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Author: Danielle Elie Touma Publisher: ISBN: Category : Languages : en Pages :
Book Description
Drought and extreme precipitation events lead to devastating damages to human and natural systems. The characteristics of these extreme climate events, including the frequency, intensity, and spatial extent of extreme wet conditions or extreme dry conditions can shape the risk posed to a region by an event. There has been substantial evidence that global warming has altered and will continue to alter atmospheric, land, and ocean conditions, which in turn lead to changes in the characteristics of extreme climate events. Additional anthropogenic emissions are expected to modify the ocean, land, and atmosphere in the future, though the role that these changes will have on future extreme precipitation and drought events is still uncertain. In my dissertation, I employ a multitude of observed and modeled climate datasets available to quantify the characteristics of drought and extreme wet events under past and future anthropogenic warming. By systematically quantifying the intensity, frequency, duration and spatial extent of extreme climate events across datasets, I aim to provide a climatological assessment of extreme climate event characteristics, and identify spatial or temporal variations of these characteristics. The findings from this dissertation will allow further insight into the impact past and future global warming have on extreme climate events, and subsequently, the risks to human and natural systems. In my first chapter, I investigate the expected changes in the frequency, duration, and spatial extent of drought over the globe in the 21st century under increased anthropogenic warming. To capture drought index-based uncertainty, I calculate four different drought indices which use precipitation, runoff, and moisture deficit, and to capture model-based uncertainty, I use climate simulations from 15 global climate models (GCMs) in the CMIP5 database. By comparing drought characteristics in the historical (1961-2005) simulations to the RCP 8.5 scenario (2010-2099) simulations, I show increases in the frequency and spatial extent of drought over the 21st century. These increases over the tropics and subtropics, reaching 80 more percentage points in the spatial extent and 40 more drought events, are robust among climate models when using deficit-based drought indices, but less robust when using precipitation or runoff-based indices. Given that deficit-based indices directly account for variations in temperature, these indices capture the significant increases in temperature simulated under high levels of anthropogenic emissions throughout the 21st century. These findings suggest that there is an increasing risk in drought stresses in many regions given the current trajectory of greenhouse gas emissions and associated warming temperatures. In my second chapter, I develop a geostatistical method to assess the spatial extent, or length scales, of extreme precipitation in GCHN-D station data. A climatological assessment over the US from 1965-2014 reveals significant seasonal and regional variations in the length scales of extreme daily precipitation. The eastern half of the US has daily extreme precipitation length scales reaching 400km during the winter months, but the length scales are halved during the summer months. The Northwest region, on the other hand, has little seasonal variation, with short extreme precipitation length scales of approximately 150km year-round. Though the magnitude of extreme precipitation length scales can be sensitive to certain choices in my method, the seasonal and regional variations remain relatively intact and can plausibly be explained by well-known atmospheric phenomena. This chapter introduces a valuable framework that can be used to quantify changes in the spatial extents of extreme climate events in the US and globally, and examine the impacts of varying spatial extents of extreme precipitation events on human and natural systems. In my third chapter, I use the geostatistical method I developed in my second chapter to quantify the intensity and length scales of tropical cyclone precipitation (TCP) along US-landfalling Atlantic tropical cyclone tracks from 1900-2017. Using GHCN-D precipitation station data and HURDAT2 tropical cyclone track data, I find significant variations in TCP intensity and length scales across different tropical cyclone strengths. TCP intensity and length scales are largest along major hurricane tracks. The highest values of TCP intensity (more than 150 mm/day) are found along major hurricane tracks, and the TCP intensity distribution is shifted positively during the weaker phases along the tracks. During these weaker phases, I also find the longest TCP length scales. However, the longest length scales of extreme TCP (> 75 mm/day) are found during the strongest phases. TCP intensity and length scales are significantly smaller along tropical storm and minor hurricane tracks. I also find varied changes in TCP intensity and length scales between the first and second halves of the 20th century. The upper quartiles of minor hurricane and tropical storm TCP intensity have significantly increased, alongside significant increases in the extent of extreme TCP. The intensity and extent of extreme TCP during major hurricanes have significantly decreased. The climatology of TCP intensity and length scales can be linked to the strength, speed, and symmetry of a tropical cyclone, as well as interactions with the land surface and topography. Moreover, the changes in TCP intensity and length scales can be explained by changes in precipitable water and vertical wind shear. This chapter provides important insights into the intensity and spatial extent of precipitation across different tropical cyclone strengths, allowing us to better understand the possible changes in TCP under future global warming. Taken together, these chapters advance our understanding of the risks posed by extreme climate events, and inform future research directions in this area of climate science. Given that these events cause severe losses to communities and their surrounding ecosystems, it is imperative that we advance our ability to address the effects of extreme climate events.
Author: Danielle Elie Touma Publisher: ISBN: Category : Languages : en Pages :
Book Description
Drought and extreme precipitation events lead to devastating damages to human and natural systems. The characteristics of these extreme climate events, including the frequency, intensity, and spatial extent of extreme wet conditions or extreme dry conditions can shape the risk posed to a region by an event. There has been substantial evidence that global warming has altered and will continue to alter atmospheric, land, and ocean conditions, which in turn lead to changes in the characteristics of extreme climate events. Additional anthropogenic emissions are expected to modify the ocean, land, and atmosphere in the future, though the role that these changes will have on future extreme precipitation and drought events is still uncertain. In my dissertation, I employ a multitude of observed and modeled climate datasets available to quantify the characteristics of drought and extreme wet events under past and future anthropogenic warming. By systematically quantifying the intensity, frequency, duration and spatial extent of extreme climate events across datasets, I aim to provide a climatological assessment of extreme climate event characteristics, and identify spatial or temporal variations of these characteristics. The findings from this dissertation will allow further insight into the impact past and future global warming have on extreme climate events, and subsequently, the risks to human and natural systems. In my first chapter, I investigate the expected changes in the frequency, duration, and spatial extent of drought over the globe in the 21st century under increased anthropogenic warming. To capture drought index-based uncertainty, I calculate four different drought indices which use precipitation, runoff, and moisture deficit, and to capture model-based uncertainty, I use climate simulations from 15 global climate models (GCMs) in the CMIP5 database. By comparing drought characteristics in the historical (1961-2005) simulations to the RCP 8.5 scenario (2010-2099) simulations, I show increases in the frequency and spatial extent of drought over the 21st century. These increases over the tropics and subtropics, reaching 80 more percentage points in the spatial extent and 40 more drought events, are robust among climate models when using deficit-based drought indices, but less robust when using precipitation or runoff-based indices. Given that deficit-based indices directly account for variations in temperature, these indices capture the significant increases in temperature simulated under high levels of anthropogenic emissions throughout the 21st century. These findings suggest that there is an increasing risk in drought stresses in many regions given the current trajectory of greenhouse gas emissions and associated warming temperatures. In my second chapter, I develop a geostatistical method to assess the spatial extent, or length scales, of extreme precipitation in GCHN-D station data. A climatological assessment over the US from 1965-2014 reveals significant seasonal and regional variations in the length scales of extreme daily precipitation. The eastern half of the US has daily extreme precipitation length scales reaching 400km during the winter months, but the length scales are halved during the summer months. The Northwest region, on the other hand, has little seasonal variation, with short extreme precipitation length scales of approximately 150km year-round. Though the magnitude of extreme precipitation length scales can be sensitive to certain choices in my method, the seasonal and regional variations remain relatively intact and can plausibly be explained by well-known atmospheric phenomena. This chapter introduces a valuable framework that can be used to quantify changes in the spatial extents of extreme climate events in the US and globally, and examine the impacts of varying spatial extents of extreme precipitation events on human and natural systems. In my third chapter, I use the geostatistical method I developed in my second chapter to quantify the intensity and length scales of tropical cyclone precipitation (TCP) along US-landfalling Atlantic tropical cyclone tracks from 1900-2017. Using GHCN-D precipitation station data and HURDAT2 tropical cyclone track data, I find significant variations in TCP intensity and length scales across different tropical cyclone strengths. TCP intensity and length scales are largest along major hurricane tracks. The highest values of TCP intensity (more than 150 mm/day) are found along major hurricane tracks, and the TCP intensity distribution is shifted positively during the weaker phases along the tracks. During these weaker phases, I also find the longest TCP length scales. However, the longest length scales of extreme TCP (> 75 mm/day) are found during the strongest phases. TCP intensity and length scales are significantly smaller along tropical storm and minor hurricane tracks. I also find varied changes in TCP intensity and length scales between the first and second halves of the 20th century. The upper quartiles of minor hurricane and tropical storm TCP intensity have significantly increased, alongside significant increases in the extent of extreme TCP. The intensity and extent of extreme TCP during major hurricanes have significantly decreased. The climatology of TCP intensity and length scales can be linked to the strength, speed, and symmetry of a tropical cyclone, as well as interactions with the land surface and topography. Moreover, the changes in TCP intensity and length scales can be explained by changes in precipitable water and vertical wind shear. This chapter provides important insights into the intensity and spatial extent of precipitation across different tropical cyclone strengths, allowing us to better understand the possible changes in TCP under future global warming. Taken together, these chapters advance our understanding of the risks posed by extreme climate events, and inform future research directions in this area of climate science. Given that these events cause severe losses to communities and their surrounding ecosystems, it is imperative that we advance our ability to address the effects of extreme climate events.
Author: Nishadi Eriyagama Publisher: IWMI ISBN: 9290907118 Category : Droughts Languages : en Pages : 36
Book Description
The study examines the global pattern and impacts of droughts through mapping several drought-related characteristics - either at a country level or at regular grid scales. It appears that arid and semi-arid areas also tend to have a higher probability of drought occurrence. It is illustrated that the African continent is lagging behind the rest of the world on many indicators related to drought-preparedness and that agricultural economies, overall, are much more vulnerable to adverse societal impacts of meteorological droughts. The study also examines the ability of various countries to satisfy their water needs during droughts using storage-related indices.
Author: Assefa Melesse Publisher: Elsevier ISBN: 0128159995 Category : Science Languages : en Pages : 584
Book Description
Extreme Hydrology and Climate Variability: Monitoring, Modelling, Adaptation and Mitigation is a compilation of contributions by experts from around the world who discuss extreme hydrology topics, from monitoring, to modeling and management. With extreme climatic and hydrologic events becoming so frequent, this book is a critical source, adding knowledge to the science of extreme hydrology. Topics covered include hydrometeorology monitoring, climate variability and trends, hydrological variability and trends, landscape dynamics, droughts, flood processes, and extreme events management, adaptation and mitigation. Each of the book's chapters provide background and theoretical foundations followed by approaches used and results of the applied studies. This book will be highly used by water resource managers and extreme event researchers who are interested in understanding the processes and teleconnectivity of large-scale climate dynamics and extreme events, predictability, simulation and intervention measures. - Presents datasets used and methods followed to support the findings included, allowing readers to follow these steps in their own research - Provides variable methodological approaches, thus giving the reader multiple hydrological modeling information to use in their work - Includes a variety of case studies, thus making the context of the book relatable to everyday working situations for those studying extreme hydrology - Discusses extreme event management, including adaption and mitigation
Author: Intergovernmental Panel on Climate Change Publisher: Cambridge University Press ISBN: 1107025060 Category : Business & Economics Languages : en Pages : 593
Book Description
Extreme weather and climate events, interacting with exposed and vulnerable human and natural systems, can lead to disasters. This Special Report explores the social as well as physical dimensions of weather- and climate-related disasters, considering opportunities for managing risks at local to international scales. SREX was approved and accepted by the Intergovernmental Panel on Climate Change (IPCC) on 18 November 2011 in Kampala, Uganda.
Author: Hans von Storch Publisher: Cambridge University Press ISBN: 1139425099 Category : Science Languages : en Pages : 979
Book Description
Climatology is, to a large degree, the study of the statistics of our climate. The powerful tools of mathematical statistics therefore find wide application in climatological research. The purpose of this book is to help the climatologist understand the basic precepts of the statistician's art and to provide some of the background needed to apply statistical methodology correctly and usefully. The book is self contained: introductory material, standard advanced techniques, and the specialised techniques used specifically by climatologists are all contained within this one source. There are a wealth of real-world examples drawn from the climate literature to demonstrate the need, power and pitfalls of statistical analysis in climate research. Suitable for graduate courses on statistics for climatic, atmospheric and oceanic science, this book will also be valuable as a reference source for researchers in climatology, meteorology, atmospheric science, and oceanography.
Author: Martin Beniston Publisher: Springer Science & Business Media ISBN: 0306479834 Category : Science Languages : en Pages : 507
Book Description
year simulations in order to separate noise in the system from the climate change signal. Several contributing papers focused on case studies using Regional Climate Models (RCMs) linked to hydrological models, applied to the analysis of runoff under conditions of convective activity and extreme precipitation, in regions of complex topography, or stakeholder-driven investigations such as water runoff simulations in Quebec undertaken for a major utility. Thorough analyses of GCM results for the Century were reported at the Workshop, in order to illustrate the improvements in model results which have taken place in recent years, and the increasing confidence with which the models can be used for projecting climatic change in coming decades. However, there is still much room for improvement; there is also a need to address more fully the manner in which climate and impacts models (e. g. , hydrological models) can be linked, in terms of consistency and the overlap between different scales, the underlying physical assumptions, and the parameterizations used. Session 2 was devoted to the two extremes of water resources, namely floods and droughts, the focus here being to identify the climate change component in river floods. These have significant economic implications, as was shown by several scientists from Western and Central Europe. Many long time series have been studied worldwide with the aim of detection of nonstationarities, yet there is no conclusive evidence of climate-related changes in flow records, in general.
Author: National Academies of Sciences, Engineering, and Medicine Publisher: National Academies Press ISBN: 0309380979 Category : Science Languages : en Pages : 187
Book Description
As climate has warmed over recent years, a new pattern of more frequent and more intense weather events has unfolded across the globe. Climate models simulate such changes in extreme events, and some of the reasons for the changes are well understood. Warming increases the likelihood of extremely hot days and nights, favors increased atmospheric moisture that may result in more frequent heavy rainfall and snowfall, and leads to evaporation that can exacerbate droughts. Even with evidence of these broad trends, scientists cautioned in the past that individual weather events couldn't be attributed to climate change. Now, with advances in understanding the climate science behind extreme events and the science of extreme event attribution, such blanket statements may not be accurate. The relatively young science of extreme event attribution seeks to tease out the influence of human-cause climate change from other factors, such as natural sources of variability like El Niño, as contributors to individual extreme events. Event attribution can answer questions about how much climate change influenced the probability or intensity of a specific type of weather event. As event attribution capabilities improve, they could help inform choices about assessing and managing risk, and in guiding climate adaptation strategies. This report examines the current state of science of extreme weather attribution, and identifies ways to move the science forward to improve attribution capabilities.
Author: Josiah Daniel Smith Publisher: ISBN: Category : Drought forecasting Languages : en Pages : 202
Book Description
Abstract: The Prairie Pothole Region in the Northern Great Plains (PPR-NGP) of the United States frequently fluctuates from drought to deluge. The historical hydrologic record for this region reveals periods of intense, prolonged drought intermingled with rapid and destructive flooding. Drought or flooding is initiated and sustained by deficit or surplus precipitation, respectively. The weather events that accompany these disasters are characterized by large spatial and temporal variations from normal in the frequency and intensity. The unique hydrology and geology of the region makes the PPR-NGP highly sensitive to these weather perturbations. The future looks to bring more warming and thus more intense precipitation to the region. As the frequency of extreme precipitation events rises, the magnitude and occurrence of floods and droughts will be elevated. The objective of this research was to determine the factors controlling precipitation trends, drought, and flooding in the study area. Also, the weather conditions preceding the disastrous events were observed and characterized. The analysis was focused on the effects of varying precipitation intensity, frequency, and antecedent conditions as they pertain to PPR-NGP drought and Red River flooding. The results may be applied to better predict the future trends of flood and drought response to extreme precipitation. Data mining was performed on available weather station observations to extract significant information and use it to derive valuable insight into PPR-NGP drought and flooding behavior. Hydrometeorological indices calculated over various timescales were applied to assess the intensity and frequency of rainfall, the change in snow depths, and the deviation from normal precipitation. Flood discharge hydrographs were classified based on shape parameters and matched to precipitation characteristics. Spatiotemporal and statistical operations were employed to determine the controlling factors of precipitation trends, drought, summer floods, and spring floods in the PPR-NGP and Red River Basin. Current precipitation and stream flow trends indicate the potential for enhanced flood and drought activity. Precipitation intensity and frequency are ascending, but the intensity is increasing more than the frequency of monthly events. The result is that Red River discharge rates are rising six times faster than total precipitation over the basin. The rise in stream flow rates can be explained by elevated precipitation intensity and to some extent precipitation frequency during key flood months. However, the most critical flood month of April has a decreasing total precipitation trend and yet the highest rise in discharge rate. These trends come about because overall fall and winter precipitation rates are on the rise. The antecedent precipitation is stored on and in the frozen ground until released by the spring thaw, which usually takes place in April. Thus, the risk for larger April floods is affected not by a single month but by a half year's worth of increasing precipitation conditions. Large fluctuations in monthly drought conditions were determined to be equally controlled by both the frequency and intensity of precipitation events. Extreme drought took a minimum of two to three months both to develop and dissipate from a semi-arid state. Though, the biggest shifts in month-to-month conditions were observed when both precipitation intensity and frequency were well above or below normal over the same area. So the onset or end of an extreme drought took place more rapidly when the intensity and frequency changes were great and harmonized. Similarly, the spatial extent of the most intense (on average) drought cells was surprisingly little, because the overlap of large precipitation intensity and frequency shifts typically occurred over a small area. Also, the drought duration usually increased when severity reached a higher level, so that multiple months of moderate drought reduced the overall intensity for all but the most severe parts of the cells. The intensity of precipitation events was the main controlling factor in Red River summer flood occurrence and magnitude. Antecedent conditions were not essential to the development of summer floods. Conditions were often near normal prior to a flood because more of the normal rain fell in a fewer number of more intense events. Conversely, the magnitude and occurrence of spring floods was controlled by antecedent precipitation and fast snow melt rates. A significant snow pack was observed prior to both major and minor floods, while a non-flood year had little snow pack over the basin. Fall soil moisture, winter snowfall, and a fast rate of stored water release all had to be present at sufficient levels to trigger a large flood response.
Author: Danielle Elie Touma
Author: Danielle Elie Touma
Author: Nishadi Eriyagama
Author: Assefa Melesse
Author: Lena M. Tallaksen
Author: Intergovernmental Panel on Climate Change
Author: Justin Sheffield
Author: Hans von Storch
Author: Martin Beniston
Author: National Academies of Sciences, Engineering, and Medicine
Author: Josiah Daniel Smith