Salt marshes as late Holocene tide gauges

Barlow, Natasha; Shennan, Ian; Long, Antony J.; Gehrels, W. Roland; Saher, Margot; Woodroffe, Sarah A.; Hillier, Caroline

doi:10.1016/j.gloplacha.2013.03.003

Cited by 106 publications

(110 citation statements)

References 168 publications

(230 reference statements)

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“…These are mainly limiting dates, either peat or wood samples indicating terrestrial or freshwater maximum RSL elevations, or marine mollusc or foraminifera samples indicating minimum RSL elevations. Major advances in applying microfossil-based transfer methods to RSL reconstructions (summaries include Barlow et al, 2013;Kemp and Telford, 2015) and how these advances promoted radiocarbon-dating sampling strategies through whole units rather than concentrating on the boundaries between units led us to refine and expand the number of indicative meanings (Table 1). We have revised the age calibrations for all samples, using the latest downloadable version of CALIB (Stuiver et al, 2017) and the IntCal13 or Marine13 calibration curve option as relevant to each sample.…”

Section: Key Enhancements In the 2017 Updatementioning

confidence: 99%

Relative sea-level changes and crustal movements in Britain and Ireland since the Last Glacial Maximum

Shennan

Bradley

Edwards

2018

Quaternary Science Reviews

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Section: Key Enhancements In the 2017 Updatementioning

confidence: 99%

Relative sea-level changes and crustal movements in Britain and Ireland since the Last Glacial Maximum

Shennan

Bradley

Edwards

2018

Quaternary Science Reviews

Self Cite

112

165

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“…changes in water properties or tidal range, can alter the depth at which a particular species can survive (Hibbert et al, 2016). At higher latitudes, reconstructions of saltmarsh environments have proved very useful for 350 determining not only past changes in water depth, but also more subtle information relating to whether sea level was rising or falling in the past (Barlow et al, 2013). Finally, if past shorelines can be continuously reconstructed over length scales of a few kilometres or more, then the subsequent warping of these contemporaneous surfaces provides a powerful constraint on GIA (McConnell, 1968).…”

Section: Relative Sea-level Data 335mentioning

confidence: 99%

Glacial Isostatic Adjustment modelling: historical perspectives, recent advances, and future directions

Whitehouse¹

2018

Preprint

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Abstract. Glacial Isostatic Adjustment (GIA) describes the response of the solid Earth, the gravitational field, and 5 consequently the oceans to the growth and decay of the global ice sheets. It is a process that takes place relatively rapidly, triggering 100 m-scale changes in sea level and solid Earth deformation over just a few tens of thousands of years. Indeed, the first-order effects of GIA could already be quantified several hundred years ago without reliance on precise measurement techniques and scientists have been developing a unifying theory for the observations for over 200 years. Progress towards this goal required a number of significant breakthroughs to be made, including the recognition that ice sheets were once 10 more extensive, the solid Earth changes shape over time, and gravity plays a central role in determining the pattern of sealevel change. This article describes in detail the historical development of the field of GIA and an overview of the processes involved. Significant recent progress has been made as concepts associated with GIA have begun to be incorporated into parallel fields of research; these advances are discussed, along with the role that GIA is likely to play in addressing outstanding research questions within the field of Earth system modelling. 15

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“…The amount of RSL rise projected for New York City by 2100 CE exceeds the global mean because of local-to regional-scale contributions from ongoing GIA (e.g., Roy and Peltier, 2015), response to such short-lived trends and because the sediment slices used to produce the e only multi-decadal trends (e.g., Kemp et al, 2011;Barlow et al, 2013). Secondly, they are unhindered by the available record length, meaning that it could be possible to detect accelerating sea-level rise now rather than waiting for additional years of measurements, which may delay efforts to plan for, or manage the effects of, future sea-level rise.…”

Section: Implications For 21 St Century Sea-level Change In New Yorkmentioning

confidence: 99%

Relative sea-level trends in New York City during the past 1500 years

et al. 2017

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foraminifera, salt marsh, Bayesian transfer function, carbon isotope, The Bronx, sedimentation Abstract: New York City is at risk from 21st century relative sea-level rise because it is likely to experience a regional trend that exceeds the global mean and has high concentrations of low-lying infrastructure and socio economic activity. To provide a long-term context for anticipated future trends, we reconstructed relative sea-level change during the past ~1500 years using a sediment core from a salt marsh at Pelham Bay in The Bronx. Foraminifera and bulk sediment δ13C values were used as sea level indicators, while the history of sediment accumulation was established by radiocarbon dating of plant macrofossils and recognition of pollution and land-use trends of known age in down-core elemental, isotopic, and pollen profiles. The reconstruction was generated within a Bayesian hierarchical model comprised of three modules (calibration, chronology, and process) to accommodate multiple proxies and to provide a unified statistical framework for quantifying uncertainty. We show that relative sea level in New York City rose by ~1.70 m since ~575 CE, of which ~0.38 m occurred after 1850 CE. The rate of relative sea level rise increased markedly between 1852 CE and 1911 CE, which coincides with other reconstructions along the U.S. Atlantic coast. A regional tidal model was used to investigate the possible influence of tidal-range change in Long Island Sound on our reconstruction and we demonstrate that this effect was likely small. However, future tidal-range change could http://mc.manuscriptcentral.com/holocene approximately mean high water (MHW) and mean higher high water (MHHW; e.g., van de Plassche, 1991;Redfield, 1972; Johnson and York, 1915). At the boundary between the salt marsh and surrounding, upland forest is a narrow vegetative zone dominated by Phragmites australis. This zone is found above the MHHW tidal datum. Peat forming in this environment is typically a black, amorphous organic matrix that hosts the rhizomes of Phragmites australis plants (e.g., Niering et al., 1977). Through time these rhizomes are commonly flattened and degraded, resulting in a homogenized peat. The halotype of Phragmites found on and around modern salt marshes in the northeastern United States is invasive, although native haloptypes existed prior to European colonization in this region (Saltonstall, 2002). Elsewhere this uppermost zone of marine influence may also be occupied by Schoeneplectus spp., Typha spp., and/or Iva fructescens. We estimated the great diurnal tidal range (mean lower low water, MLLW to MHHW) at the site to be 2.44 m using the VDatum Harbor and Long Island Sound. METHODS Core collection and levelingThe sediment beneath the Pelham Bay salt marsh was described from hand-driven cores collected along two transects ( Figure 1C, D). Core PBA-4 was selected for detailed analysis because it included the thickest accumulation of peat and was therefore anticipated to provide the longest RSL record and adequate materia...

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Salt marshes as late Holocene tide gauges

Cited by 106 publications

References 168 publications

Relative sea-level changes and crustal movements in Britain and Ireland since the Last Glacial Maximum

Relative sea-level changes and crustal movements in Britain and Ireland since the Last Glacial Maximum

Glacial Isostatic Adjustment modelling: historical perspectives, recent advances, and future directions

Relative sea-level trends in New York City during the past 1500 years

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