ENSO frequency change in coupled climate models as response to the increasing CO_2 concentration 被引量：1

ENSO frequency change in coupled climate models as response to the increasing CO_2 concentration

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摘要 The response of ENSO frequency to the increasing CO2 concentration and associated mechanism are examined with outputs of four coupled climate models (GFDL/CM2.0,CNRM/CM3,IPSL/CM4 and INM/CM3.0) submitted to the IPCC Fourth Assessment Report (IPCC AR4).Results reveal a significant change of ENSO frequency as response to the increasing CO2 concentration.However,such a change exhibits an evident model dependence.The ENSO frequency tends to increase in GFDL/CM2.0 and CNRM/CM3 models and decreases in IPSL/CM4 and INM/CM3.0 models.The model dependence is found to be determined by how the model climatological background state of the tropical Pacific responds to the increasing CO 2 concentration.It is demonstrated that the change of zonally-and vertically-averaged climatological background upper ocean temperature gradient between the equator and off-equator is crucially responsible for the ENSO frequency change.As response to the increasing CO 2 concentration,the climatological background temperature gradient is increased in GFDL/CM2.0 and CNRM/CM3 models and decreased in IPSL/CM4 and INM/CM3.0 models.In terms of the recharge-discharge oscillator theory for ENSO,the increased (decreased) climatological background temperature gradient between the equator and off-equator induces a faster (slower) exchange of oceanic heat content between the equator and off-equator,thus giving rise to a shorter (longer) ENSO timescale and a higher (lower) ENSO frequency. The response of ENSO frequency to the increasing CO2 concentration and associated mechanism are examined with outputs of four coupled climate models （GFDL/CM2.0, CNRM/CM3, IPSL/CM4 and INM/CM3.0） submitted to the IPCC Fourth Assessment Report （IPCC AR4）. Results reveal a significant change of ENSO frequency as response to the increasing CO2 concentration However, such a change exhibits an evident model dependence. The ENSO frequency tends to increase in GFDL/CM2.0 and CNRM/CM3 models and decreases in IPSL/CM4 and INM/CM3.0 models. The model dependence is found to be determined by how the model climatological background state of the tropical Pacific responds to the increasing CO2 concentration. It is demon- strated that the change of zonally- and vertically-averaged climatological background upper ocean temperature gradient between the equator and off-equator is crucially responsible for the ENSO frequency change. As response to the increasing CO2 concentration, the climatological background temperature gradient is increased in GFDL/CM2.0 and CNRM/CM3 models and decreased in IPSL/CM4 and INM/CM3.0 models. In terms of the recharge-discharge oscillator theory for ENSO, the increased （decreased） climatological background temperature gradient between the equator and off-equator induces a faster （slower） exchange of oceanic heat content between the equator and off-equator, thus giving rise to a shorter （longer） ENSO timescale and a higher （lower） ENSO frequency.

作者 DENG Lin YANG XiuQun XIE Qian

机构地区 School of Atmospheric Sciences Institute of Meteorology

出处《Chinese Science Bulletin》 SCIE EI CAS 2010年第8期744-751,共8页

基金 supported by the National Natural Science Foundation of China (Grant Nos.40730953 and 40425009) Natural Science Foundation of Jiangsu Province (Grant No.BK2008027)

关键词二氧化碳浓度 ENSO 频率响应气候模式耦合气候背景温度梯度评估报告 coupled climate model, increasing CO2 concentration, ENSO frequency change, recharge-discharge oscillator

分类号 P732 [天文地球—海洋科学] X16 [环境科学与工程—环境科学]

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