Collaborative Research: Investigating the potential of carbon-14 in polar firn and ice as a tracer of past cosmic ray flux and an absolute dating tool

合作研究：研究极地冰和冰中碳 14 作为过去宇宙射线通量示踪剂和绝对测年工具的潜力

• 批准号: 1203779
• 负责人: Vasilii Petrenko
• 金额: $ 54.12万
• 依托单位: University of Rochester
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2012
• 资助国家: 美国
• 起止时间: 2012-08-01 至 2017-07-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=1203779&HistoricalAwards=false
• 关键词: Collaborative; Research; Investigating; potential; carbon

The proposed work will investigate the potential of carbon-14 in ice cores as an absolute dating tool, as a tracer of the past cosmic ray flux and as a recorder of the past fossil fraction of the global methane budget. Cosmic ray particles produce carbon-14 from oxygen-16 directly within near-surface glacial ice and firn. This in-situ produced carbon-14 quickly reacts to form 14C-containing carbon dioxide, carbon monoxide, and methane in the ice matrix. Some or all of the resulting 14C-bearing gases may be lost from the firn to the atmosphere. The proposed work will provide a thorough characterization of in-situ cosmogenic 14C in glacial firn and shallow ice in the Summit region of Greenland. It will examine the retention of cosmogenic 14C in ice grains at all depth levels in the firn column, the partitioning of 14C between carbon dioxide, carbon monoxide, and methane, as well as the production rates and accumulation of cosmogenic 14C in shallow ice below firn close-off. A thorough understanding of cosmogenic C-14 in firn and shallow ice will likely enable the use of C-14 in ice for one or more of the following applications:
1) If a relatively large amount of cosmogenic 14C is present in ice below the depth at which air bubbles become sealed off, it will be useful as a tracer for past cosmic ray flux. The investigators believe that this is the likely case for 14C-carbon monoxide. 2) If the amount of retained in-situ-produced 14C-carbon dioxide is relatively small compared to 14C-carbon dioxide from trapped air, the study will demonstrate the validity of using 14C-carbon dioxide for absolute dating of ice cores; this has long been a target of ice core studies.3) If the amount of retained in-situ-produced 14C-methane is relatively small compared to 14C-methane from trapped air, the study will demonstrate the validity of using 14C-methane in glacial ice for determinations of the fossil fraction of the past methane budget, including releases from methane clathrates.The proposed work will establish a new international collaboration between University of Rochester (UR) and University of Bern and result in novel laboratory and field analytical systems. The data from the study will be made available to the scientific community and the broad public through the ACADIS data service. One graduate student will be trained at UR, and one postdoc and one graduate student will be partially supported at Oregon State University. Three UR undergraduates will be involved in fieldwork and research. The work will support an early career scientist. All of the investigators will continue to participate in public outreach.

拟议的工作将调查冰芯中碳-14作为绝对测年工具的潜力，作为过去宇宙射线通量的示踪剂，以及作为过去全球甲烷预算化石部分的记录者。宇宙射线粒子直接在近地表的冰川冰和雪中由氧-16产生碳-14。这种原位产生的碳-14在冰基质中迅速反应形成含有碳-14的二氧化碳、一氧化碳和甲烷。产生的部分或全部含碳气体可能会从公司流失到大气中。这项工作将为格陵兰峰顶地区冰原和浅冰的原位宇宙成因14C提供全面的表征。它将检查在冰柱中所有深度的冰粒中宇宙生成的14C的保留，二氧化碳、一氧化碳和甲烷之间的14C的分配，以及在冰柱关闭以下的浅层冰中宇宙生成的14C的生产速率和积累。透彻地了解坚硬冰和浅冰中宇宙成因的C-14，可能会使C-14在冰中的应用能够用于以下一种或多种应用：1)如果在气泡被封闭的深度以下的冰中存在相对大量的宇宙成因的14C，那么它就可以作为过去宇宙射线通量的示踪剂。研究人员认为，这可能是14c -一氧化碳的情况。2)如果原地产生的14c -二氧化碳的保留量相对于捕获空气中的14c -二氧化碳相对较少，则该研究将证明使用14c -二氧化碳进行冰芯绝对定年的有效性；这一直是冰芯研究的目标。3)如果保留的原位产生的14c -甲烷的数量相对于捕获的空气中的14c -甲烷相对较少，则该研究将证明使用冰川冰中的14c -甲烷来确定过去甲烷预算的化石部分的有效性，包括甲烷包合物的释放。拟议的工作将在罗切斯特大学（UR）和伯尔尼大学之间建立一个新的国际合作，并产生新的实验室和现场分析系统。该研究的数据将通过ACADIS数据服务提供给科学界和广大公众。一名研究生将在俄勒冈州立大学接受培训，一名博士后和一名研究生将在俄勒冈州立大学获得部分资助。三名本科生将参与实地考察和研究。这项工作将支持一位早期职业科学家。所有调查人员将继续参与公众宣传。