Collaborative Research: Combined Influence of Snow Cover and El Nino/Southern Oscillation (ENSO) on North African/Mediterranean Temperature and Precipitation

合作研究：积雪和厄尔尼诺/南方涛动（ENSO）对北非/地中海气温和降水的综合影响

基本信息

批准号：
1303647
负责人：
Judah Cohen
金额：
$ 24.34万
依托单位：
Atmospheric and Environmental Research Inc
依托单位国家：
美国
项目类别：
Standard Grant
财政年份：
2013
资助国家：
美国
起止时间：
2013-12-01 至 2016-11-30
项目状态：
已结题

来源：
https://www.nsf.gov/awardsearch/showAward?AWD_ID=1303647&HistoricalAwards=false
关键词：
Collaborative Research Combined Influence Snow

项目摘要

This project considers the generation of North African and Mediterranean climate anomalies by El Nino/Southern Oscillation (ENSO) events and Eurasian snow cover fluctuations. Two causal mechanisms are examined, one involving tropospheric teleconnections produced by Rossby wave generation and propagation (a "horizontal" mechanism), and the other involving stratosphere-troposphere interactions (a "vertical" mechanism). The horizontal mechanism is hypothesized to consist of 1) a canonical northeastward propagating wave train that emanates from the eastern equatorial Pacific, and 2) an ultra-low frequency Rossby wave that is excited over the Pacific, trapped within the North African-Asian (NAA) jet and propagates upstream to the Mediterranean region. The vertical mechanism begins with an expansion of Eurasian snow cover, which leads to colder surface conditions and lowering of mid-tropospheric geopotential height. This in turn amplifies the wave-1 stationary wave pattern, which propagates into the stratosphere and reduces the strength of the polar vortex, resulting in a negative anomaly of the Arctic or North Atlantic Oscillation, which shifts the jet stream and storm track southward. The southward shift of the jet and storm track allows colder temperatures to invade the middle latitudes, including the Mediterranean region. These influences will be examined through statistical analysis combined with a suite of models including a Rossby wave ray tracing calculation, a linearized barotropic model, a state-of-the-art global atmospheric model (CAM), and an atmospheric model with a well-resolved stratosphere (WACCM). In addition, an empirical prediction scheme will be developed and tested using Eurasian snow cover and ENSO as predictors for seasonal Mediterranean precipitation and surface temperature.The work has societal broader impacts due to the agricultural and other consequences of climate variability in the Mediterranean region. More specifically, the empirical prediction scheme will be provided to operational centers including the International Research Institute at Columbia University. In addition, a website will be developed to provide public information regarding the role of atmospheric teleconnections in producing climate anomalies. The project will also support and train a graduate student, thereby providing for the future scientific workforce in this research area.

该项目考虑了厄尔尼诺/南方涛动（ENSO）事件和欧亚积雪波动造成的北非和地中海气候异常。研究了两种因果机制，一种涉及罗斯贝波产生和传播产生的对流层遥相关（“水平”机制），另一种涉及平流层-对流层相互作用（“垂直”机制）。假设水平机制包括 1）从赤道东部太平洋发出的典型东北传播波列，以及 2）在太平洋上空激发的超低频罗斯贝波，被困在北非-亚洲（NAA）内）喷射并向上游传播到地中海地区。垂直机制始于欧亚积雪的扩张，导致地表条件变冷和对流层中层位势高度降低。这反过来又放大了第一波驻波模式，传播到平流层并降低了极地涡旋的强度，导致北极或北大西洋涛动的负异常，从而使急流和风暴路径向南移动。急流和风暴路径向南移动，使得寒冷的气温侵入中纬度地区，包括地中海地区。这些影响将通过统计分析结合一套模型进行检查，包括罗斯比波射线追踪计算、线性正压模型、最先进的全球大气模型（CAM）以及具有良好性能的大气模型。解析平流层（WACCM）。此外，还将使用欧亚积雪和 ENSO 作为地中海季节性降水和地表温度的预测因子来开发和测试经验预测方案。由于地中海地区气候变化的农业和其他后果，这项工作具有更广泛的社会影响。更具体地说，经验预测方案将提供给包括哥伦比亚大学国际研究所在内的运营中心。此外，还将开发一个网站，提供有关大气遥相关在产生气候异常中的作用的公共信息。该项目还将支持和培训一名研究生，从而为该研究领域的未来科学劳动力提供支持。