Collaborative Research: Calibrating the Isotopologue-47 Geothermometer in Soils

合作研究：校准土壤中的 Isotopologue-47 地温计

• 批准号: 0843104
• 负责人: Jay Quade
• 金额: $ 8.64万
• 依托单位: University of Arizona
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2009
• 资助国家: 美国
• 起止时间: 2009-03-01 至 2012-02-29
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=0843104&HistoricalAwards=false
• 关键词: Collaborative; Research; Calibrating; Isotopologue; 47

Use of isotopologue-47 paleothermometer over the past several years is an exciting new development that holds enormous potential for reconstruction of paleotemperatures in the deeper geologic record. Paleosol carbonates are a particularly attractive target for such analysis because they are so abundant in the geologic record, and because temperature in soils displays a highly predictable relationship to air temperature (unlike in many other systems). Before this potential can be realized, the relationship between temperatures estimated from isotopologue-47 analysis (expressed as Ä47) of modern soil carbonate, and that of local air and soil temperature must be rigorously established. We present unpublished results from a number of modern soils that show that temperature estimates from Ä47 values systematically exceed those of modeled summer maximum temperatures by 6±2°C. Part of the excess?up to 2-4°C?may be explained asymmetric summer heating of soil. The remaining excess may be the result of contamination, the wrong assumed soil temperatures, or perhaps non-equilibrium kinetic effects. Whatever the cause, the more key question is whether the offset between actual and estimated values is systematic. This must be tested with a much larger sample set and with direct measurements of soil temperature. Here we propose to monitor temperature and other parameters in modern soils from a range of settings for comparison to Ä47 estimates of temperatures. Our study sites include Arizona, Nevada, Hawaii, and NW Argentina, taking in most of the natural temperature range for soil carbonate formation. Broader impacts of this on the larger scientific community will be substantial, given the intense interest in using this new geothermometer on a variety of research questions. Exciting potential applications of the new paleothermometer include reconstruction of paleotemperature (±2°C) using such long paleosol time series (17 Myr) as the Siwaliks in Pakistan, and of paleoelevation, through the strong sensitivity of the temperature to elevation in the world?s major orogens. Field and laboratory measurements and data analysis are ideal training opportunities for undergraduates in the sciences, who will be recruited from several institutions to participate in field and labwork.

同位素47古温度计在过去几年中的使用是一个令人兴奋的新发展，具有在更深的地质记录中重建古温度的巨大潜力。古土壤碳酸盐是这种分析的特别有吸引力的目标，因为它们在地质记录中非常丰富，而且土壤温度与气温之间的关系具有高度可预测性（与许多其他系统不同）。在实现这一潜力之前，必须严格建立现代土壤碳酸盐同位素47分析（表示为Δ 47）估计的温度与当地空气和土壤温度之间的关系。我们提出了一些现代土壤的未发表的结果，表明从Δ 47值估计的温度系统地超过模拟的夏季最高温度6±2°C。部分过剩？2-4 ℃？可以解释不对称的夏季加热的土壤。剩余的过量可能是污染的结果，错误的假设土壤温度，或者可能是非平衡动力学效应。无论原因是什么，更关键的问题是实际值和估计值之间的偏移是否是系统性的。这必须用更大的样本集和土壤温度的直接测量来测试。在这里，我们建议从一系列设置中监测现代土壤中的温度和其他参数，以与温度的估计值进行比较。我们的研究地点包括亚利桑那州、内华达州、夏威夷和阿根廷西北部，涵盖了土壤碳酸盐形成的大部分自然温度范围。鉴于人们对在各种研究问题上使用这种新的地质温度计的浓厚兴趣，这对更大的科学界将产生更广泛的影响。令人兴奋的潜在应用的新的古温度计包括重建古温度（±2°C）使用这样长的古土壤时间序列（17百万年）在巴基斯坦的西瓦利克，和古海拔，通过强烈的敏感性，在世界各地的温度海拔？的主要造山带。现场和实验室测量和数据分析是科学本科生的理想培训机会，他们将从几个机构招募参加现场和实验室工作。