Evaluating Models for Lithospheric Loss and Intraplate Volcanism Beneath the Central Appalachian Mountains

Abstract: The eastern margin of North America has been shaped by a series of tectonic events including the Paleozoic Appalachian Orogeny and the breakup of Pangea during the Mesozoic. For the past ∼200 Ma, eastern North America has been a passive continental margin; however, there is evidence in the Central Appalachian Mountains for post-rifting modification of lithospheric structure. This evidence includes two co-located pulses of magmatism that post-date the rifting event (at 152 and 47 Ma) along with low seismic velo… Show more

“…The high velocity lithosphere shallows toward the ocean until it meets the most prominent slow-velocity feature in our model, in Virginia (∼38.5°N, 79°W). This is the previously imaged low-velocity HA (e.g., Long et al, 2021;Savage et al, 2017;Shen & Ritzwoller, 2016;Wagner et al, 2018). This feature dips oceanward from the surface.…”

“…EDC is an attractive hypothesis for explaining a variety of discontinuous, short-wavelength, upper mantle velocity features imaged here and elsewhere without invoking multiple processes (Menke et al, 2016). Another appealing explanation of the HA is shear-driven upwelling (e.g., Long et al, 2021). This is highly localized asthenospheric upwelling caused by lithospheric motion in the case that the LAB has concave-down divots (Figure 7; Conrad et al, 2010).…”

“…Conversely, the slow velocity features may indicate lithospheric delamination and asthenospheric upwelling, which could also account for enigmatic Eocene volcanism (Figure 1; e.g., Biryol et al, 2016;Mazza et al, 2014). Shear-driven upwelling of asthenosphere into a divot in the moving lithosphere has also been suggested to explain mantle anomalies and volcanism (Long et al, 2021). Margin-parallel shear-wave splitting results offshore have been interpreted as reflecting large scale density-driven flow (Lynner & Bodmer, 2017).…”

Mantle Structure and Flow Across the Continent‐Ocean Transition of the Eastern North American Margin: Anisotropic S‐Wave Tomography

“…The high velocity lithosphere shallows toward the ocean until it meets the most prominent slow-velocity feature in our model, in Virginia (∼38.5°N, 79°W). This is the previously imaged low-velocity HA (e.g., Long et al, 2021;Savage et al, 2017;Shen & Ritzwoller, 2016;Wagner et al, 2018). This feature dips oceanward from the surface.…”

“…EDC is an attractive hypothesis for explaining a variety of discontinuous, short-wavelength, upper mantle velocity features imaged here and elsewhere without invoking multiple processes (Menke et al, 2016). Another appealing explanation of the HA is shear-driven upwelling (e.g., Long et al, 2021). This is highly localized asthenospheric upwelling caused by lithospheric motion in the case that the LAB has concave-down divots (Figure 7; Conrad et al, 2010).…”

“…Conversely, the slow velocity features may indicate lithospheric delamination and asthenospheric upwelling, which could also account for enigmatic Eocene volcanism (Figure 1; e.g., Biryol et al, 2016;Mazza et al, 2014). Shear-driven upwelling of asthenosphere into a divot in the moving lithosphere has also been suggested to explain mantle anomalies and volcanism (Long et al, 2021). Margin-parallel shear-wave splitting results offshore have been interpreted as reflecting large scale density-driven flow (Lynner & Bodmer, 2017).…”

Mantle Structure and Flow Across the Continent‐Ocean Transition of the Eastern North American Margin: Anisotropic S‐Wave Tomography

“…Superimposed on the prevailing lithologic fabric of the Appalachian landscape are smaller geomorphic signals of mid‐Cenozoic topographic rejuvenation, responsible for an estimated 40–400 m of additional relief (Gallen et al., 2013; Rowley et al., 2013). Absent of active tectonic uplift, potential external drivers of this rejuvenation include buoyant mantle upwelling (Gallen et al., 2013; Long et al., 2021; Moucha et al., 2008; Rowley et al., 2013; S. R. Miller et al., 2013), and climatic fluctuations (Harbor et al., 2005; Prince & Spotila, 2013). Compelling autogenic controls have been proposed as well, namely drainage reorganization/stream capture events driven by divide asymmetry (Prince et al., 2010, 2011) or exhumation of heterogeneous bedrock (Gallen, 2018).…”

Uncovering the Controls on Fluvial Bedrock Erodibility and Knickpoint Expression: A High‐Resolution Comparison of Bedrock Properties Between Knickpoints and Non‐Knickpoint Reaches

“…The precise positioning of the LAB provides good constraints on the evolution of cratons and orogens, such as lithospheric thinning owing to extension (e.g., Buck, 1991) or detachment (e.g., Davies & Von Blanckenburg, 1995; Kosarev et al., 1999) and lithospheric thickening owing to collision (e.g., Houseman et al., 1981). A series of methods, such as receiver functions (P‐ and S‐wave receiver function; PRF and SRF, respectively), SS precursors, and body‐wave and surface‐wave tomography, have been developed to detect the lithospheric thickness at both global (Bijwaard & Spakman, 2000; Ritsema et al., 2004; Ritzwoller et al., 2002) and local scales (Long et al., 2021; Mojaver et al., 2021; Rawlinson & Fishwick, 2012; Zhang et al., 2021).…”

A Generalized Strategy From S‐Wave Receiver Functions Reveals Distinct Lateral Variations of Lithospheric Thickness in Southeastern Tibet