EAGER: Pedogenic Carbonates Record Insolation Driven Surface Melting in Antarctica

EAGER：成土碳酸盐记录了南极洲日照驱动的表面融化

• 批准号: 2423761
• 负责人: Terrence Blackburn
• 金额: $ 29.91万
• 依托单位: University of California-Santa Cruz
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2024
• 资助国家: 美国
• 起止时间: 2024-10-01 至 2026-09-30
• 项目状态: 未结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=2423761&HistoricalAwards=false
• 关键词: EAGER; Pedogenic; Carbonates; Record; Insolation

Non-technical abstractEarth’s climatic changes have been recorded in the ice core collected from the Antarctic ice sheet. While these records provide a high resolution view of how polar temperatures changed through time, it is not always clear what Earth process influence Antarctic climate. One likely contributor to Antarctic temperature changes is the cyclic changes in Earth’s orientation as it orbits the sun. These so-called Milankovitch cycles control the amount and pattern of sunlight reaching the polar regions, that in turn result in periods of climatic warming or cooling. While the orbital variations and control on incoming solar energy remain well understood, how they influence Antarctic climate remains unresolved. It is the goal of this project to determine how variations in Earth’s orbit may be locally influencing Antarctic temperatures. The researchers on this project are pursing this goal by identifying periods of past ice melting on the surface of Antarctica using minerals that precipitate from the meltwaters that resulted from past warm periods. The timing of this past melting will be determined by radioisotopic dating of the minerals using the natural radioactive decay of uranium to thorium. By dating numerous samples, collected in past scientific expeditions throughout the Antarctic continent, these researchers aim to reconstruct the frequency and spatial pattern of past warming and in doing so, determine what aspect of Earth’s orbital variations influences Antarctic ice loss.Technical abstractAntarctic ice cores provide high resolution records of Pleistocene Southern Hemisphere temperatures that show an overall coherence with Northern Hemisphere temperature variations. One explanation for this bi-hemispheric temperature covariance relies on changes in atmospheric CO2 that result from varying northern hemisphere insolation. An alternative posits that the apparent coherence of polar temperatures is due to the misleading covariance between northern hemisphere summer insolation and, the southern hemisphere summer duration. At present there is an insufficient understanding of the role that local insolation plays in Antarctic climate. The goal of this research project is to identify the temporal spatial patterns of solar forcing in Antarctica. To reach this goal, the project team will: 1) develop a way to identify periods of past surface melt production in Antarctica using U-Th dating of pedogenic carbonates; and 2) utilize the evidence of past surface melting to calibrate energy balance models and interrogate past Antarctic surface temperatures and; 3) compare the timing of Antarctic warm periods to potential solar forcing mechanisms such as peak summer insolation or summer duration. A means of identifying the spatial and temporal pattern at which local insolation influences Antarctic temperature would provide a transformative solution to the contradiction in current climate records.This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.

非技术摘要从南极冰盖收集的冰芯中记录了地球的气候变化，虽然这些记录提供了极地温度如何随时间变化的高分辨率视图，但并不总是清楚地球过程可能影响南极气候。造成南极温度变化的因素是地球绕太阳运行时的方向的周期性变化，这些所谓的米兰科维奇周期控制着到达极地地区的阳光量和模式，从而导致了南极地区的周期性变化。虽然轨道变化和对传入太阳能的控制仍然很清楚，但它们如何影响南极气候仍然悬而未决，该项目的目标是确定地球轨道的变化如何影响南极的局部温度。该项目正在通过利用过去温暖时期产生的融水中沉淀的矿物质来确定南极洲表面过去冰融化的时期来实现这一目标。通过利用铀到钍的自然放射性衰变对矿物进行放射性同位素测年，这些研究人员对过去在整个南极大陆的科学考察中收集的大量样本进行了测年，旨在重建过去变暖的频率和空间模式。 ，确定地球轨道变化的哪些方面影响南极冰损失。技术摘要南极冰芯提供了更新世南半球温度的高分辨率记录，显示了整体一致性这种双半球温度协方差的一种解释依赖于北半球日照变化引起的大气二氧化碳的变化，另一种假设是极地温度的明显一致性是由于北半球夏季日照之间的误导性协方差。目前，人们对南半球夏季持续时间的了解还不够。该研究项目的目标是确定时间。为了实现这一目标，项目团队将：1）开发一种方法，利用成土碳酸盐的 U-Th 测年来确定南极洲过去地表融化产生的时期；2）利用过去的证据；地表融化来校准能量平衡模型并询问过去的南极表面温度；3）将南极温暖期的时间与潜在的太阳强迫机制（例如夏季日照峰值或夏季持续时间）进行比较。局部绝缘影响南极温度的空间和时间模式将为当前气候记录中的矛盾提供变革性的解决方案。该奖项反映了 NSF 的法定使命，并通过使用基金会的智力价值和更广泛的影响审查标准进行评估，被认为值得支持。