Abstract
Abstract Cenozoic extension of the Qinling range-Weihe Graben system has occurred in response to the uplift and growth of the Tibetan Plateau. Rapid exhumation of the northern Qinling range since the late Miocene is also regarded as resulting from the eastward expansion of the northeast part of Tibet. Tectonic evidence of this in the landscape remains unclear, but the fluvial system can provide a sensitive proxy record of tectonic forcing through space and over time scales of 105–107 a. Here, we present a study of channel profiles in the northern Qinling range, which forms a footwall highland separated from the southern Weihe Graben by active normal faults. We identify a population of knickpoints that separate river profiles with a gentle upstream gradient from steeper downstream reaches. Above the knickpoints, steepness indices increase from the central part towards the west and east, whereas channel steepness shows its highest values in the Huaxian-Huayin section. We observed no systematic changes of channel steepness pattern as a function of rock resistance, drainage area, or channel concavity. Correlation analysis between channel steepness and basin elevation and relief documents the control of tectonic forcing on regional topography. While bearing no relation to geological outcrop boundaries, the knickpoints show a strong correlation between retreat distance, catchment area, and river length. We infer that the knickpoints formed in response to an increase in mountain uplift rates and retreated as a kinematic wave. Under linear slope exponent n, we calibrated channel erodibility K~1.00±0.44×10−6 m0.1/a and derived knickpoint ages of 5.59±1.80 Ma. Combining the ages of onset of active faulting and mountain growth in the NE Tibetan Plateau (8–10 Ma, e.g., Liupan Shan, Jishi Shan, and eastern segments of the Haiyuan and Kunlun faults) and in the southwest Qinling range (9–4 Ma), we conclude that growth of the NE Tibetan Plateau began in the mid-Miocene time and expanded eastwards to the Qinling range-Weihe Graben during the late Miocene and early Pliocene.
Highlights
Knowledge of both spatial and temporal changes in rock uplift rates places constraints on the geometry and tectonic activity of fault systems [1, 2], provides a diagnostic test for evaluating regional landscape evolution models [3, 4], and constitutes a foundation for understanding large-scale lithospheric deformation dynamics [5, 6]
Studies on active tectonics (103– 104 a) and low-temperature thermochronology (>106 a) provide details on long-term rates and patterns, which have always been focused on deformed geologic structures, wellexposed fault outcrops, and available field samples [10,11,12]
We propose that the periodic variation in channel steepness might indicate that, for each segment, fault throw rate decreases from the fault center to each of its tips
Summary
Knowledge of both spatial and temporal changes in rock uplift rates places constraints on the geometry and tectonic activity of fault systems [1, 2], provides a diagnostic test for evaluating regional landscape evolution models [3, 4], and constitutes a foundation for understanding large-scale lithospheric deformation dynamics [5, 6]. Studies on active tectonics (103– 104 a) and low-temperature thermochronology (>106 a) provide details on long-term rates and patterns, which have always been focused on deformed geologic structures, wellexposed fault outcrops, and available field samples [10,11,12]. For an absence of such strict conditions, some geomorphic features (e.g., topographic relief and slope-length index)
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