A 7000-year history of coastal environmental changes from Mexico’s Pacific coast: A multi-proxy record from Laguna Mitla, Guerrero

Bianchette, Thomas A.; McCloskey, Terrence A.; Liu, Kam‐biu

doi:10.1177/0959683616687379

Cited by 11 publications

(3 citation statements)

References 94 publications

(133 reference statements)

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“…In coastal areas where a freshwater lens sits atop the subterranean salt water wedge, rising sea level drives the overlying freshwater lens upward. During the Holocene, in coastal areas this unidirectional rise in the water table typically resulted in first, the development of vegetative growth and, later, freshwater wetlands, and, depending on elevation, increasing marine influence and the eventual replacement of freshwater wetlands with halophytic vegetation; mangroves at lower latitudes − and salt marshes farther north. , This environmental sequence has been documented for coastal areas sites throughout the western hemisphere. − …”

Section: Discussionmentioning

confidence: 92%

How Could a Freshwater Swamp Produce a Chemical Signature Characteristic of a Saltmarsh?

McCloskey

Smith

Liu

et al. 2017

ACS Earth Space Chem.

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Reduction–oxidation (redox) reaction conditions, which are of great importance for the soil chemistry of coastal marshes, can be temporally dynamic. We present a transect of cores from northwest Florida wherein radical postdepositional changes in the redox regime has created atypical geochemical profiles at the bottom of the sedimentary column. The stratigraphy is consistent along the transect, consisting of, from the bottom upward, carbonate bedrock, a gray clay, an organic mud section, a dense clay layer, and an upper organic mud unit representing the current saltwater marsh. However, the geochemical signature of the lower organic mud unit suggests pervasive redox reactions, although the interval has been identified as representing a freshwater marsh, an unlikely environment for such conditions. Analyses indicate that this discrepancy results from postdepositional diagenesis driven by millennial-scale environmental parameters. Rising sea level that led to the deposition of the capping clay layer, created anaerobic conditions in the freshwater swamp interval, and isolated it hydrologically from the rest of the sediment column. The subsequent infiltration of marine water into this organic material led to sulfate reduction, the buildup of H2S and FeS, and anoxic conditions. Continued sulfidation eventually resulted in euxinic conditions, as evidenced by elevated levels of Fe, S, and especially Mo, the diagnostic marker of euxinia. Because this chemical transformation occurred long after the original deposition the geochemical signature does not reflect soil chemistry at the time of deposition and cannot be used to infer syn-depositional environmental conditions, emphasizing the importance of recognizing diagenetic processes in paleoenvironmental studies.

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Section: Discussionmentioning

confidence: 92%

How Could a Freshwater Swamp Produce a Chemical Signature Characteristic of a Saltmarsh?

McCloskey

Smith

Liu

et al. 2017

ACS Earth Space Chem.

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“…Hurricanes normally deposit anomalous sediments through either overwash or flooding. Observations of such anomalous layers have been made in storm deposits from multiple sites that have been impacted by intense storm events (Bianchette et al, 2017;Braun et al, 2017;Liu et al, 2011;McCloskey et al, 2018;Reese et al, 2008;Ryu et al, 2018). The storms disturbed the vegetation in coastal Louisiana as is seen in the diminished pollen percentages of marsh vegetation such as Poaceae, Typha, and Cyperaceae accompanied by an increase in Cheno/Am, which are disturbance indicators.…”

Section: Environmental History Of Bay Jimmy Marshmentioning

confidence: 99%

A 1200-year history of environmental changes in Bay Jimmy area, coastal Louisiana, USA

Kiage

2019

The Holocene

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Paleoecological studies from the northern Gulf of Mexico (GOM) have mostly aimed at understanding long-term paleoenvironmental changes. Only a few studies have been performed in the southern United States focusing on paleoenvironmental changes during the common era. This study investigated paleoenvironmental changes in coastal Louisiana over the past 1200 years by utilizing proxy data, including loss-on-ignition (LOI) and pollen from a sediment core collected from a wetland in Bay Jimmy. The results indicate that the marsh in the study area was formed at ca. AD 1090 and has been primarily shaped by prevailing climatic conditions, including rare extreme events. At least four major hurricanes impacted the site over the 1200 years, including two that made landfall in recent times. The findings show that coastal Louisiana was warm and dry during the ‘Medieval Warm Period’ (ca. AD 950–1250). The environment after AD 1090 contained scattered Pinus and Juglans vegetation communities that were later succeeded by a closed forest that included Quercus and Morus. Red mangrove ( Rhizophora) was established in the vicinity of Bay Jimmy until shortly after cal AD 1450 and 1640. The pollen record indicates that the ‘Little Ice Age’ period (AD 1550–1850) was cold and dry, characterized by a more open vegetation community. There is evidence of forest disturbance that is marked by a rise in Ambrosia pollen in the 1700s, coinciding with the time of European settlement in North America. The presence of Ambrosia and Cheno/Am pollen throughout the record suggests that anthropogenic influence has been part of the fabric of the southern Louisiana landscapes throughout the 1200 years.

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“…High scores for the second component, which accounts for 21.5% of the variability, are associated with large concentrations of Cl and S, while low sores are associated with higher concentrations of Br and Ca. Because Cl and S are marine indicators, higher concentrations can be used to indicate increased marine influence (Goff et al, 2012;Liu et al, 2014;Bianchette et al, 2017;McCloskey et al, 2018a). Notably, there is a large movement in the direction of S and Cl at the interface between the underlying organics and the bottom of the event layer (from 17 to 15 cm).…”

Section: Elemental Concentrationmentioning

confidence: 99%

The Effects of Tropical Cyclone-Generated Deposition on the Sustainability of the Pearl River Marsh, Louisiana: The Importance of the Geologic Framework

et al. 2018

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Shoreline retreat is a tremendously important issue along the coast of the northern Gulf of Mexico, especially in Louisiana. Although this marine transgression results from a variety of causes, the crucial factor is the difference between marsh surface elevation and rising sea levels. In most cases, the primary cause of a marsh's inability to keep up with sea level is the lack of input of inorganic material. Although tropical cyclones provide an important source of such sediment, little effort has been made to determine the point of origin of the deposited material. In this study we use sedimentary, geochemical and biogeochemical data to identify the bed of the Pearl River and/or Lake Borgne as the source of a ∼5 cm thick clastic layer deposited on the surface of the Pearl River marsh on the Louisiana/Mississippi border. Radiochemical chronologies and sedimentary evidence indicate that this layer was associated with the passage of Hurricane Katrina in 2005. As this material would otherwise have been lost to the system, this deposition indicates a net gain to marsh surface elevation. Accretion rates, determined from 137Cs and 14C profiles and the use of the Katrina layer as a stratigraphic marker, indicate that short-term (∼50 years) rates are as much as an order of magnitude higher than the long-term (1000s of years) rates. We suggest that the marsh's geologic setting in an incised river valley with steep vertical constraints and a large fluvial discharge, promotes rapid accretion rates, with rates accelerating as the sea moves inland, due to extended hydroperiods and the input of clastic material from both the marine and terrestrial sides. These rates are especially large when compared to accretion occurring in the more common open marshes fringing the Gulf that lack fluvial input. The difference is particularly large when related to marsh recovery/regrowth following the deposition of thick hurricane-generated clastic layers. Given the number of similar incised river valleys along the Gulf Coast, we believe that understanding the processes controlling marsh accretion in such environments is essential in evaluating marsh sustainability on a regional basis.

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A 7000-year history of coastal environmental changes from Mexico’s Pacific coast: A multi-proxy record from Laguna Mitla, Guerrero

Cited by 11 publications

References 94 publications

How Could a Freshwater Swamp Produce a Chemical Signature Characteristic of a Saltmarsh?

How Could a Freshwater Swamp Produce a Chemical Signature Characteristic of a Saltmarsh?

A 1200-year history of environmental changes in Bay Jimmy area, coastal Louisiana, USA

The Effects of Tropical Cyclone-Generated Deposition on the Sustainability of the Pearl River Marsh, Louisiana: The Importance of the Geologic Framework

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