Identifying the Greatest Earthquakes of the Past 2000 Years at the Nehalem River Estuary, Northern Oregon Coast, USA

Alan R. Nelson; Andrea D. Hawkes; Yuki Sawai; Simon E. Engelhart; Rob Witter; Wendy C. Grant-Walter; Lee-Ann Bradley; Tina Dura; Niamh Cahill; Ben Horton

doi:10.5334/oq.70

Identifying the Greatest Earthquakes of the Past 2000 Years at the Nehalem River Estuary, Northern Oregon Coast, USA

Alan R. Nelson^*, Andrea D. Hawkes, Yuki Sawai, Simon E. Engelhart, Rob Witter, Wendy C. Grant-Walter, Lee-Ann Bradley, Tina Dura, Niamh Cahill, Ben Horton

^*Corresponding author for this work

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

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Abstract

We infer a history of three great megathrust earthquakes during the past 2000 years at the Nehalem River estuary based on the lateral extent of sharp (≤3 mm) peat-mud stratigraphic contacts in cores and outcrops, coseismic subsidence as interpreted from fossil diatom assemblages and reconstructed with foraminiferal assemblages using a Bayesian transfer function, and regional correlation of ¹⁴C-modeled ages for the times of subsidence. A subsidence contact from 1700 CE (contact A), sometimes overlain by tsunami-deposited sand, can be traced over distances of 7 km. Contacts B and D, which record subsidence during two earlier megathrust earthquakes, are much less extensive but are traced across a 700-m by 270-m tidal marsh. Although some other Cascadia studies report evidence for an earthquake between contacts B and D, our lack of extensive evidence for such an earthquake may result from the complexities of preserving identifiable evidence of it in the rapidly shifting shoreline environments of the lower river and bay. Ages (95% intervals) and subsidence for contacts are: A, 1700 CE (1.1 ± 0.5 m); B, 942–764 cal a BP (0.7 ± 0.4 m and 1.0 m ± 0.4 m); and D, 1568–1361 cal a BP (1.0 m ± 0.4 m). Comparisons of contact subsidence and the degree of overlap of their modeled ages with ages for other Cascadia sites are consistent with megathrust ruptures many hundreds of kilometers long. But these data cannot conclusively distinguish among different types or lengths of ruptures recorded by the three great earthquake contacts at the Nehalem River estuary. © 2020 The Author(s).

Original language	English
Article number	2
Journal	Open Quaternary
Volume	6
Online published	14 Jan 2020
DOIs	https://doi.org/10.5334/oq.70
Publication status	Published - 2020
Externally published	Yes

Funding

This work was supported by the Earthquake Hazards Program of the U.S. Geological Survey (USGS) and by NSF grants EAR-1419846, EAR-1419844, and EAR-1419824 to Hawkes, Engelhart, and Horton, respectively. Able field assistance was provided by Rich Briggs (USGS, Golden, Colorado), Zeb Maharrey (USGS, Golden, Colorado), Candice Grand Pre (University of Pennsylvania), SeanPaul La Selle (USGS, Santa Cruz, California), and J. Scott Padgett (University of Rhode Island). Some field equipment was supplied by the State of Oregon Department of Geology and Mineral Industries. Collection and preparation of diatom samples by Sawai were supported by the Geological Survey of Japan and a Japan Society for the Promotion of Science postdoctoral fellowship for research abroad. Brian Atwater (USGS, Seattle, Washington) guided Grant?s work (non-thesis M.S. degree, University of Washington, Seattle, 1992) in the Nehalem River estuary (1987?1994). The National Ocean Sciences Accelerator Mass Spectrometry facility (NOSAMS) at Woods Hole Oceanographic Institution (WHOI; Woods Hole, Massa-chusetts) supported the analysis of four AMS14C samples during Hawkes? WHOI NOSAMS postdoctoral fellowship. Jamie Delano (USGS, Golden, Colorado), Zeb Maharrey, and Nadine Reitman helped with graphics. We thank Brian Atwater for notes from a 1997 visit to the East Bank outcrop, and for comments on an earlier version of the paper. This version of the paper, which is a contribution to IGCP Project 639 ?Sea-Level Changes from Minutes to Millennia,? was also improved through the suggestions of Andrew Kemp, Ian Hutchinson, and an anonymous reviewer.

Research Keywords

Bayesian transfer function
Cascadia subduction zone
Coseismic subsidence
Earthquake hazards
Paleoseismology
Salt-marsh stratigraphy
Sea-level changes
Tidal foraminifera and diatoms

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title = "Identifying the Greatest Earthquakes of the Past 2000 Years at the Nehalem River Estuary, Northern Oregon Coast, USA",

abstract = "We infer a history of three great megathrust earthquakes during the past 2000 years at the Nehalem River estuary based on the lateral extent of sharp (≤3 mm) peat-mud stratigraphic contacts in cores and outcrops, coseismic subsidence as interpreted from fossil diatom assemblages and reconstructed with foraminiferal assemblages using a Bayesian transfer function, and regional correlation of 14C-modeled ages for the times of subsidence. A subsidence contact from 1700 CE (contact A), sometimes overlain by tsunami-deposited sand, can be traced over distances of 7 km. Contacts B and D, which record subsidence during two earlier megathrust earthquakes, are much less extensive but are traced across a 700-m by 270-m tidal marsh. Although some other Cascadia studies report evidence for an earthquake between contacts B and D, our lack of extensive evidence for such an earthquake may result from the complexities of preserving identifiable evidence of it in the rapidly shifting shoreline environments of the lower river and bay. Ages (95% intervals) and subsidence for contacts are: A, 1700 CE (1.1 ± 0.5 m); B, 942–764 cal a BP (0.7 ± 0.4 m and 1.0 m ± 0.4 m); and D, 1568–1361 cal a BP (1.0 m ± 0.4 m). Comparisons of contact subsidence and the degree of overlap of their modeled ages with ages for other Cascadia sites are consistent with megathrust ruptures many hundreds of kilometers long. But these data cannot conclusively distinguish among different types or lengths of ruptures recorded by the three great earthquake contacts at the Nehalem River estuary. {\textcopyright} 2020 The Author(s).",

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author = "Nelson, {Alan R.} and Hawkes, {Andrea D.} and Yuki Sawai and Engelhart, {Simon E.} and Rob Witter and Grant-Walter, {Wendy C.} and Lee-Ann Bradley and Tina Dura and Niamh Cahill and Ben Horton",

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T1 - Identifying the Greatest Earthquakes of the Past 2000 Years at the Nehalem River Estuary, Northern Oregon Coast, USA

AU - Nelson, Alan R.

AU - Hawkes, Andrea D.

AU - Sawai, Yuki

AU - Engelhart, Simon E.

AU - Witter, Rob

AU - Grant-Walter, Wendy C.

AU - Bradley, Lee-Ann

AU - Dura, Tina

AU - Cahill, Niamh

AU - Horton, Ben

PY - 2020

Y1 - 2020

N2 - We infer a history of three great megathrust earthquakes during the past 2000 years at the Nehalem River estuary based on the lateral extent of sharp (≤3 mm) peat-mud stratigraphic contacts in cores and outcrops, coseismic subsidence as interpreted from fossil diatom assemblages and reconstructed with foraminiferal assemblages using a Bayesian transfer function, and regional correlation of 14C-modeled ages for the times of subsidence. A subsidence contact from 1700 CE (contact A), sometimes overlain by tsunami-deposited sand, can be traced over distances of 7 km. Contacts B and D, which record subsidence during two earlier megathrust earthquakes, are much less extensive but are traced across a 700-m by 270-m tidal marsh. Although some other Cascadia studies report evidence for an earthquake between contacts B and D, our lack of extensive evidence for such an earthquake may result from the complexities of preserving identifiable evidence of it in the rapidly shifting shoreline environments of the lower river and bay. Ages (95% intervals) and subsidence for contacts are: A, 1700 CE (1.1 ± 0.5 m); B, 942–764 cal a BP (0.7 ± 0.4 m and 1.0 m ± 0.4 m); and D, 1568–1361 cal a BP (1.0 m ± 0.4 m). Comparisons of contact subsidence and the degree of overlap of their modeled ages with ages for other Cascadia sites are consistent with megathrust ruptures many hundreds of kilometers long. But these data cannot conclusively distinguish among different types or lengths of ruptures recorded by the three great earthquake contacts at the Nehalem River estuary. © 2020 The Author(s).

AB - We infer a history of three great megathrust earthquakes during the past 2000 years at the Nehalem River estuary based on the lateral extent of sharp (≤3 mm) peat-mud stratigraphic contacts in cores and outcrops, coseismic subsidence as interpreted from fossil diatom assemblages and reconstructed with foraminiferal assemblages using a Bayesian transfer function, and regional correlation of 14C-modeled ages for the times of subsidence. A subsidence contact from 1700 CE (contact A), sometimes overlain by tsunami-deposited sand, can be traced over distances of 7 km. Contacts B and D, which record subsidence during two earlier megathrust earthquakes, are much less extensive but are traced across a 700-m by 270-m tidal marsh. Although some other Cascadia studies report evidence for an earthquake between contacts B and D, our lack of extensive evidence for such an earthquake may result from the complexities of preserving identifiable evidence of it in the rapidly shifting shoreline environments of the lower river and bay. Ages (95% intervals) and subsidence for contacts are: A, 1700 CE (1.1 ± 0.5 m); B, 942–764 cal a BP (0.7 ± 0.4 m and 1.0 m ± 0.4 m); and D, 1568–1361 cal a BP (1.0 m ± 0.4 m). Comparisons of contact subsidence and the degree of overlap of their modeled ages with ages for other Cascadia sites are consistent with megathrust ruptures many hundreds of kilometers long. But these data cannot conclusively distinguish among different types or lengths of ruptures recorded by the three great earthquake contacts at the Nehalem River estuary. © 2020 The Author(s).

KW - Bayesian transfer function

KW - Cascadia subduction zone

KW - Coseismic subsidence

KW - Earthquake hazards

KW - Paleoseismology

KW - Salt-marsh stratigraphy

KW - Sea-level changes

KW - Tidal foraminifera and diatoms

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U2 - 10.5334/oq.70

DO - 10.5334/oq.70

M3 - RGC 21 - Publication in refereed journal

SN - 2055-298X

VL - 6

JO - Open Quaternary

JF - Open Quaternary

M1 - 2

ER -

Identifying the Greatest Earthquakes of the Past 2000 Years at the Nehalem River Estuary, Northern Oregon Coast, USA

Abstract

Funding

Research Keywords

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