用MRI-AGCM模拟中美洲未来气候变化:气候类似物研究

IF 0.6 Q4 WATER RESOURCES
Reinhardt Pinzón, K. Hibino, I. Takayabu, T. Nakaegawa
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引用次数: 11

摘要

利用气象研究所大气环流模式(MRI-AGCM)进行了24次模拟,预测了《排放情景特别报告》情景A1B下21世纪后期的气候。使用最近开发的非参数方法确定了中美洲首都城市的未来气候类似物。我们使用水平分辨率约为60 km的MRI-AGCM3.2H, 3种对流方案,4种海面温度分布和2种初始条件。因此,总群落大小为24,模拟周期为25年。大多数未来的类似物都位于比目标城市更低的纬度,或者靠近生物多样性和地方性热点,如珊瑚礁和红树林。预测的巴拿马城地表气温和降雨量的季节变化与位于越南湄公河河口的Soc Trang现在的气候相似。本研究中引入的识别气候类似物的非参数方法可用于气候变化下的影响评估。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Virtually experiencing future climate changes in Central America with MRI-AGCM: climate analogues study
: Twenty-four simulations were carried using the Meteorological Research Institute-Atmospheric General Circulation Model (MRI-AGCM) to predict the late 21st century climate under scenario A1B of the Special Report on Emissions Scenarios. Future climate analogues were identified for Central American capital cities using a recently developed nonparametric method. We used MRI-AGCM3.2H with a horizontal resolution of approximately 60 km, three convection schemes, four sea surface temperature distributions, and two initial conditions. Thus, the total ensemble size was 24, with a simulation period of 25 years. Most of the future analogues are at lower latitudes than their target cities, or near biological diversity and endemism hotspots like coral reefs and mangrove forests. Projected seasonal variations in surface air temperature and rainfall in Panama City were similar to the present-day climate of Soc Trang, located at the mouth of the Mekong River in Vietnam. The nonparametric method introduced in this study for identifying climate analogues can be utilized for impact assess-ments under a changing climate.
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来源期刊
CiteScore
1.90
自引率
18.20%
发文量
9
审稿时长
10 weeks
期刊介绍: Hydrological Research Letters (HRL) is an international and trans-disciplinary electronic online journal published jointly by Japan Society of Hydrology and Water Resources (JSHWR), Japanese Association of Groundwater Hydrology (JAGH), Japanese Association of Hydrological Sciences (JAHS), and Japanese Society of Physical Hydrology (JSPH), aiming at rapid exchange and outgoing of information in these fields. The purpose is to disseminate original research findings and develop debates on a wide range of investigations on hydrology and water resources to researchers, students and the public. It also publishes reviews of various fields on hydrology and water resources and other information of interest to scientists to encourage communication and utilization of the published results. The editors welcome contributions from authors throughout the world. The decision on acceptance of a submitted manuscript is made by the journal editors on the basis of suitability of subject matter to the scope of the journal, originality of the contribution, potential impacts on societies and scientific merit. Manuscripts submitted to HRL may cover all aspects of hydrology and water resources, including research on physical and biological sciences, engineering, and social and political sciences from the aspects of hydrology and water resources.
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