Leonie Peti, K. Fitzsimmons, J. Hopkins, A. Nilsson, T. Fujioka, D. Fink, Charles Mifsud, M. Christl, R. Muscheler, P. Augustinus
{"title":"新西兰奥克兰Orakei maar湖末次冰期多方法年代学的发展","authors":"Leonie Peti, K. Fitzsimmons, J. Hopkins, A. Nilsson, T. Fujioka, D. Fink, Charles Mifsud, M. Christl, R. Muscheler, P. Augustinus","doi":"10.5194/gchron-2020-23","DOIUrl":null,"url":null,"abstract":"Abstract. Northern New Zealand is an important location for understanding Last Glacial Interval (LGI) palaeoclimate dynamics, since it is\ninfluenced by both tropical and polar climate systems which have varied in\nrelative strength and timing. Sediments from the Auckland Volcanic Field\nmaar lakes preserve records of such large-scale climatic influences on\nregional palaeo-environment changes, as well as past volcanic eruptions. The\nsediment sequence infilling Orakei maar lake is continuous, laminated, and\nrapidly deposited, and it provides a high-resolution (sedimentation rate above\n∼ 1 m kyr−1) archive from which to investigate the dynamic nature\nof the northern New Zealand climate system over the LGI. Here we present the\nchronological framework for the Orakei maar sediment sequence. Our\nchronology was developed using Bayesian age modelling of combined\nradiocarbon ages, tephrochronology of known-age rhyolitic tephra marker\nlayers, 40Ar∕39Ar-dated eruption age of a local basaltic volcano, luminescence dating (using post-infrared–infrared stimulated luminescence,\nor pIR-IRSL), and the timing of the Laschamp palaeomagnetic excursion. We\nhave integrated our absolute chronology with tuning of the relative\npalaeo-intensity record of the Earth's magnetic field to a global reference\ncurve (PISO-1500). The maar-forming phreatomagmatic eruption of the Orakei\nmaar is now dated to > 132 305 years (95 % confidence range:\n131 430 to 133 180 years). Our new chronology facilitates high-resolution\npalaeo-environmental reconstruction for northern New Zealand spanning the last\nca. 130 000 years for the first time as most NZ records that span all or\nparts of the LGI are fragmentary, low-resolution, and poorly dated. Providing\nthis chronological framework for LGI climate events inferred from the Orakei\nsequence is of paramount importance in the context of identification of\nleads and lags in different components of the Southern Hemisphere climate\nsystem as well as identification of Northern Hemisphere climate signals.\n","PeriodicalId":12723,"journal":{"name":"Geochronology","volume":"4 1","pages":""},"PeriodicalIF":2.7000,"publicationDate":"2020-08-05","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"6","resultStr":"{\"title\":\"Development of a multi-method chronology spanning the Last Glacial Interval from Orakei maar lake, Auckland, New Zealand\",\"authors\":\"Leonie Peti, K. Fitzsimmons, J. Hopkins, A. Nilsson, T. Fujioka, D. Fink, Charles Mifsud, M. Christl, R. Muscheler, P. Augustinus\",\"doi\":\"10.5194/gchron-2020-23\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"Abstract. Northern New Zealand is an important location for understanding Last Glacial Interval (LGI) palaeoclimate dynamics, since it is\\ninfluenced by both tropical and polar climate systems which have varied in\\nrelative strength and timing. Sediments from the Auckland Volcanic Field\\nmaar lakes preserve records of such large-scale climatic influences on\\nregional palaeo-environment changes, as well as past volcanic eruptions. The\\nsediment sequence infilling Orakei maar lake is continuous, laminated, and\\nrapidly deposited, and it provides a high-resolution (sedimentation rate above\\n∼ 1 m kyr−1) archive from which to investigate the dynamic nature\\nof the northern New Zealand climate system over the LGI. Here we present the\\nchronological framework for the Orakei maar sediment sequence. Our\\nchronology was developed using Bayesian age modelling of combined\\nradiocarbon ages, tephrochronology of known-age rhyolitic tephra marker\\nlayers, 40Ar∕39Ar-dated eruption age of a local basaltic volcano, luminescence dating (using post-infrared–infrared stimulated luminescence,\\nor pIR-IRSL), and the timing of the Laschamp palaeomagnetic excursion. We\\nhave integrated our absolute chronology with tuning of the relative\\npalaeo-intensity record of the Earth's magnetic field to a global reference\\ncurve (PISO-1500). The maar-forming phreatomagmatic eruption of the Orakei\\nmaar is now dated to > 132 305 years (95 % confidence range:\\n131 430 to 133 180 years). Our new chronology facilitates high-resolution\\npalaeo-environmental reconstruction for northern New Zealand spanning the last\\nca. 130 000 years for the first time as most NZ records that span all or\\nparts of the LGI are fragmentary, low-resolution, and poorly dated. 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引用次数: 6
摘要
摘要新西兰北部是了解末次冰期(LGI)古气候动力学的重要地点,因为它受到热带和极地气候系统的影响,这些气候系统在相对强度和时间上都有所不同。奥克兰火山场湖泊的沉积物保存了如此大规模的气候对区域古环境变化的影响,以及过去的火山爆发。填充Orakei maar湖的沉积物序列是连续的、层状的和快速沉积的,它提供了一个高分辨率(沉积速率大于1 m kyr−1)的档案,从中研究LGI上新西兰北部气候系统的动态性质。在这里,我们提出了奥拉凯马尔沉积序列的年代框架。我们的年代学是利用贝叶斯年龄模型的组合放射性碳年龄、已知年龄流纹岩岩屑标志层的年代学、40Ar / 39 ar定年的当地玄武岩火山喷发年龄、发光测年(使用后红外-红外刺激发光,或pIR-IRSL)和Laschamp古地磁运动的时间来建立的。我们将我们的绝对年表与地球磁场的相对古强度记录调整到全球参考曲线(PISO-1500)相结合。奥拉基玛尔火山的岩浆喷发距今超过133305年(95%置信范围:131330 ~ 133180年)。我们的新年代学促进了新西兰北部最后一个世纪的高分辨率古环境重建。13万年前,因为大多数跨越LGI全部或部分的新西兰记录都是碎片化的,低分辨率的,而且年代不准确。为从奥莱克序列推断出的LGI气候事件提供这个时间框架,对于识别南半球气候系统不同组成部分的领先和滞后以及识别北半球气候信号具有至关重要的意义。
Development of a multi-method chronology spanning the Last Glacial Interval from Orakei maar lake, Auckland, New Zealand
Abstract. Northern New Zealand is an important location for understanding Last Glacial Interval (LGI) palaeoclimate dynamics, since it is
influenced by both tropical and polar climate systems which have varied in
relative strength and timing. Sediments from the Auckland Volcanic Field
maar lakes preserve records of such large-scale climatic influences on
regional palaeo-environment changes, as well as past volcanic eruptions. The
sediment sequence infilling Orakei maar lake is continuous, laminated, and
rapidly deposited, and it provides a high-resolution (sedimentation rate above
∼ 1 m kyr−1) archive from which to investigate the dynamic nature
of the northern New Zealand climate system over the LGI. Here we present the
chronological framework for the Orakei maar sediment sequence. Our
chronology was developed using Bayesian age modelling of combined
radiocarbon ages, tephrochronology of known-age rhyolitic tephra marker
layers, 40Ar∕39Ar-dated eruption age of a local basaltic volcano, luminescence dating (using post-infrared–infrared stimulated luminescence,
or pIR-IRSL), and the timing of the Laschamp palaeomagnetic excursion. We
have integrated our absolute chronology with tuning of the relative
palaeo-intensity record of the Earth's magnetic field to a global reference
curve (PISO-1500). The maar-forming phreatomagmatic eruption of the Orakei
maar is now dated to > 132 305 years (95 % confidence range:
131 430 to 133 180 years). Our new chronology facilitates high-resolution
palaeo-environmental reconstruction for northern New Zealand spanning the last
ca. 130 000 years for the first time as most NZ records that span all or
parts of the LGI are fragmentary, low-resolution, and poorly dated. Providing
this chronological framework for LGI climate events inferred from the Orakei
sequence is of paramount importance in the context of identification of
leads and lags in different components of the Southern Hemisphere climate
system as well as identification of Northern Hemisphere climate signals.