Collaborative Research: P2C2--isotope-enabled TRAnsient Climate Evolution of the last 21,000 years (iTRACE21)----Understanding Deglacial Climate/Isotope Changes Using iCESM

合作研究：P2C2——过去21,000年同位素驱动的瞬态气候演化（iTRACE21）——利用iCESM了解冰消期气候/同位素变化

• 批准号: 1401802
• 负责人: Peter Clark
• 金额: $ 8.52万
• 依托单位: Oregon State University
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2014
• 资助国家: 美国
• 起止时间: 2014-09-01 至 2018-08-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=1401802&HistoricalAwards=false
• 关键词: Collaborative; Research; P2C2; isotope; enabled

This research investigates the mechanisms of climate changes during the last deglaciation (21,000 to 11,000 years ago) using a state-of-the-art isotope-enabled Earth System Model (ESM). The major scientific questions to be addressed in this project are: (1) What are the relationships between the isotopic composition of water and climate changes over the globe? (2) How does the climate system respond to changing climate forcings of the last deglaciation, and what is the contribution from each forcing: insolation, atmospheric greenhouse gases, continental ice sheets, and meltwater? The simulations will allow the study of the continuous evolution and abrupt changes of climate from interannual to orbital time scales. The type of transient simulation marks a transformative breakthrough in model-data comparison, allowing for direct data and model time series comparisons, and will have a significant impact on future paleoclimate studies using both models and observations. The proposed simulations will have a ground breaking impact on research in the paleoclimate community, providing model data for a number of other community projects. It will lay a foundation for a systematic test of future generations of ESMs with coupled cryosphere and biogeochemical models. Specifically, the new version of NCAR's community ESM (CESM), enabled with water isotope tracers, will be run in fully-coupled mode for the period 21,000 to 11,000 years ago. The main simulation will be forced by prescribed changes in insolation, atmospheric greenhouse gas concentrations, continental ice sheets, sea level, and meltwater, while sensitivity simulations will investigate the effect of the different forcings separately. This simulation will be run at a higher resolution (2 degrees in the atmosphere and 1 degree in the ocean) than the previous generation transient model run with CCSM3 (3 degrees). Furthermore, stable water isotope tracers have been included in the atmosphere, land-surface, ocean, and sea-ice models and will be tested first for the Last Glacial Maximum (LGM, 21,000 years ago) and present climate time slices before being run in transient mode for the last deglaciation. One central task of the proposed transient simulations is to explore a new paradigm of model-data comparison in close collaboration with the data community, focusing on direct time series comparisons of isotopes. The simulation of isotope time series will improve paleoclimate model-data comparison significantly, because it will reduce the uncertainties arising from both the inference of isotopes and the absolute chronology of the proxy records. The project will provide the basis for graduate research for students from the University of Wisconsin and Oregon State University.

这项研究使用最先进的同位素地球系统模型（ESM）调查了最后一次冰川消退（21，000至11，000年前）期间气候变化的机制。本项目所要解决的主要科学问题是：（1）水的同位素组成与地球仪气候变化之间的关系是什么？(2)气候系统如何响应末次冰消期气候强迫的变化，以及每种强迫的贡献是什么：日照、大气温室气体、大陆冰盖和融水？通过模拟将能够研究从年际到轨道时间尺度的气候连续演变和突变。瞬态模拟的类型标志着一个变革性的突破，在模型数据比较，允许直接的数据和模型时间序列比较，并将有显着的影响，未来的古气候研究使用模型和观测。拟议的模拟将对古气候社区的研究产生开创性的影响，为其他一些社区项目提供模型数据。它将为未来几代具有耦合冰冻圈和地球化学模型的ESM的系统测试奠定基础。具体来说，NCAR的社区ESM（CESM）的新版本，启用了水同位素示踪剂，将在21，000至11，000年前以完全耦合模式运行。主要的模拟将受到规定的日照变化，大气温室气体浓度，大陆冰盖，海平面和融水的影响，而敏感性模拟将分别研究不同强迫的影响。与使用CCSM 3运行的上一代瞬态模型（3度）相比，该模拟将以更高的分辨率（大气中为2度，海洋中为1度）运行。此外，稳定的水同位素示踪剂已被纳入大气，陆地表面，海洋和海冰模型，并将首先测试末次盛冰期（LGM，21，000年前）和目前的气候时间切片，然后在最后一次冰川消退的瞬态模式下运行。所提出的瞬态模拟的一个中心任务是与数据界密切合作，探索模型数据比较的新范式，重点是同位素的直接时间序列比较。同位素时间序列的模拟将大大改善古气候模型-数据的比较，因为它将减少由同位素推断和代理记录的绝对年代学引起的不确定性。该项目将为来自威斯康星州和俄勒冈州州立大学的学生提供研究生研究的基础。