Temperature, Deformation, and Mass Transfer in a Hot Orogen: Insights From Thermokinematic Forward Models for Far Western Nepal

IF 3.3 1区 地球科学 Q1 GEOCHEMISTRY & GEOPHYSICS Tectonics Pub Date : 2023-08-13 DOI:10.1029/2023TC007912
M. Braza, N. McQuarrie, D. Robinson, L. Webb
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Abstract

Exhumation and cooling pathways of mid‐crustal metamorphic rocks in the western Nepal Himalaya can be replicated by fold‐thrust belt structures with displacement localized along discrete décollements. New and published muscovite 40Ar/39Ar, zircon U‐Th/He, and apatite fission track cooling ages, peak temperature estimates, geologic mapping, and basin data are integrated with thermokinematic forward models to constrain the geometry, kinematics, and rates of shortening in far western Nepal. The best fit to peak temperatures, cooling ages, and basin accumulation data is achieved with a largely in‐sequence kinematic order, with out‐of‐sequence motion on the Ramgarh‐Munsiari thrust. Fast rates (∼20–40 mm/yr) are required during shortening on early, large displacement faults at ∼23–12 Ma and decrease to ∼10–15 mm/yr during formation of the Lesser Himalayan duplex until ∼1 Ma. Thermokinematic models highlight the relationship between peak temperature, geometry, and shortening on the large displacement Main Central and Ramgarh‐Munsiari thrusts. In the thermokinematic models, we observe a relationship between the location of frontal ramps for the faults that displace lower Lesser Himalayan units and the ∼375°C isotherm, immediately before the ramp becomes active. These correlations suggest that temperature exerts a first‐order control on thrust geometry in a hot orogen. Viable models highlight the position of active ramps, kinematic order of faults, timing of fault motion, and reduction in shortening rates that are required to reproduce the surface geology, basin accumulation, peak temperature conditions, and timing of exhumation. Cooling ages are far more sensitive to the age of fault motion than the rate of fault motion.
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热造山带中的温度、变形和质量传递:从尼泊尔西部的热运动学正演模型看
尼泊尔-喜马拉雅西部中地壳变质岩的剥蚀和冷却路径可以用褶皱冲断带构造来复制,这些构造的位移定位于离散的变径段。新的和已发表的白云母40Ar/39Ar、锆石U‐Th/He和灰石裂变径迹冷却年龄、峰值温度估计、地质制图和盆地数据与热运动学正推模型相结合,以约束尼泊尔西部遥远地区的几何、运动学和缩短率。峰值温度、冷却年龄和盆地成藏数据的最佳拟合是通过在很大程度上按序列的运动顺序实现的,其中包括Ramgarh - Munsiari逆冲构造的非序列运动。在早期大位移断层在~ 23-12 Ma的缩短过程中,需要快速的速率(~ 20-40 mm/yr),在小喜马拉雅双相形成期间,速率降至~ 10-15 mm/yr,直到~ 1 Ma。热运动学模型强调了大位移主中央和Ramgarh - Munsiari逆冲断层的峰值温度、几何形状和缩短之间的关系。在热动力学模型中,我们观察到,在斜坡开始活动之前,取代下喜马拉雅单元的断层锋面斜坡的位置与~ 375°C等温线之间存在关系。这些相关性表明,温度对热造山带的逆冲构造具有一级控制作用。可行的模型强调了活动斜坡的位置、断层的运动顺序、断层运动的时间,以及再现地表地质、盆地聚集、峰值温度条件和挖掘时间所需的缩短率的降低。冷却年龄对断层运动年龄的敏感性远高于断层运动速率。
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来源期刊
Tectonics
Tectonics 地学-地球化学与地球物理
CiteScore
7.70
自引率
9.50%
发文量
151
审稿时长
3 months
期刊介绍: Tectonics (TECT) presents original scientific contributions that describe and explain the evolution, structure, and deformation of Earth¹s lithosphere. Contributions are welcome from any relevant area of research, including field, laboratory, petrological, geochemical, geochronological, geophysical, remote-sensing, and modeling studies. Multidisciplinary studies are particularly encouraged. Tectonics welcomes studies across the range of geologic time.
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