Projeccions climàtiques per a Catalunya

Aquest capítol té com a objectiu donar respostes a les qüestions següents: d'una banda, descriure projeccions climàtiques més detallades per a Catalunya i, d’altra banda, donar aquestes projeccions per a escenaris temporals més immediats. Atès que no es tractava en aquest informe de generar nous resultats com a conseqüència de nova activitat investigadora, la metodologia seguida ha estat, com en els capítols anteriors, la revisió bibliogràfica i documental d’articles i informes publicats fins avui. En concret, el principal document que s’ha utilitzat és l’informe titulat Generación de escenarios regionalizados de cambio climático para España (INM, 2007), que ha estat elaborat recentment per l'Institut Nacional de Meteorologia espanyol (actualment, Agència Estatal de Meteorologia, AEMET). Les principals tècniques de regionalització i els resultats més destacats d’aquest document es resumiranen els propers apartats. També hem emprat altres articles publicats en revistes científiques, en molts casos derivats del projecte Prudence, que permeten deduir algun resultat aplicable a Catalunya. Finalment, s’ha fet l'esforç d’integrar tota la informació obtinguda sobre les projeccions climàtiques a diferents escales, per resumir-la en un quadre que indiqui quins són els rangs esperats d'augment de la temperatura i de canvis de la precipitació, per a Catalunya i en tres àrees diferenciades (litoral, interior i Pirineu). En el mateix quadre donem valors corresponents a finals del segle xxi i, també, per al primer terç d'aquest segle. Avancem ja ara que l'elaboració d'aquest resum no ha seguit una metodologia quantitativa o estadística, sinó que s'ha fetintegrant de manera qualitativa (i, per tant, no exempta d’una certa subjectivitat) tot el coneixement dels autors, que correspon en principi a l’estat de la qüestió en cercles científics

Horizontal Grid Size Selection and its Influence on Mesoscale Model Simulations

The use of two-dimensional spectral analysis applied to terrain heights in order to determine characteristic terrain spatial scales and its subsequent use for the objective definition of an adequate grid size required to resolve terrain forcing are presented in this paper. In order to illustrate the influence of grid size, atmospheric flow in a complex terrain area of the Spanish east coast is simulated by the Regional Atmospheric Modeling System (RAMS) mesoscale numerical model using different horizontal grid resolutions. In this area, a grid size of 2 km is required to account for 95% of terrain variance. Comparison among results of the different simulations shows that, although the main wind behavior does not change dramatically, some small-scale features appear when using a resolution of 2 km or finer. Horizontal flow pattern differences are significant both in the nighttime, when terrain forcing is more relevant, and in the daytime, when thermal forcing is dominant. Vertical structures also are investigated, and results show that vertical advection is influenced highly by the horizontal grid size during the daytime period. The turbulent kinetic energy and potential temperature vertical cross sections show substantial differences in the structure of the planetary boundary layer for each model configuration

A Method for Sky-Condition Classification from Ground-Based Solar Radiation Measurements

Identification of clouds from satellite images is now a routine task. Observation of clouds from the ground, however, is still needed to acquire a complete description of cloud conditions. Among the standard meteorologicalvariables, solar radiation is the most affected by cloud cover. In this note, a method for using global and diffuse solar radiation data to classify sky conditions into several classes is suggested. A classical maximum-likelihood method is applied for clustering data. The method is applied to a series of four years of solar radiation data and human cloud observations at a site in Catalonia, Spain. With these data, the accuracy of the solar radiation method as compared with human observations is 45% when nine classes of sky conditions are to be distinguished, and it grows significantly to almost 60% when samples are classified in only five different classes. Most errors are explained by limitations in the database; therefore, further work is under way with a more suitable database

Analytical investigation of the atmospheric radiation limits in semigray atmospheres in radiative equilibrium

We model the wavelength-dependent absorption of atmospheric gases by assuming constant mass absorption coefficients in finite-width spectral bands. Such a semigray atmosphere is analytically solved by a discrete ordinate method. The general solution is analyzed for a water vapor saturated atmosphere that also contains a carbon dioxide-like absorbing gas in the infrared. A multiple stable equilibrium with a relative upper limit in the outgoing long-wave radiation is found. Differing from previous radiative–convective models, we find that the amount of carbon dioxide strongly modifies the value of this relative upper limit. This result is also obtained in a gray (i.e., equal absorption of radiation at all infrared wavelengths) water vapor saturated atmosphere. The destabilizing effect of carbon dioxide implies that massive carbon dioxide atmospheres are more likely to reach a runaway greenhouse state than thin carbon dioxide ones

Impacts of climate change on water resources in the Mediterranean basin : a case study in Catalonia, Spain

Most climate change projections show important decreases in water availability in the Mediterranean region by the end of this century. We assess those main climate change impacts on water resources in three medium-sized catchments with varying climatic conditions in north-eastern Spain. A combination of hydrological modelling and climate projections with B1 and A2 IPCC emission scenarios is performed to infer future stream flows. The largest reduction (22-48% for 2076-2100) of stream flows is expected in the headwaters of the two wettest catchments, while lower decreases (22-32% for 2076-2100) are expected in the drier one. In all three catchments, autumn and summer are the seasons with the most notable projected decreases in stream flow, 50% and 34%, respectively (2076-2100). Thus, ecological flows might be noticeably impacted by climate change in the catchments, especially in the headwaters of those wet catchments.