Climate Model Projections for Canada: A Comparison of CMIP5 and CMIP6

IF 1.8 4区地球科学 Q4 METEOROLOGY & ATMOSPHERIC SCIENCES

Atmosphere-Ocean Pub Date : 2021-10-20 DOI:10.1080/07055900.2021.2011103

S. Sobie, F. Zwiers, C. Curry

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引用次数: 7

Abstract

ABSTRACT Recent studies have identified stronger warming in the latest generation of climate model simulations globally, and the same is true for projected changes in Canada. This study examines differences for Canada and six sub-regions between simulations from the latest Sixth Coupled Model Intercomparison Project (CMIP6) and its predecessor CMIP5. Ensembles from both experiments are assessed using a set of derived indices calculated from daily precipitation and temperature, with projections compared at fixed future time intervals and fixed levels of global temperature change. For changes calculated at fixed time intervals most temperature indices display higher projected changes in CMIP6 than CMIP5 for most sub-regions, while greater precipitation changes in CMIP6 occur mainly in extreme precipitation indices. When future projections are calculated at fixed levels of global average temperature increase, the size and spread of differences for future projected changes between CMIP6 and CMIP5 are substantially reduced for most indices. Temperature scaling behaviour, or the regional response to increasing global temperatures, is similar in both ensembles, with annual temperature anomalies for Canada and its sub-regions increasing at between 1.5 and 2.5 times the rate of increase globally, depending on the region. The CMIP6 ensemble projections exhibit modestly stronger scaling behaviour for temperature anomalies in northern Canada, as well as for certain indices of moderate and extreme events. Such temperature scaling differences persist even if anomalously warm CMIP6 global climate models are omitted. Comparing the mean and variance of future projections for Canada in CMIP5 and CMIP6 simulations from the same modelling centre suggests CMIP6 models are significantly warmer in Canada than CMIP5 models at the same level of forcing, with some evidence that internal temperature variability in CMIP6 is reduced compared with CMIP5.

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加拿大气候模型预测：CMIP5和CMIP6的比较

摘要最近的研究在最新一代全球气候模型模拟中发现了更强的变暖，加拿大的预测变化也是如此。本研究考察了加拿大和六个子区域最新的第六耦合模型相互比较项目（CMIP6）及其前身CMIP5的模拟之间的差异。这两个实验的集合使用一组根据每日降水量和温度计算的衍生指数进行评估，并在固定的未来时间间隔和固定的全球温度变化水平上对预测进行比较。对于以固定时间间隔计算的变化，对于大多数子区域，大多数温度指数在CMIP6中显示出比CMIP5更高的预测变化，而CMIP6的较大降水变化主要发生在极端降水指数中。当未来预测是在全球平均气温上升的固定水平上计算时，CMIP6和CMIP5之间未来预测变化的差异大小和分布对于大多数指数来说都会大大减少。温度标度行为，或区域对全球温度上升的反应，在这两个集合中都是相似的，加拿大及其子区域的年温度异常增长率是全球增长率的1.5到2.5倍，具体取决于区域。CMIP6系综预测对加拿大北部的温度异常以及中等和极端事件的某些指数表现出适度更强的标度行为。即使省略了异常温暖的CMIP6全球气候模型，这种温度标度差异仍然存在。比较来自同一建模中心的CMIP5和CMIP6模拟中加拿大未来预测的平均值和方差表明，在相同强迫水平下，CMIP6模型在加拿大的温度明显高于CMIP5模型，一些证据表明CMIP6的内部温度变化性与CMIP5相比有所降低。

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来源期刊

Atmosphere-Ocean 地学-海洋学

CiteScore

2.50

自引率

16.70%

发文量

审稿时长

>12 weeks

期刊介绍： Atmosphere-Ocean is the principal scientific journal of the Canadian Meteorological and Oceanographic Society (CMOS). It contains results of original research, survey articles, notes and comments on published papers in all fields of the atmospheric, oceanographic and hydrological sciences. Arctic, coastal and mid- to high-latitude regions are areas of particular interest. Applied or fundamental research contributions in English or French on the following topics are welcomed: climate and climatology; observation technology, remote sensing; forecasting, modelling, numerical methods; physics, dynamics, chemistry, biogeochemistry; boundary layers, pollution, aerosols; circulation, cloud physics, hydrology, air-sea interactions; waves, ice, energy exchange and related environmental topics.