Global ETD Search

11	The Behaviour of the Latent Heat Exchange Coefficient in the Stable Marine Boundary Layer Lindgren, Kristina January 2008 (has links) <p>Knowledge of the turbulent fluxes at the sea surface is important for understanding the interaction between atmosphere and ocean. With better knowledge, improvements in the estimation of the heat exchange coefficients can be made and hence models are able to predict the weather and future climate with higher accuracy.</p><p>The exchange coefficients of latent and sensible heat during stable stratification vary in the literature. Therefore it is necessary to investigate the processes influencing the air-sea exchange of water vapour and heat in order to estimate these values. With measurements from a tower and a directional waverider buoy at the site Östergarnsholm in the Baltic Sea, data used in this study have been sampled from the years 2005-2007. This site represents open-ocean conditions during most situations when the wind comes from the south-east sector. The neutral exchange coefficients, CEN and CHN, have been calculated along with the non-dimensional profile functions for temperature and wind to study the dependence of stability and other parameters of relevance.</p><p>It was found that CEN increased slightly with wind speed and reached a mean value of approximately 1.45×10-3. The highest values of CEN were observed during near neutral conditions and low wave ages. CHN attained a mean value of approximately 0.77×10-3 and did not show any relation to wind speed or to wave age. No significant dependence with wind or wave direction could be shown for either CEN or CHN in the sector 80-220°. The stability correction, performed to reduce the dependence on stratification for CEN and CHN, was well performed for stabilities higher than 0.15. The stability is represented by a relationship between the height and the Obukhov-length (z/L).</p><p>Validity of the non-dimensional profile functions for temperature and wind showed that, for smaller stabilities, these functions gave higher values than the corresponding functions recommended by Högström (1996). The profile funtions for temperature was shown to have a larger scatter while the profile functions for wind was less scattered and deviated more from the functions given by Högström</p> / <p>Kunskap om turbulenta flöden i det marina gränsskiktet är viktigt för att förstå växelverkan mellan atmosfär och hav. Med bättre kunskap kan förbättringar i bestämningen av utbyteskoefficienterna för latent och sensibelt värme erhållas. Det medför att modeller kan prognostisera väder och framtida klimat med högre noggrannhet.</p><p>Utbyteskoefficienterna för latent och sensibelt värme har för stabil skiktning olika värden i litteraturen. Detta gör det nödvändigt att undersöka de processer som påverkar utbytet av vattenånga och värme mellan luft och hav för att kunna bestämma dessa värden. Data som har använts i den här studien insamlades mellan år 2005 och 2007 från en boj och ett torn vid mätplatsen Östergarnsholm i Baltiska havet. För det flesta situationer, när vinden blåser från syd-ost, representerar mätplatsen ett förhållande likvärdigt det över öppet hav. De neutrala utbyteskoefficienterna, CEN och CHN, och de dimensionslösa profilfunktionera för temperatur och vind, och , har beräknats för att studera beroendet av stabilitet samt andra relevanta parametrar.</p><p>Beräkningarna visade att CEN ökade något med vindhastighet och hamnade på ett medelvärde av ungefär 1.45×10-3. De högsta värdena på CEN observerades vid nära neutrala förhållanden och låga vågåldrar. CHN uppmättes till att ha ett medelvärde på ungefär 0.77×10-3 och uppvisade inget beroende med vindhastighet eller vågålder. Inget märkbart beroende med vind- eller vågriktning kunde visas för CEN eller CHN i sektorn 80-220°. Stabilitetskorrektionen, utförd för att reducera beroendet av atmosfärens skiktning för CEN och CHN, var bra för stabiliteter högre än 0.15. Stabiliteten representeras av förhållandet mellan höjden och Obukhov-längden (z/L).</p><p>Utvärdering av de dimensionslösa funktionerna för temperatur och vind visade att dessa funktioner, för små stabiliteter, gav högre värden än motsvarande funktioner som rekommenderas av Högström (1996). Värdena på profilfunktionerna för temperatur hade större spridning än värdena på profilfunktionerna för vind och avvek mer från funktionerna givna av Högström.</p> Latent heat flux Sensible heat flux Exchange coefficient Neutral exchange coefficient Turbulent Fluxes Marine Boundary Layer Stable Stratification Air-sea interaction Dimensionless profile functions Östergarnsholm Meteorology Meteorologi
12	Fluxes of Sensible and Latent Heat and Carbon Dioxide in the Marine Atmospheric Boundary Layer Sahlée, Erik January 2007 (has links) <p>Oceans cover about 70% of the earth’s surface. They are the largest source of the atmospheric water vapour and act as enormous heat reservoirs. Thus in order to predict the future weather and climate it is of great importance to understand the processes governing the exchange of water vapour and heat between the ocean and atmosphere. This exchange is to a large extent mediated by turbulent eddies. Current numerical climate and weather forecast models are unable to resolve the turbulence, which means that the turbulent exchange needs to be simplified by using parameterizations. </p><p>Tower based measurements at the Östergarnsholm Island in the Baltic Sea have been used to study the air-sea turbulent exchange of latent and sensible heat and the heat flux parameterizations. Although the measurements are made at an island, data obtained at this site is shown to represent open ocean conditions during most situations for winds coming from the east-south sector. It is found that during conditions with small air-sea temperature differences and wind speeds above 10 m s<sup>-1</sup>, the structure of the turbulence is re-organized. Drier and colder air from aloft is transported to the surface by detached eddies, which considerably enhance the turbulent heat fluxes. The fluxes where observed to be much larger than predicted by current state-of-the-art parameterizations. The turbulence regime during these conditions is termed the Unstable Very Close to Neutral Regime, the UVCN-regime.</p><p>The global increase of the latent and sensible heat fluxes due to the UVCN-regime is calculated to 2.4 W m<sup>-2</sup> and 0.8 W m<sup>-2</sup> respectively. This is comparable to the current increase of the radiative forcing due to anthropogenic emissions of greenhouse gases, reported in Intergovernmental Panel on Climate Change fourth assessment report (IPCC AR4). Thus the UVCN-effect could have a significant influence when predicting the future weather and climate.</p> Meteorology Sensible heat flux Latent heat flux Carbon dioxide Turbulent exchange Global heat fluxes Marine boundary layer Air-sea interaction Meteorologi
13	Fluxes of Sensible and Latent Heat and Carbon Dioxide in the Marine Atmospheric Boundary Layer Sahlée, Erik January 2007 (has links) Oceans cover about 70% of the earth’s surface. They are the largest source of the atmospheric water vapour and act as enormous heat reservoirs. Thus in order to predict the future weather and climate it is of great importance to understand the processes governing the exchange of water vapour and heat between the ocean and atmosphere. This exchange is to a large extent mediated by turbulent eddies. Current numerical climate and weather forecast models are unable to resolve the turbulence, which means that the turbulent exchange needs to be simplified by using parameterizations. Tower based measurements at the Östergarnsholm Island in the Baltic Sea have been used to study the air-sea turbulent exchange of latent and sensible heat and the heat flux parameterizations. Although the measurements are made at an island, data obtained at this site is shown to represent open ocean conditions during most situations for winds coming from the east-south sector. It is found that during conditions with small air-sea temperature differences and wind speeds above 10 m s-1, the structure of the turbulence is re-organized. Drier and colder air from aloft is transported to the surface by detached eddies, which considerably enhance the turbulent heat fluxes. The fluxes where observed to be much larger than predicted by current state-of-the-art parameterizations. The turbulence regime during these conditions is termed the Unstable Very Close to Neutral Regime, the UVCN-regime. The global increase of the latent and sensible heat fluxes due to the UVCN-regime is calculated to 2.4 W m-2 and 0.8 W m-2 respectively. This is comparable to the current increase of the radiative forcing due to anthropogenic emissions of greenhouse gases, reported in Intergovernmental Panel on Climate Change fourth assessment report (IPCC AR4). Thus the UVCN-effect could have a significant influence when predicting the future weather and climate. Meteorology Sensible heat flux Latent heat flux Carbon dioxide Turbulent exchange Global heat fluxes Marine boundary layer Air-sea interaction Meteorologi
14	The Behaviour of the Latent Heat Exchange Coefficient in the Stable Marine Boundary Layer Lindgren, Kristina January 2008 (has links) Knowledge of the turbulent fluxes at the sea surface is important for understanding the interaction between atmosphere and ocean. With better knowledge, improvements in the estimation of the heat exchange coefficients can be made and hence models are able to predict the weather and future climate with higher accuracy. The exchange coefficients of latent and sensible heat during stable stratification vary in the literature. Therefore it is necessary to investigate the processes influencing the air-sea exchange of water vapour and heat in order to estimate these values. With measurements from a tower and a directional waverider buoy at the site Östergarnsholm in the Baltic Sea, data used in this study have been sampled from the years 2005-2007. This site represents open-ocean conditions during most situations when the wind comes from the south-east sector. The neutral exchange coefficients, CEN and CHN, have been calculated along with the non-dimensional profile functions for temperature and wind to study the dependence of stability and other parameters of relevance. It was found that CEN increased slightly with wind speed and reached a mean value of approximately 1.45×10-3. The highest values of CEN were observed during near neutral conditions and low wave ages. CHN attained a mean value of approximately 0.77×10-3 and did not show any relation to wind speed or to wave age. No significant dependence with wind or wave direction could be shown for either CEN or CHN in the sector 80-220°. The stability correction, performed to reduce the dependence on stratification for CEN and CHN, was well performed for stabilities higher than 0.15. The stability is represented by a relationship between the height and the Obukhov-length (z/L). Validity of the non-dimensional profile functions for temperature and wind showed that, for smaller stabilities, these functions gave higher values than the corresponding functions recommended by Högström (1996). The profile funtions for temperature was shown to have a larger scatter while the profile functions for wind was less scattered and deviated more from the functions given by Högström / Kunskap om turbulenta flöden i det marina gränsskiktet är viktigt för att förstå växelverkan mellan atmosfär och hav. Med bättre kunskap kan förbättringar i bestämningen av utbyteskoefficienterna för latent och sensibelt värme erhållas. Det medför att modeller kan prognostisera väder och framtida klimat med högre noggrannhet. Utbyteskoefficienterna för latent och sensibelt värme har för stabil skiktning olika värden i litteraturen. Detta gör det nödvändigt att undersöka de processer som påverkar utbytet av vattenånga och värme mellan luft och hav för att kunna bestämma dessa värden. Data som har använts i den här studien insamlades mellan år 2005 och 2007 från en boj och ett torn vid mätplatsen Östergarnsholm i Baltiska havet. För det flesta situationer, när vinden blåser från syd-ost, representerar mätplatsen ett förhållande likvärdigt det över öppet hav. De neutrala utbyteskoefficienterna, CEN och CHN, och de dimensionslösa profilfunktionera för temperatur och vind, och , har beräknats för att studera beroendet av stabilitet samt andra relevanta parametrar. Beräkningarna visade att CEN ökade något med vindhastighet och hamnade på ett medelvärde av ungefär 1.45×10-3. De högsta värdena på CEN observerades vid nära neutrala förhållanden och låga vågåldrar. CHN uppmättes till att ha ett medelvärde på ungefär 0.77×10-3 och uppvisade inget beroende med vindhastighet eller vågålder. Inget märkbart beroende med vind- eller vågriktning kunde visas för CEN eller CHN i sektorn 80-220°. Stabilitetskorrektionen, utförd för att reducera beroendet av atmosfärens skiktning för CEN och CHN, var bra för stabiliteter högre än 0.15. Stabiliteten representeras av förhållandet mellan höjden och Obukhov-längden (z/L). Utvärdering av de dimensionslösa funktionerna för temperatur och vind visade att dessa funktioner, för små stabiliteter, gav högre värden än motsvarande funktioner som rekommenderas av Högström (1996). Värdena på profilfunktionerna för temperatur hade större spridning än värdena på profilfunktionerna för vind och avvek mer från funktionerna givna av Högström. Latent heat flux Sensible heat flux Exchange coefficient Neutral exchange coefficient Turbulent Fluxes Marine Boundary Layer Stable Stratification Air-sea interaction Dimensionless profile functions Östergarnsholm Meteorology Meteorologi
15	Non-dimensional gradient functions for water vapor and carbon dioxide in the marine boundary layer / Dimensionslösa gradientfunktioner för vattenånga och koldioxid i det marina gränsskiktet Vahlberg, Caroline January 2015 (has links) A better understanding of the exchange processes taking place over the oceans is of great importance since the oceans cover about 70 % of the Earth’s surface. With better knowledge the turbulent fluxes can be more accurate parameterized, which is essential in order to improve the weather- and climate models. In this study, the non-dimensional gradient functions for water vapor (Φq) and carbon dioxide (Φc) in the marine boundary layer have principally been studied. The quality of the instrumentation used in the study has also been evaluated. The study is mainly based on tower measurements of turbulent fluxes and vertical profiles of water vapor and carbon dioxide, taken from the Östergarnsholm Island located in the Baltic Sea. The measurements have been shown to represent open-sea conditions for most situations when the winds are coming from the east-south sector, even though the measurements are obtained over land. It was found that the best fitting non-dimensional gradient functions for water vapor during unstable conditions were Φq = 2(1–18z/L)–1/2 and Φq = 1.2(1–14z/L) –1/2 at the 10 and 26 m level on the tower, respectively. No unique relationship could be established for Φq during stable conditions. Φq showed a dependence with wind direction and could for winds coming from the sector 80°– 160° be described with the relationship Φq = 1.2 + 10.7z/L during stable conditions. For the wind sector 50°– 80° the relationship for Φq was found to be Φq = 1.8 + 7.1z/L during stable conditions. A high degree of scatter was apparent in the calculated values of Φc during both stable and unstable conditions and did not seem to show any Monin-Obukhov similarity behaviour. The results indicate that there might be measurement problems with the instruments measuring the turbulent fluxes of carbon dioxide, but further studies are needed in order to draw a firm conclusion about the quality of the instruments. The profile measurements of water vapor seem to work fine, but more studies of carbon dioxide are needed before a statement can be made regarding the quality of the profile measurements of carbon dioxide. / Skiktet närmast marken kallas det atmosfäriska gränsskiktet och karaktäriseras av turbulens, dvs. oregelbundna virvelrörelser av olika storlekar som uppstår av vindens friktion mot jordytan (land eller hav) eller av luftens uppvärmning av jordytan. Genom turbulens kan utbyte av värme, vattenånga, momentum, koldioxid och andra gaser ske mellan jordytan och atmosfären. Turbulenta utbytesprocesser i det atmosfäriska gränsskiktet är viktiga att studera för att kunna beräkna ett turbulent flöde från en yta i väder- och klimatmodeller. Genom en ökad förståelse av flödena kan dessa bli mer noggrant parametriserade (dvs. en fysikalisk process som sker på en mindre skala eller är för komplex för att kunna beskrivas i en modell förenklas genom att beskriva processen med hjälp av ett antal kända parametrar som kan upplösas i modellen), vilket är grundläggande för att kunna förbättra modellerna. Flödena beräknas med hjälp av de s.k. dimensionslösa gradientfunktionerna, vilka relaterar flödet av en viss turbulent kvantitet, t.ex. värme, momentum, vattenånga, koldioxid etc., till dess vertikala gradient. Enligt Monin-Obukhovs similaritetsteori ska funktionerna vara universella och endast bero på den atmosfäriska stabiliteten. I denna studie har de dimensionslösa gradientfunktionerna för vattenånga (Φq) och koldioxid (Φc) i det marina gränsskiktet huvudsakligen analyserats. Kvaliteten på de instrument som har använts i studien har också utvärderats. I studien har främst data av turbulenta flöden och vertikala profiler av vattenånga och koldioxid använts som erhållits från ett torn på ön Östergarnsholm i Östersjön. Även om mätningarna sker över land har det visat sig att de för de flesta situationer när vinden blåser från sektorn ost-syd representerar likvärdiga förhållanden som gäller över öppet hav. Resultaten visade på att uttrycken Φq = 2(1–18z/L)–1/2 respektive Φq = 1.2(1–14z/L)–1/2 bäst beskriver de dimensionslösa gradientfunktionerna för vattenånga under instabila förhållanden på mäthöjderna 10 respektive 26 m. Något unikt uttryck för Φq under stabila förhållanden kunde inte fastställas. Φq visade ett beroende av vindriktning och kunde under stabila förhållanden beskrivas med uttrycket Φq = 1.2 + 10.7z/L för vindsektorn 80°– 160°. För vindar i sektorn 50°– 80° kunde Φq beskrivas enligt Φq = 1.8 + 7.1z/L under stabila förhållanden. En stor spridning syntes i de beräknade värdena av Φc under både stabila och instabila förhållanden och verkade inte följa Monin-Obukhov’s similaritetsteori. Resultatet tyder på att det kan vara mätproblem med de instrument som mäter de turbulenta flödena av koldioxid, men fler studier behövs för att kunna dra en definitiv slutsats om instrumentens kvalitet. Profilmätningarna av vattenånga verkar fungera bra, men fler studier om koldioxid måste utföras innan ett uttalande angående kvaliteten på profilmätningarna av koldioxid kan göras. Monin-Obukhov similarity theory non-dimensional gradient functions water vapor carbon dioxide marine boundary layer turbulent fluxes Monin-Obukhov similaritetsteori dimensionslösa gradientfunktioner vattenånga koldioxid marina gränsskiktet turbulenta flöden
16	Cycle atmosphérique du mercure dans des zones reculées de l’Hémisphère Sud : cas de la couche limite marine subantarctique et du continent Antarctique / Atmospheric mercury cycling in remote areas of the Southern Hemisphere : focus on the subantarctic marine boundary layer and on the Antarctic continent Angot, Hélène 07 November 2016 (has links) Le mercure (Hg) est un métal émis dans l’atmosphère par des sources naturelles et anthropiques. Il est préoccupant à l’échelle mondiale de par sa propagation atmosphérique sur de longues distances, loin des sources d’émissions, sa persistance dans l’environnement, son potentiel de bioaccumulation dans les chaînes alimentaires aquatiques et ses effets néfastes sur la santé humaine. Les modèles atmosphériques, utilisés pour retracer son cheminement depuis les sources d’émissions jusqu’aux dépôts au sein des écosystèmes, sont entachés de fortes incertitudes en raison notamment de notre compréhension partielle des processus atmosphériques (réactions d’oxydo-réduction, dépôts, réémissions) et du manque de données d’observations à l’échelle planétaire. L’objectif de ces travaux de thèse est d’améliorer notre compréhension du cycle atmosphérique du Hg en trois sites reculés de l’Hémisphère Sud : l’île d’Amsterdam (AMS) en plein océan Indien, Concordia (DC) sur la calotte glaciaire antarctique et Dumont d’Urville (DDU) sur la côte Est du continent. Les données acquises à AMS démontrent une réactivité atmosphérique limitée du Hg dans cette région du globe. L’île étant faiblement et rarement influencée par des masses d’air continentales polluées, il s’agit d’un site clé pour la surveillance, sur le long terme, du bruit de fond atmosphérique aux moyennes latitudes de l’Hémisphère Sud. Les données acquises en Antarctique démontrent l’existence de processus inédits en termes de réactivité dans l’atmosphère et à l’interface air-neige. Les processus observés sur la calotte glaciaire influent par ailleurs sur le cycle du Hg à l’échelle continentale du fait des forts vents catabatiques. Ces avancées scientifiques permettront, à terme, de contraindre et d’améliorer les modèles atmosphériques globaux. / Mercury (Hg) is a metal emitted by both natural and anthropogenic sources. It is of global concern owing to its long-range atmospheric transport, its persistence in the environment, its ability to bioaccumulate in ecosystems, and its negative effects on human health. Large uncertainties associated with atmospheric models – that trace the link from emissions to deposition of Hg onto environmental surfaces – arise as a result of our incomplete understanding of atmospheric processes (oxidation pathways, deposition, and re-emission) and of the scarcity of monitoring data at a global scale. The aim of this PhD work is to improve our understanding of the atmospheric Hg cycling at three remote sites of the Southern Hemisphere: Amsterdam Island (AMS) in the Indian Ocean, Concordia (DC) on the East Antarctic ice sheet, and Dumont d’Urville (DDU) on the East Antarctic coast. Data acquired at AMS suggest a limited atmospheric reactivity of Hg in this part of the globe. The advection of polluted continental air masses being scarce, AMS is a key site for the long-term monitoring of the atmospheric background in the Southern Hemisphere mid-latitudes. Data acquired in Antarctica highlight the occurrence of unprecedented processes in the atmosphere and at the air-snow interface. Due to katabatic winds flowing out from the East Antarctic ice sheet down the steep vertical drops along the coast, processes observed at DC influence the cycle of atmospheric Hg on a continental scale. These scientific breakthroughs will ultimately lead to improved global transport and deposition models. Mercure Cycle atmosphérique Hémisphère Sud Antarctique Couche limite marine subantarctique Mercury Atmospheric cycling Southern Hemisphere Antarctica Subantarctic marine boundary layer 550
17	Implementation and Analysis of Air-Sea Exchange Processes in Atmosphere and Ocean Modelling Carlsson, Björn January 2008 (has links) To understand and to predict the weather and climate, numerical models are important tools and it is crucial that the controlling processes are described correctly. Since 70% of the global surface is covered with water the description how the ocean and atmosphere communicates has a considerable impact. The ocean–atmosphere exchange occurs through transport of momentum (friction) and heat, governed by turbulent eddies. The sea surface is also an important source of turbulence in both directions. The scales of the turbulent eddies cannot be resolved in ocean and climate models. Therefore, the turbulent exchanges have to be related to mean variables, such as wind speed and temperature differences. By using measurements, new methods to describe the air–sea exchange during two specific processes were developed. These processes are the so-called UVCN-regime (Unstable Very Close to Neutral stratification) and swell, i.e. waves which are not produced by the local wind. These processes were included in an ocean model and in a regional atmospheric climate model and the impact was investigated. The UVCN-regime enhances the heat transport significantly during the autumn and winter months in the ocean model. This results in a shallower well-mixed surface layer in the ocean. Wind-following swell reduces the surface friction, which is very important for the atmosphere. Some secondary effects in the climate model are reduced low-level cloud cover and reduced precipitation by more than 10% over sea areas. Locally and for short periods the impact is large. It is important to include the UVCN-regime and the swell impact in models, to make simulations more reliable. Sensible heat flux Latent heat flux Momentum flux Wind stress Marine boundary layer Air–Sea interaction Swell Climate model Ocean model Roughness parameter Drag coefficient Wave breaking Meteorology Meteorologi
18	Fluxes and Mixing Processes in the Marine Atmospheric Boundary Layer Nilsson, Erik Olof January 2013 (has links) Atmospheric models are strongly dependent on the turbulent exchange of momentum, sensible heat and moisture (latent heat) at the surface. Oceans cover about 70% of the Earth’s surface and understanding the processes that control air-sea exchange is of great importance in order to predict weather and climate. In the atmosphere, for instance, hurricane development, cyclone intensity and track depend on these processes. Ocean waves constitute an obvious example of air-sea interaction and can cause the air-flow over sea to depend on surface conditions in uniquely different ways compared to boundary layers over land. When waves are generated by wind they are called wind sea or growing sea, and when they leave their generation area or propagate faster than the generating wind they are called swell. The air-sea exchange is mediated by turbulent eddies occurring on many different scales. Field measurements and high-resolution turbulence resolving numerical simulations have here been used to study these processes. The standard method to measure turbulent fluxes is the eddy covariance method. A spatial separation is often used between instruments when measuring scalar flux; this causes an error which was investigated for the first time over sea. The error is typically smaller over ocean than over land, possibly indicating changes in turbulence structure over sea. Established and extended analysis methods to determine the dominant scales of momentum transfer was used to interpret how reduced drag and sometimes net upward momentum flux can persist in the boundary layer indirectly affected by swell. A changed turbulence structure with increased turbulence length scales and more effective mixing was found for swell. A study, using a coupled wave-atmosphere regional climate model, gave a first indication on what impact wave mixing have on atmosphere and wave parameters. Near surface wind speed and wind gradients was affected especially for shallow boundary layers, which typically increased in height from the introduced wave-mixing. A large impact may be expected in regions of the world with predominant swell. The impact of swell waves on air-sea exchange and mixing should be taken into account to develop more reliable coupled Earth system models. Waves Growing sea Swell Marine boundary layer Air-sea interaction Mixing Momentum flux Wind stress Flux attenuation Sensor separation Large eddy simulation Multiresolution analysis Coupling Wave model Climate model Wave age

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