Your search keyword '"Isabel L. Pilotto"' showing total 3 results

1. Downscaling projections of climate change in Sao Tome and Principe Islands, Africa

Author

Sin Chan Chou, José Luiz Lima Onofre, Adérito Santana, Nicole Costa Resende, André Lyra, Daniel Andrés Rodriguez, Idalécio Major, Claudine Pereira Dereczynski, Jorge Gomes, Manuel Penhor, Priscila Tavares, Isabel L. Pilotto, Luís Felipe Alves de Carvalho, Minella Alves Martins, and Alessandro Marques Martins

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, Climate change, Representative Concentration Pathways, 010502 geochemistry & geophysics, 01 natural sciences, Climatology, Greenhouse gas, Environmental science, Spatial variability, Climate model, Precipitation, Sea level, 0105 earth and related environmental sciences, Downscaling

Abstract

Sao Tome and Principe is a small insular African country extremely vulnerable to rising sea levels and impacts such as inundation, shore line change, and salt water intrusion into underground aquifers. Projections of climate change have considered coarse model resolutions. The objective of this work is to dynamically downscale the global model projections to 4-km resolution and to assess the climate change in the Sao Tome and Principe islands. The global climate projections are provided by the Canadian Earth System Model under two Representative Concentration Pathways greenhouse gas scenarios, RCP4.5 and RCP8.5. The downscaling is produced by the Eta regional climate model. The baseline period is taken between 1971 and 2000, and the future climate period is taken between 2041 and 2070. The 2-m temperature simulations show good agreement with station data. The model simulates temperature more accurately than precipitation. The precipitation simulations systematically show underestimation and delay of the rainy and the dry seasons by about 1 month, a feature inherited from the global climate model. In the middle of the 21st century, projections show the strongest warming in the elevated parts of the Sao Tome Island, especially in February under RCP8.5. Warmer nights and warmer days become more frequent in the islands when compared with those in the present. While under RCP4.5, precipitation increases in the islands; under RCP8.5, it decreases everywhere in both islands. Heavy precipitation rates should increase, especially in the south-southwestern parts of the Sao Tome islands. Detailed spatial variability of the temperature and precipitation changes in the islands can only be revealed at very high spatial model resolution. Implications for the potential energy production from two major river basins are assessed in this work.

Published

2020

2. Assessment of Climate Change over South America under RCP 4.5 and 8.5 Downscaling Scenarios

Author

Sin Chan Chou, José A. Marengo, Jorge Gomes, Priscila Tavares, Isabel L. Pilotto, Josiane F. Bustamante, Diego Campos, Claudine Pereira Dereczynski, Caroline Mourão, Daniela Rodrigues, Gracielle Siqueira, André Lyra, Gustavo Sueiro, Adan Silva, and Diego Chagas

Subjects

Psychiatry and Mental health, Amazon rainforest, General Circulation Model, Climatology, Climate change, Environmental science, Climate model, Precipitation, Climate change assessment, Downscaling

Abstract

Four sets of downscaling simulations based on the Eta Regional Climate Model forced by two global climate models, the HadGEM2-ES and the MIROC5, and two RCP scenarios—8.5 and 4.5, have been carried out. The objective of this work is to assess the climate change over South America based on the Eta simulations. The future changes are shown in timeslices of 30 years: 2011-2040; 2041-2070 and 2071-2100. The climate change response of the Eta simulations nested in HadGEM2-ES is larger than the Eta nested in MIROC5. Major warming area is located in the central part of Brazil. In austral summer, the reduction of precipitation in the central part and the increase in the southeastern part of the continent are common changes in these simulations, while the EtaHadGEM2-ES intensifies the decrease of precipitation in central Brazil, the Eta-MIROC5 expands the area of increase of precipitation in southern Brazil toward the end of the century. In austral winter, precipitation decrease is found in the northern part of South America and in most of Central America, whereas the reduction in southeastern South America is limited to near coastal region. The time series of temperatures show that warming trends are larger in the Eta-HadGEM2-ES than in the Eta-MIROC5 simulations. Heavier precipitation rates are projected in the Central-South of Brazil toward the end of the century. Increase in the length of consecutive dry days (CDD) in Northeast of Brazil and the decrease of consecutive wet days (CWD) in the Amazon region are common features in these simulations.

Published

2014

3. Evaluation of the Eta Simulations Nested in Three Global Climate Models

Author

Diego Campos, Jorge Gomes, Sin Chan Chou, André Lyra, Claudine Pereira Dereczynski, Paulo Nobre, Adan Silva, Gracielle Siqueira, José A. Marengo, Priscila Tavares, Gustavo Sueiro, Isabel L. Pilotto, Caroline Mourão, Daniela Rodrigues, Diego Chagas, and Josiane F. Bustamante

Subjects

Psychiatry and Mental health, General Circulation Model, Climatology, Climate change, Environmental science, Cru, Climate model, Precipitation, Heat wave, Extreme value theory, Annual cycle, Atmospheric sciences

Abstract

To provide long-term simulations of climate change at higher resolution, Regional Climate Models (RCMs) are nested in global climate models (GCMs). The objective of this work is to evaluate the Eta RCM simulations driven by three global models, the HadGEM2-ES, BESM, and MIROC5, for the present period, 1961-1990. The RCM domain covers South America, Central America, and Caribbean. These simulations will be used for assessment of climate change projections in the region. Maximum temperatures are generally underestimated in the domain, in particular by MIROC5 driven simulations, in summer and winter seasons. Larger spread among the simulations was found in the minimum temperatures, which showed mixed signs of errors. The spatial correlations of temperature simulations against the CRU observations show better agreement for the MIROC5 driven simulations. The nested simulations underestimate precipitation in large areas over the continent in austral summer, whereas in winter overestimate occurs in southern Amazonia, and underestimate in southern Brazil and eastern coast of Northeast Brazil. The annual cycle of the near-surface temperature is underestimated in all model simulations, in all regions in Brazil, and in most of the year. The temperature and precipitation frequency distributions reveal that the RCM and GCM simulations contain more extreme values than the CRU observations. Evaluations of the climatic extreme indicators show that in general hot days, warm nights, and heat waves are increasing in the period, in agreement with observations. The Eta simulations driven by HadGEM2-ES show wet trends in the period, whereas the Eta driven by BESM and by MIROC5 show trends for drier conditions.

Published

2014