Continental‐Scale Landscape Evolution: A History of North American Topography

Fernandes, Victoria M.; White, Nicky; Whittaker, Alexander C.

doi:10.1029/2018jf004979

Cited by 31 publications

(54 citation statements)

References 228 publications

(438 reference statements)

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“…The long wavelength flow directions of large western North American rivers are therefore likely to be no older than the ongoing mantle support. This result is consistent with geomorphic and provenance studies, which indicate that the present day planform of rivers draining western North America has been broadly stable during the last few tens of millions of years (Blum & Pecha, 2014;Fernandes et al, 2019;Galloway et al, 2011).…”

Section: Synthetic and Probabilistic Landscapessupporting

confidence: 90%

“…Second, calculated dynamic topography was added to this surface by converting long wavelength free‐air gravity anomalies using an admittance of 25 mGal/km (Figure 1b). We note that this surface is similar to cumulative post‐Cretaceous uplift mapped using the distribution of marine rocks in western North America, and its crest coincides with loci of Cenozoic basaltic magmatism (Fernandes et al., 2019; Klocking et al., 2018). Simulations of North American landscape evolution parameterized in a similar way have yielded broadly stable Cenozoic drainage planforms (Fernandes et al., 2019).…”

Section: Synthetic and Probabilistic Landscapessupporting

confidence: 66%

“…We note that this surface is similar to cumulative post‐Cretaceous uplift mapped using the distribution of marine rocks in western North America, and its crest coincides with loci of Cenozoic basaltic magmatism (Fernandes et al., 2019; Klocking et al., 2018). Simulations of North American landscape evolution parameterized in a similar way have yielded broadly stable Cenozoic drainage planforms (Fernandes et al., 2019). In the third step, the resultant surface is eroded so that channels form using the well‐known stream power formulation of fluvial erosion, which has the form of a nonlinear advective equation

\frac{\partial z}{\partial t} = - v A^{m} \nabla z,

where z is elevation, t is time, and A is upstream drainage area (Howard & Kerby, 1983; Rosenbloom & Anderson, 1994; Tinkler & Wohl, 1998; Whipple & Tucker, 1999).…”

Section: Synthetic and Probabilistic Landscapessupporting

confidence: 66%

“…Gravity anomalies, tomographic models, magmatism and isostatic calculations, which include crustal thickness estimates, indicate that western North American topography is principally a consequence of subcrustal support moderated by tectonic and erosional processes (Atwater, 1970; Fernandes et al., 2019; Wernicke, 1985). A guide to the amplitude and wavelength of subplate support is the transfer function (admittance) between long wavelength free‐air gravity and topography (McKenzie, 2010).…”

Section: Wavelet Analysismentioning

confidence: 99%

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Scale‐Dependent Flow Directions of Rivers and the Importance of Subplate Support

Lipp

2021

Geophysical Research Letters

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Despite its general importance, the way in which drainage networks acquire their planforms is poorly understood across different length scales. Evolution of the solid Earth (orogenesis, crustal thickening, and mantle convection) is an obvious means to determine flow paths by generating extensive areas of elevated terrain (e.g., Cox, 1989). Lithologic and internal hydraulic processes can also generate complex paths such as meanders (Scheingross et al., 2020). Drainage planforms can also be determined by antecedence (preexisting flow directions) resulting in hysteresis behavior and they can be modified by drainage capture/piracy (e.g., Shugar et al., 2017). Anthropic and biotic processes are also important means by which drainage networks can be generated and modified (Anderson & Anderson, 2010; Rinaldo et al., 1993). The processes controlling drainage planforms are, to some degree, scale dependent. For example, fluvial hydraulics can generate meanders at scales <10 km. This process is independent of vertical lithospheric motion which can determine the paths of rivers at scales >1,000 km. In this contribution, we are concerned with separating the flow directions of rivers into constituent scales and identifying where the dominant signals are generated. It provides a basis for comparing flow directions to independent (e.g., geologic) observations at appropriate scales.

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Section: Synthetic and Probabilistic Landscapessupporting

confidence: 90%

Section: Synthetic and Probabilistic Landscapessupporting

confidence: 66%

\frac{\partial z}{\partial t} = - v A^{m} \nabla z,

where z is elevation, t is time, and A is upstream drainage area (Howard & Kerby, 1983; Rosenbloom & Anderson, 1994; Tinkler & Wohl, 1998; Whipple & Tucker, 1999).…”

Section: Synthetic and Probabilistic Landscapessupporting

confidence: 66%

Section: Wavelet Analysismentioning

confidence: 99%

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Scale‐Dependent Flow Directions of Rivers and the Importance of Subplate Support

Lipp

2021

Geophysical Research Letters

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“…In the middle to late Miocene, active mountain building in East Asia, the Himalayas, and Southeast Asia to Oceania produced highly heterogeneous habitats represented by a wide altitudinal range 26,27,29 , which, together with high precipitation caused mainly by the intensi cation of Asian monsoons, greatly promoted the rapid rediversi cation of subgenera Tsutsusi and Hymenanthes and section Vireya of the subgenus Rhododendron and the evolution of new lineages, leading to the highest diversi cation rate of this genus. Although mountain building also occurred in southern Europe and western North America in the Neogene 29,30 , it was not active as in Asia, and the relatively dry habitats limited the rediversi cation of Rhododendron. This also explains why only a few intercontinental dispersals occurred within subgenera of this genus, except the deciduous subgenus Pentanthera, which grows in very low altitudes.…”

Section: Discussionmentioning

confidence: 99%

Spatiotemporal evolution of the global species diversity of Rhododendron

Xia

Yang

et al. 2020

Preprint

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How large cosmopolitan plant genera survived great environmental changes and rediversified remains largely unknown. Here we investigated mechanisms underlying the rediversification of Rhododendron, the largest genus of woody plants in the Northern Hemisphere. Using 3437 orthologous nuclear genes, we reconstructed the first completely resolved and dated phylogeny of Rhododendron. We found that most extant species of Rhododendron originated by Neogene rediversification from Paleogene relicts during southern migration. The geographically uneven rediversification of Rhododendron led to a much higher diversity in Asia than in other continents, which was driven by two main environmental variables, i.e., habitat heterogeneity represented by elevation range and annual precipitation related to the Asian monsoons, and can be explained by leaf functional traits that show strong phylogenetic signals and correspond well with leaf-forms and geographical regions. Our study highlights the importance of integrating phylogenomic and ecological analyses in revealing the spatiotemporal evolution of species-rich cosmopolitan plant genera.

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