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Atmospheric carbon dioxide concentration has increased globally from about 280 ppm before the Industrial Revolution (Pearman 1988) to about 353 ppm in 1990. That increase, and the continuing increase at a rate of about 1.5 ppm per annum, owing mainly to fossil fuel burning, is likely to cause change in climate, in primary productivity of terrestrial vegetation (managed and unmanaged), and in the degree of net sequestration of atmospheric CO into organic form. The quantitative role 2 of the latter in attenuating the increase in atmospheric CO concentration itself is 2 an important but uncertain element of the global carbon-cycle models that are required to predict future increases of atmospheric CO concentration. 2 In my experience in workshops and other multidisciplinary gatherings, argument arises in discussion of this topic among different groups of scientists such as bioclimatologists, plant physiologists, biogeochemists and ecologists. Plant concentration physiologists are often impressed by the positive effect of higher CO 2 on plant growth under experimental controlled environments and argue that this would be at least partly expressed in the field for many species and communities.
r-------------{ Environment (Disease) Fig. 1. A schematic presentation of the interplay between the external environment, pathogen and animal, which influences resistance to infectious disease. Disturbance in equilibrium results in infection and disease skin and the mucous membranes of the respiratory tract. These tissues are in contact with the environment, and direct injury to them facilitate entry of pathogenic microorganisms through these important natural barriers. Sunburn and frostbite are examples of such adverse effects. Climatic factors such as heat and cold may also act as physiological stress factors which affect the specific and non-specific responses of the body to infection. 1.1.2 Pathogen Survival Climatic factors may affect dispersal, spread and survival of pathogenic micro organisms in the environment. This is also true for arthropod vectors such as mosquitos and ticks (Smith 1970; Ferguson and Branagan 1972). The density of the animal population is an important factor determining the concentration of patho gens in the environment. Population density can be influenced by weather condi tions, as animals respond to heat and cold by typical changes in behaviour. For example, in cold weather they tend to huddle together. This behaviour results in increased population density, which in turn involves an increased risk of the spread of airborne infections.
This volume contains reviews on five different aspects of bioclimatology: (1) The establishment, maintenance and use of data from automatic weather station networks for agricultural purposes; (2) Techniques for estimating global and ultraviolet irradiance at the earth's surface, and the net radiation balance from operational satellite observations; (3) Mathematical models of the effects of climate on energy and mass balance in crop production; (4) Paleoecological and experimental studies of the response of stomatal density to changes in the atmospheric CO2 concentrations; and (5) The sensory and behavioral responses of insects and other invertebrates to small CO2 gradients resulting from plant and animal metabolism, considering the global changes in CO2 concentration and air temperature.
A. AULICIEMS Living organisms respond to atmospheric variability and variation, and over time morphological and process differentiations occur both within individuals and the species, as well as in the environment itself. In systems language, the concern is with the atmospheric process-response system of energy and matter flows within the biosphere. The study of such interactions between living organ isms and the atmospheric environment falls within the field of bioclimatology, alternatively referred to as biometeorology. Amongst the more readily recognizable study areas under the bioclimatolog that investigate the effects of atmospheric variation and ical umbrella are those variability upon 1. Terrestrial and aquatic ecology (zoological, botanical and ethological), natural resource production and management (including silviculture, agri culture, horticulture, and grassland, wetland, and marine systems). 2. Stress, morbidity and mortality in animals and humans (including physiolog ical and psychological adaptations). 3. The built environment (all aspects of planning, urban design, and architec ture). 4. Economic systems and social activities (including organizational, individual, and group behavior and management). In addition, bioclimatology is very much concerned with the feedback loop, that is both 5. The inadvertent modification of the atmosphere by living systems, especially human, i.e., studies of pollution, changes to atmospheric amenity, and the processes of deterioration of landscape (deforestation and desertification), and 6. The advertent modifications of natural energy and matter flows within urban areas and indoor climate constructions.
This book essentially comprises the proceedings of the 11th International Conference of Meteorology, Climatology and Atmospheric Physics (COMECAP 2012) that is held in Athens from 30 May to 1 June 2012. The Conference addresses researchers, professionals and students interested in the following topics: Agricultural Meteorology and Climatology, Air Quality, Applied Meteorology and Climatology, Applications of Meteorology in the Energy Sector, Atmospheric Physics and Chemistry, Atmospheric Radiation, Atmospheric Boundary Layer, Biometeorology and Bioclimatology, Climate Dynamics, Climatic Changes, Cloud Physics, Dynamic and Synoptic Μeteorology, Extreme Events, Hydrology and Hydrometeorology, Mesoscale Meteorology, Micrometeorology/Urban Microclimate, Remote Sensing/ Satellite Meteorology and Climatology, Weather Analysis and Forecasting. The book includes all papers that have been accepted for presentation at the conference.
This book focuses on various psycho-social and socio-physical aspects of climate change and includes a wide range of case studies. Included topics are notable climate-related social thinking; climate vulnerability; transformation in socio-ecological subsystems; bioclimatological, urban bioclimatological and socio-bioclimatic ideas; disasters; policy instruments; climate justice; human rights; and sustainability. The book distinguishes itself from similar works by including a wide variety of topics and assists policy management in the current and upcoming climate crisis era. This book also addresses the Sustainable Development Goals 13 (Take Urgent Action to Combat Climate Change and Its Impacts), highlighting resilience, recovery potential and adaptive capacity, climate change measures integrated into policies and planning, and knowledge and capacity to mitigate climate change. The ideas covered in this book evolved in response to the current climate crisis, ideas that the authors believe will aid in societal management and development in the present and future. The book is a useful source for planners, geographers, professionals, academics, government officials, laypeople, and others interested in climate change.
Natural Resources Conservation and Advances for Sustainability addresses the latest challenges associated with the management and conservation of natural resources. It presents interdisciplinary approaches to promote advances in solving these challenges. By examining what has already been done and analyzing it in the context of what still needs to be done, particularly in the context of latest technologies and sustainability, the book helps to identify ideal methods for natural resource management and conservation. Each chapter begins with a graphical abstract and presents complicated or detailed content in the form of figures or tables. In addition, the book compares the latest techniques with conventional techniques and troubleshoots conventional methods with modifications, making it a practical resource for researchers in environmental science and natural resource management. - Discusses the pros and cons of past and current endeavors related to natural resource management - Presents recent technologies and methods for management and conservation, particularly with applications for sustainability - Covers a variety of disciplines, from environmental science to life science - Includes a graphical abstract as well as a section on significant achievements in the field and future perspectives
Presenting the latest research on the effects of cold and sub-zero temperatures on plant distribution, growth and yield, this comprehensive volume contains 28 chapters by international experts covering basic molecular science to broad ecological studies on the impact of global warming, and an industry perspective on transgenic approaches to abiotic stress tolerance. With a focus on integrating molecular studies in the laboratory with field research and physiological studies of whole plants in their natural environments, this book covers plant physiology, production, development, agronomy, ecology, breeding and genetics, and their applications in agriculture and horticulture. Global Analysis of Gene Networks to Solve Complex Abiotic Stress responses, K Shinozaki, RIKEN Tsukuba Institute, Japan and K Yamaguchi-Shinozaki, Japan International Research Center for Agricultural Sciences, Japan, The CBF Cold Response Pathways of Arabidopsis and Tomato, J T Vogel, Michigan State University, USA, D Cook, Mississippi State University, USA, S G Fowler and M F Thomashow, Michigan State University, USA, Barley Contains a Large CBF Gene Family Associated with Quantitative Cold Tolerance Traits, J S Skinner, J von Zitzewitz, L Marquez-Cedillo, T Filichkin, Oregon State University, USA, P Szucs, Agricultural Research Institute of the Hungarian Academy of Sciences, Hungary, K Amundsen, Michigan State University, USA, E Stockinger, Ohio State University, USA, M F Thomashow, Michigan State University, USA, T H H Chen, and P M Hayes, Oregon State University, USA, Structural Organization of Barley CBF Genes Coincident with QTLS for Cold Hardiness , E J Stockinger, H Cheng, Chinese Academy of Agricultural Sciences, China and J Skinner, The genetic basis of vernalization response in barley, L L D Cooper, Oregon State University, USA, J von Zitzewitz, J S Skinner, P Szucs, I Karsai, Agriculturtal Research Institute of the Hungarian Academy of Sciences, Hungary, E Francia, A M Stanca, Experimental Institute for Cereal Resources, Italy, N Pecchioni, Universita di Modena e Reggio Emilia, Italy, D A Laurie, John Innes Research Centre, UK, T H H Chen, and P M Hayes, Vernalization Genes in Winter Cereals, N A Kane, J Danyluk, and F Sarhan, Universite du Quebec a Montreal, Canada, A Bulk Segregant Approach to Identify Genetic Polymorphisms Associated with Cold Tolerance in Alfalfa, Y Castonguay, J Cloutier, S Laberge, A Bertrand and R Michaud, Agriculture and Agri-Food Canada, Canada, Ectopic Over-expression of AtCBF1 in Potato Enhances Freezing Tolerance, M T Pino, J S Skinner, Z Jeknic, E J Park, Oregon State University, USA, P M Hayes, and T H H Chen, Over-expression of a Heat-inducible apx Gene Confers Chilling Tolerance to Rice Plants, Y Sato, National Agricultural Research Center for Hokkaido Region, Japan, and H Saruyama, Hokkaido Green-Bio Institute, Japan Physiological and Morphological Alterations Associated with Development of Freezing Tolerance in The Moss Physcomitrella patens, A Minami, M Nagao, Iwate University, Japan, K Arakawa, S Fujikawa, Hokkaido University and D Takezawa, Saitama University, Japan, Control of Growth and Cold Acclimation in Silver Birch, M K Aalto and E T Palva, Viikki Biocenter, Finland, The Role of the CBF-Dependent Signalling Pathway in Woody Perennials, C Benedict, Umea University, Sweden, J S Skinner, R Meng, Y Chang, Oregon State University, USA, R Bhalerao, Swedish University of Agricultural Sciences, Sweden, C Finn, USDA-ARS, USA, T H H Chen, V Hurry, Umea University, Sweden, Functional Role of Winter-accumulating Proteins from Mulberry Tree in adaptation to Winter-induced Stresses, S Fujikawa, N Ukaji, Hokkaido University, Japan, M Nagao, K Yamane, Hokkaido University, Japan, D Takezawa, and K Arakawa, The Role of Compatible Solutes in Plant Freezing Tolerance: A Case Study on Raffinose, D K Hincha, E Zuther, M Hundertmark, A G Heyer, Max-Planck-Institut fur Molekulare Pflanzenphysiologie, Germany, Dehydration in model membranes and protoplasts: contrasting effects at low, intermediate and high hydrations, K L Koster, University of South Dakota,USA, and G Bryant, RMIT University, Australia, Effect of Plasma Membrane-associated Proteins on Acquisition of Freezing Tolerance in Arabidopsis thaliana, Y Tominaga, Universite du Quebec a Montreal, Canada, C Nakagawara, Y Kawamura and M Uemura, Iwate University, Japan