Miocene climate cooling and aridification of Antarctica may have enhanced syn-extensional magmatism in the western Ross Sea

IF 4 1区 地球科学 Q1 GEOGRAPHY, PHYSICAL
Marco Fioraso , Pietro Sternai , Valerio Olivetti , Maria Laura Balestrieri , Massimiliano Zattin , Gianluca Cornamusini
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引用次数: 0

Abstract

Continental rift systems are commonly characterized by volcanism with parental basaltic magmas sourced from the mantle. Erosion of the rift shoulders and sedimentation in the adjacent basins can affect the stress and thermal fields at depth, thereby affecting partial mantle melting. However, the sensitivity of magmatic activity to such surface forcing is elusive. Geological observations from the western Ross Sea, Antarctica, suggest rift onset in the Cretaceous with a transition from wide-rifting to narrow-rifting at the boundary between the Antarctic craton and the Transantarctic Mountains. Miocene climate cooling during rifting in the western Ross Sea, in addition, leads to an abrupt decrease in sedimentation rate, synchronous to the emplacement of the McMurdo Volcanic Group. This represents the largest alkali province worldwide, extending both inland and offshore of Transantarctic Mountains and western Ross Sea, respectively. Here, we use coupled thermo-mechanical and landscape evolution numerical modeling to quantify melt production in slowly stretching rift basins due to changes in erosion/deposition rates. The model combines visco-elasto-plastic deformation of the lithosphere and underlying mantle during extension, partial rock melting, and linear hillslope diffusion of the surface topography. The parametric study covers a range of slow extension rates, crustal thicknesses, mantle potential temperatures and diffusion coefficients. Numerical simulations successfully reproduce the ∼150–200-km-wide extension of western Ross Sea and Miocene-to-present asthenospheric melt production (McMurdo Volcanic Group). Results further show that slow rifts magmatism is highly sensitive to sediment deposition within the basin, which inhibits mantle decompression melting and delays the crustal breakup. Regional climate-driven sedimentation rate changes are thus likely to have affected the syn-rift magmatic history of the western Ross Sea, Antarctica, supporting the relevance of interactions between surface and deep-seated processes across extensional settings.

中新世气候变冷和南极洲干旱化可能加剧了罗斯海西部的同步扩展岩浆活动
大陆裂谷系统通常以火山活动为特征,其母体玄武岩浆来自地幔。裂谷肩部的侵蚀和邻近盆地的沉积会影响深部的应力场和热场,从而影响地幔的部分熔化。然而,岩浆活动对这种地表作用力的敏感性却难以捉摸。南极罗斯海西部的地质观测结果表明,断裂发生于白垩纪,在南极陨石坑和横贯南极山脉之间的边界由宽断裂过渡到窄断裂。此外,罗斯海西部断裂期间的中新世气候冷却导致沉积速率突然下降,与麦克默多火山群的形成同步。麦克默多火山群是世界上最大的碱性矿带,分别延伸至横贯南极山脉和罗斯海西部的内陆和近海。在这里,我们使用热力学和地貌演化耦合数值模型来量化由于侵蚀/沉积速率变化而在缓慢伸展的裂谷盆地中产生的熔体。该模型结合了延伸过程中岩石圈和下伏地幔的粘弹塑性变形、部分岩石熔融以及地表地形的线性山坡扩散。参数研究涵盖了一系列缓慢延伸率、地壳厚度、地幔潜在温度和扩散系数。数值模拟成功地再现了罗斯海西部 150-200 千米宽的延伸以及中新世至今的星体层熔体生成(麦克默多火山群)。研究结果进一步表明,缓慢的裂谷岩浆作用对盆地内的沉积物沉积高度敏感,沉积物沉积抑制了地幔减压熔融,推迟了地壳破裂。因此,区域气候驱动的沉积速率变化很可能影响了南极洲罗斯海西部的同步裂谷岩浆史,证明了地表和深层过程之间的相互作用在整个伸展环境中的相关性。
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来源期刊
Global and Planetary Change
Global and Planetary Change 地学天文-地球科学综合
CiteScore
7.40
自引率
10.30%
发文量
226
审稿时长
63 days
期刊介绍: The objective of the journal Global and Planetary Change is to provide a multi-disciplinary overview of the processes taking place in the Earth System and involved in planetary change over time. The journal focuses on records of the past and current state of the earth system, and future scenarios , and their link to global environmental change. Regional or process-oriented studies are welcome if they discuss global implications. Topics include, but are not limited to, changes in the dynamics and composition of the atmosphere, oceans and cryosphere, as well as climate change, sea level variation, observations/modelling of Earth processes from deep to (near-)surface and their coupling, global ecology, biogeography and the resilience/thresholds in ecosystems. Key criteria for the consideration of manuscripts are (a) the relevance for the global scientific community and/or (b) the wider implications for global scale problems, preferably combined with (c) having a significance beyond a single discipline. A clear focus on key processes associated with planetary scale change is strongly encouraged. Manuscripts can be submitted as either research contributions or as a review article. Every effort should be made towards the presentation of research outcomes in an understandable way for a broad readership.
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