Geographic bias effects on interpretations of secular trends of Hf isotope times series in zircons

IF 2.9 2区 地球科学 Q2 GEOCHEMISTRY & GEOPHYSICS
Kent C. Condie , Stephen J. Puetz , Kurt E. Sundell , Sergei A. Pisarevsky , Christopher J. Spencer , Nick M.W. Roberts
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引用次数: 0

Abstract

The analysis of εHf(t) time series data from zircon reveals notable discrepancies based on sample type (igneous versus detrital), statistical weighting methodology, and geographic sampling bias. These differences warrant caution when interpreting data in the context of tectonic settings and the history of supercontinents. In terms of tectonic setting, accretionary orogens dominate in both sedimentary basins that host detrital zircons and in igneous zircon sources. Because of differences between the various time series, emphasis in this study is on peaks, valleys and secular trends and not on absolute εHf(t) values. Specifically, the igneous time series for εHf(t) in zircons shows more peaks and valleys than corresponding detrital time series for both weighted and unweighted data (weighting corrects for disproportionate geographic sampling). Also, sample-based (each sample considered separately) and site-based (samples grouped by geographic location and age) results align closely to the igneous time series, whereas the site-based detrital series displays more negative εHf(t) values. Regardless of the type of time series, the failure to compensate for disproportionate geographic sampling increases the prospects of producing an unrepresentative time-series. Nine zircon age peaks (both detrital and igneous) have corresponding εHf(t) peaks (3200, 2700, 2500, 2150, 1500, 1100, 750 Ma) and two have corresponding age valleys (1800–2000, 550 Ma). With exception of a geographically widespread 1500 Ma peak, most of the εHf(t) peaks and valleys are controlled by specific geographic regions and are likely not be global in extent.

Two distinct periods (200–0 and 1800–1600 Ma) display εHf(t) signatures that rise steadily for 100–200 Myr, coinciding with the final stages of supercontinent assembly and the transition to the retreat of exterior orogens. An εHf(t) peak at 750 Ma and a high at 1400–1100 Ma partly overlap with supercontinent breakup and valleys at 550 Ma and 900 Ma with supercontinent assembly. A large εHf(t) valley at 2000–1800 Ma corresponds with the onset of craton collisions that led to the final assembly of Columbia at 1800–1600 Ma. The steep rise in εHf(t) in the last 200 Myr in both igneous and detrital zircons is controlled by sites in Circum-Pacific orogens in North and South America and Southwest Asia, and it parallels the breakup of Pangea. The general increase in zircon εHf(t) in the last 500 Myr in both detrital and igneous data reflects an increase in the proportion of isotopically juvenile components in accretionary orogens.

地理偏差对锆石中 Hf 同位素时间序列世俗趋势解释的影响
对锆石εHf(t)时间序列数据的分析表明,基于样品类型(火成岩与碎屑岩)、统计加权方法和地理取样偏差的数据存在明显差异。在根据构造环境和超大陆历史解释数据时,这些差异值得警惕。就构造环境而言,沉积盆地和火成岩锆石源中的吸积造山运动都占主导地位。由于各种时间序列之间的差异,本研究的重点是峰值、谷值和世俗趋势,而不是εHf(t)的绝对值。具体来说,锆石中εHf(t)的火成岩时间序列在加权和非加权数据(加权可纠正不成比例的地理取样)上都比相应的碎屑岩时间序列显示出更多的峰值和谷值。此外,基于样本(每个样本单独考虑)和基于矿点(按地理位置和年龄分组的样本)的结果与火成岩时间序列非常接近,而基于矿点的碎屑岩序列则显示出更多的εHf(t)负值。无论是哪种类型的时间序列,如果不对不成比例的地理取样进行补偿,就会增加产生不具代表性的时间序列的可能性。九个锆石年龄峰(包括碎屑岩和火成岩)都有相应的εHf(t)峰(3200, 2700, 2500, 2150, 1500, 1100, 750 Ma),两个有相应的年龄谷(1800-2000, 550 Ma)。两个不同时期(200-0 Ma和1800-1600 Ma)的εHf(t)特征在100-200 Myr内持续上升,与超大陆组装的最后阶段和外部原点退缩的过渡阶段相吻合。εHf(t)在750Ma达到峰值,在1400-1100Ma达到高点,这与超大陆的解体部分重合,而在550Ma和900Ma的低谷则与超大陆的组装重合。2000-1800Ma处的εHf(t)大谷与1800-1600Ma处导致哥伦比亚最终组装的陨石撞击的开始相吻合。火成岩和碎屑锆石中的εHf(t)在过去 200 Myr 的急剧上升是由北美、南美和西南亚环太平洋造山带中的地点控制的,它与 Pangea 的解体相平行。锆石εHf(t)在过去500 Myr的碎屑岩和火成岩数据中的普遍上升反映了增生造山运动中同位素幼年成分比例的增加。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Lithos
Lithos 地学-地球化学与地球物理
CiteScore
6.80
自引率
11.40%
发文量
286
审稿时长
3.5 months
期刊介绍: Lithos publishes original research papers on the petrology, geochemistry and petrogenesis of igneous and metamorphic rocks. Papers on mineralogy/mineral physics related to petrology and petrogenetic problems are also welcomed.
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