest southern hemisphere season in the CIPS data record," says Cora Randall, a member of the AIM science team at the University of Colorado. -
Unravelling the Microphysics of Polar Mesospheric Cloud Formation
Unravelling the microphysics of polar mesospheric cloud formation Denis Duft 1, Mario Nachbar 1, Thomas Leisner 1,2 1 Institute of Meteorology and Climate Research, Karlsruhe Institute of Technology, Karlsruhe, 76021, Germany 2 Institute of Environmental Physics, University of Heidelberg, Heidelberg, 69120, Germany 5 Correspondence to : Denis Duft ([email protected]) Abstract. Polar mesospheric clouds are the highest water ice clouds occurring in the terrestrial atmosphere. They form in the polar summer mesopause, the coldest region in the atmosphere. It has long been assumed that these clouds form by heterogeneous nucleation on meteoric smoke particles which are the remnants of material ablated from meteoroids in the upper atmosphere. However, until now little was known about the properties of these nm-size particles and application of the classical 10 theory for heterogeneous ice nucleation was impacted by large uncertainties. In this work, we performed laboratory measurements on the heterogeneous ice formation process at mesopause conditions on small (r=1 to 3 nm) iron-silicate nano- particles serving as meteoric smoke analogues. We observe that ice growth on these particles sets in for saturation ratios with respect to hexagonal ice below Sh=50, a value that is commonly exceeded during polar mesospheric cloud season, affirming meteoric smoke particles as likely nuclei for heterogeneous ice formation in mesospheric clouds. We present a simple ice 15 activation model based on the Kelvin-Thomson equation that takes into account the water coverage of iron-silicates of various compositions. The activation model reproduces the experimental data very well using bulk properties of compact amorphous solid water. -
Stratospheric Observations of Noctilucent Clouds: a New Approach in Studying Middle- and Large-Scale Mesospheric Dynamics
Ann. Geophys., 38, 61–71, 2020 https://doi.org/10.5194/angeo-38-61-2020 © Author(s) 2020. This work is distributed under the Creative Commons Attribution 4.0 License. Stratospheric observations of noctilucent clouds: a new approach in studying middle- and large-scale mesospheric dynamics Peter Dalin1,2, Nikolay Pertsev3, Vladimir Perminov3, Denis Efremov4,5, and Vitaly Romejko6 1Solar Terrestrial and Atmospheric Research, Swedish Institute of Space Physics, P.O. Box 812, 981 28 Kiruna, Sweden 2Space Research Institute, RAS, Profsouznaya st. 84/32, Moscow, 117997, Russia 3A.M. Obukhov Institute of Atmospheric Physics, RAS, Pyzhevskiy per. 3, Moscow, 119017, Russia 4Aerospace laboratory “Stratonautica”, Moscow, Russia 5Faculty of Cosmic Research, M.V. Lomonosov Moscow State University, GSP-1, Leninskie Gory, Moscow, 119991, Russia 6The Moscow Association for NLC Research, Kosygina st. 17, Moscow, 119334, Russia Correspondence: Peter Dalin ([email protected]) Received: 8 August 2019 – Discussion started: 20 August 2019 Revised: 29 November 2019 – Accepted: 11 December 2019 – Published: 16 January 2020 Abstract. The Stratospheric Observations of Noctilucent studies on the time evolution of the cloud movements will be Clouds (SONC) experimental campaign was conducted on done in the future. the night of 5–6 July 2018 with the aim of photographing noctilucent clouds (NLCs) and studying their large-scale spa- tial dynamics at scales of 100–1450 km. An automated high- resolution camera (equipped with a wide-angle lens) was 1 Introduction lifted by a stratospheric sounding balloon to 20.4 km altitude above the Moscow region in Russia ( ∼ 56◦ N, 41◦ E), tak- Night-shining clouds or noctilucent clouds (NLCs) are the ing several hundreds of NLC images during the flight that highest clouds in the Earth’s atmosphere observed at the lasted 1.7 h. -
Space Vehicle Terrestrial Environment Design NASA Marshall Space Flight Center Requirements Guidelines (Draft 11/14/05A)
I Source of Acquisition Space Vehicle Terrestrial Environment Design NASA Marshall Space Flight Center Requirements Guidelines (Draft 11/14/05a) Dale L. Johnson' and Vernon W. Kellert NASA Marshall Space Flight Center, Huntsville AL 35812 William W. Vaughan' University of Alabama in Huntsville, Huntsville AL 35899 The terrestrial environment is an important driver of space vehicle structural, control, and thermal system design. NASA is currently in the process of producing an update to an earlier Terrestrial Environment Guidelines for Aerospace Vehide Design and Development Handbook. Ths paper addresses the contents of this updated handbook, with special emphasis on new material being included in the areas of atmospheric thermodynamic models, wind dynamics, atmospheric composition, atmospheric electricity, cloud phenomena, atmospheric extremes, and sea state. In addition, the respective engineering design elements are discussed relative to terrestrial environment inputs that require consideration. Specifc lessons learned that have contributed to the advancements made in the application and awarenss of terrestrial environment inputs for aerospace engineering applications are presented. Nomenclature km = kilometer MAHRSI = Middle Atmosphere High Resolution Spectrograph Investigation NASA = National Aeronautics and Scwe Administration NE = natural environment NLC = noctilucent clouds nm = nanometer NRL = Naval Research Laboratory PMC = polar mesospheric clouds PMSE = polar mesospheric summer echos RCS = readion control system (fuel) RSS -
Measurements of Global Distributions of Polar Mesospheric Clouds During 2005–2012 by MIPAS/Envisat
Atmos. Chem. Phys., 16, 6701–6719, 2016 www.atmos-chem-phys.net/16/6701/2016/ doi:10.5194/acp-16-6701-2016 © Author(s) 2016. CC Attribution 3.0 License. Measurements of global distributions of polar mesospheric clouds during 2005–2012 by MIPAS/Envisat Maya García-Comas1, Manuel López-Puertas1, Bernd Funke1, Á. Aythami Jurado-Navarro1, Angela Gardini1, Gabriele P. Stiller2, Thomas von Clarmann2, and Michael Höpfner2 1Instituto de Astrofísica de Andalucía, CSIC, Granada, Spain 2Karlsruhe Institute of Technology, Institute for Meteorology and Climate Research, Karlsruhe, Germany Correspondence to: M. López-Puertas ([email protected]) Received: 4 February 2016 – Published in Atmos. Chem. Phys. Discuss.: 26 February 2016 Revised: 29 April 2016 – Accepted: 13 May 2016 – Published: 3 June 2016 Abstract. We have analysed MIPAS (Michelson Interfer- of the migrating diurnal tide on the diurnal variation of the ometer for Passive Atmopheric Sounding) infrared measure- PMC volume ice density. ments of PMCs for the summer seasons in the Northern (NH) and Southern (SH) hemispheres from 2005 to 2012. Mea- surements of PMCs using this technique are very useful be- cause they are sensitive to the total ice volume and indepen- 1 Introduction dent of particle size. For the first time, MIPAS has provided coverage of the PMC total ice volume from midlatitudes to Polar mesospheric clouds (PMCs), also called noctilucent the poles. MIPAS measurements indicate the existence of a clouds (NLCs), occur in the coldest regions of the atmo- continuous layer of mesospheric ice, extending from about sphere near the summer polar mesopause. PMCs normally ∼ form a layer extending vertically for several kilometres, 81 km up to about 88–89 km on average and from the ◦ poles to about 50–60◦ in each hemisphere, increasing in con- peaking near 83 km, located at latitudes polewards of 50 . -
2008 Atmospheric Research Technical Highlights (PDF, 18.6
NASA/TM—2009–214181 Laboratory for Atmospheres 2008 Technical Highlights August 2009 COVER PHOTO CaptIONS Top Left: California Fire Sampling California air quality during the ARCTAS-CARB field experiment in summer 2008. The wild fire was encountered and sampled by the DC-8 aircraft. (Photo taken by Mian Chin onboard of DC-8.) Bottom Left: North Pole Flight-1: Sampling the Arctic Haze, ozone depletion events, and long-range transport of pollution and smoke. Photo showing the NASA DC-8 doing measurements near the surface during the spring phase ARCTAS field experiment over the Arctic Ocean. (Photo taken by Mian Chin on board of DC-8.) Top Right: Forecast People The model forecast and satellite support team in front of the Elvey Building in University of Alaska during the spring phase of the ARCTAS field experiment. Several Lab scientists are in the photo. Middle Right: North Pole Flight-2 Sampling the Arctic Haze and long-range transport of pollution and smoke during the spring phase of ARCTAS over Alaska. (Photo taken by Mian Chin on board of DC-8.) Bottom Right: P3B People Photo showing the P-3B crew, scientists from instrument, model forecast, and satellite support teams in front of the NASA P-3B aircraft during the ARCTAS field experiment in Canada, summer 2008. Several Lab scientists are in the photo. NASA/TM—2009–214181 Laboratory for Atmospheres 2008 Technical Highlights National Aeronautics and Space Administration Goddard Space Flight Center Greenbelt, Maryland 20771 August 2009 The NASA STI Program Offi ce … in Profi le Since its founding, NASA has been ded i cated to the • CONFERENCE PUBLICATION.