Major reorganization of the Snake River modulated by passage of the Yellowstone Hotspot

Paul K Link,Chris Holm-Denoma,Lydia M Staisch,John Lasher,Jeremy A Alexander,Jim E O’Connor,Charles M Cannon

doi:10.1130/b36174.1

Abstract

ABSTRACT The details and mechanisms for Neogene river reorganization in the U.S. Pacific Northwest and northern Rocky Mountains have been debated for over a century with key implications for how tectonic and volcanic systems modulate topographic development. To evaluate paleo-drainage networks, we produced an expansive data set and provenance analysis of detrital zircon U-Pb ages from Miocene to Pleistocene fluvial strata along proposed proto-Snake and Columbia River pathways. Statistical comparisons of Miocene-Pliocene detrital zircon spectra do not support previously hypothesized drainage routes of the Snake River. We use detrital zircon unmixing models to test prior Snake River routes against a newly hypothesized route, in which the Snake River circumnavigated the northern Rocky Mountains and entered the Columbia Basin from the northeast prior to incision of Hells Canyon. Our proposed ancestral Snake River route best matches detrital zircon age spectra throughout the region. Furthermore, this northerly Snake River route satisfies and provides context for shifts in the sedimentology and fish faunal assemblages of the western Snake River Plain and Columbia Basin through Miocene–Pliocene time. We posit that eastward migration of the Yellowstone Hotspot and its effect on thermally induced buoyancy and topographic uplift, coupled with volcanic densification of the eastern Snake River Plain lithosphere, are the primary mechanisms for drainage reorganization and that the eastern and western Snake River Plain were isolated from one another until the early Pliocene. Following this basin integration, the substantial increase in drainage area to the western Snake River Plain likely overtopped a bedrock threshold that previously contained Lake Idaho, which led to incision of Hells Canyon and establishment of the modern Snake and Columbia River drainage network.

Highlights

Mantle dynamics and their impact on the thermomechanical state of the overlying lithosphere are often invoked to explain topographic change (Stanley et al, 2013, 2015); few geologic records document the interplay of competing drivers of landscape evolution
Central to the history of the Snake River is Hells Canyon, through which the Snake River currently carves the deepest canyon in North America (Fig. 1), and its relation to draining Lake Idaho, a massive lake centered in the western Snake River Plain during late Miocene–Pliocene time (Wood and Clemens, 2002; Fig. 2)
Based on the geographic and temporal distributions of strata analyzed for detrital zircon provenance and paleontology, we propose that the upper Snake River flowed into the Columbia Basin via an alternative route to the north that circumvented the western Snake River Plain (Fig. 2)

Summary

Introduction

Mantle dynamics and their impact on the thermomechanical state of the overlying lithosphere are often invoked to explain topographic change (Stanley et al, 2013, 2015); few geologic records document the interplay of competing drivers of landscape evolution. On the basis of anomalous tributary orientations and a thick sequence of lake strata upstream of Hells Canyon (Fig. 1), early researchers hypothesized that the Snake River likely changed its course in recent geologic time, but these studies disagree upon the mechanism of landscape evolution and interpret vastly different pathways for the ancestral Snake River (Lindgren, 1898; Livingston, 1928; Wheeler and Cook, 1954). More recent studies of fish and rodent fossils from the western Snake River Plain and Columbia Basin suggest that Lake Idaho was isolated from the Columbia Basin until the late Pliocene, which lends support to the Sacramento drainage route of the Snake River (Repenning et al, 1995; Smith et al, 2000; Stearley and Smith, 2016). Detrital zircon age distributions of Miocene–Pliocene Ringold Formation lacustrine deposits from the Columbia Basin suggest that the Snake River was part of the Columbia River drainage network over the same time period (Staisch et al, 2018)

Methods

Results

Discussion

Conclusion