Transition Zones at the Changing Coastal Terrestrial-Aquatic Interface

Kaizad F. Patel; Avni Malhotra; Cooper G. Norris; Sophia A. McKever; Devon M. Fields; Jared I. Musci; Sreejata Bandopadhyay; Ben Bond-Lamberty; Xingyuan Chen; Donnie J. Day; Kennedy O. Doro; Etienne Fluet-Chouinard; Marci Garcia; Kenneth M. Kemner; Fausto Machado-Silva; Nate McDowell; Kendalynn A. Morris; Allison Myers-Pigg; Edward J. O’Loughlin; Teri O’Meara; Roberta B. Peixoto; Stephanie C. Pennington; Peter Regier; Roy Rich; Kenton A. Rod; Benjamin Sulman; Peter Thornton; Nicholas Ward; Stephanie J. Wilson; Michael N. Weintraub; J. Patrick Megonigal; Vanessa L. Bailey

doi:10.1029/2025JG008978

Transition Zones at the Changing Coastal Terrestrial-Aquatic Interface

Kaizad F. Patel
, Avni Malhotra
, Cooper G. Norris
, Sophia A. McKever
, Devon M. Fields
, Jared I. Musci
, Sreejata Bandopadhyay
, Ben Bond-Lamberty
, Xingyuan Chen
, Donnie J. Day
, Kennedy O. Doro
, Etienne Fluet-Chouinard
, Marci Garcia
, Kenneth M. Kemner
, Fausto Machado-Silva
, Nate McDowell
, Kendalynn A. Morris
, Allison Myers-Pigg
, Edward J. O’Loughlin
, Teri O’Meara

Roberta B. Peixoto, Stephanie C. Pennington, Peter Regier, Roy Rich, Kenton A. Rod, Benjamin Sulman, Peter Thornton, Nicholas Ward, Stephanie J. Wilson, Michael N. Weintraub, J. Patrick Megonigal, Vanessa L. Bailey

Environmental Sciences Division

Research output: Contribution to journal › Article › peer-review

Abstract

Coastal soils are a significant but highly uncertain component of global biogeochemical cycles. These systems experience spatial and temporal variability in biogeochemical processes, driven by marsh-to-upland gradients and hydrological fluctuations. These fluctuations make it difficult to understand and predict biogeochemical processes in these highly dynamic systems. We studied coastal soil biogeochemistry and its variability (a) at regional scales and (b) across transects from upland forest to marsh, in two contrasting regions—Lake Erie, a freshwater lacustrine system, and Chesapeake Bay, a saltwater estuarine system. Salinity-related analytes were a key source of variability in soil biogeochemistry, not just in the saltwater system, but surprisingly, also in the freshwater system. We had hypothesized linear trends in biogeochemical parameters along the TAI—however, contrary to expectations, transition soils were not consistently intermediate between upland and marsh endmembers; the non-monotonic trends of C, P, Fe along our transects suggest that these do not behave as expected and may be difficult to model and predict—thus these are key analytes to study in our regions. Rapidly changing soil factors across coastal gradients (e.g., Ca, K, CEC, and TS) may act as precursors to ecosystem shifts. Our comprehensive soil characterization represents a snapshot of a single timepoint of surface soils and provides essential data for mechanistic modeling of ecosystem dynamics across coastal transects.

Original language	English
Article number	e2025JG008978
Journal	Journal of Geophysical Research: Biogeosciences
Volume	130
Issue number	11
DOIs	https://doi.org/10.1029/2025JG008978
State	Published - Nov 2025

Funding

This work was supported through the Field, Measurements, and Experiments (FME) component of the Coastal Observations, Mechanisms, and Predictions Across Systems and Scales (COMPASS) project (https://compass.pnnl.gov/). COMPASS-FME is a multi-institutional project supported by the US Department of Energy, Office of Science, Biological and Environmental Research as part of the Environmental System Science Program. This project is led by Pacific Northwest National Laboratory which is operated for DOE by Battelle Memorial Institute under contract DE-AC05-76RL01830. A portion of this research was performed on a project award (60602) from the Environmental Molecular Sciences Laboratory. This work was also supported by the Smithsonian Environmental Research Center. We thank Steven McMurray and Janice Kerns at the OWC/ODNR and Scott Lerberg and Alexander Demeo at CBNERR-VA for facilitating site access. The region of Ohio we are studying is the ancestral homelands of the Seneca, Erie, Kaskaskia and Odawa, as well as places of trade for Indigenous peoples, including the Anishinaabe (Ojibwa, Pottawatomi), Kilatika, Lenape, Kaskaskia, Kickapoo, Miami, Munsee, Peoria, Piankashaw, Shawnee, Wea, and Wyandot. The region of the Chesapeake Bay we are studying is the ancestral homelands of the Cheroenhaka (Nottoway), Chickahominy, Eastern Chickahominy, Mattaponi, Monacan, Nansemond, Nottoway, Pamunkey, Patawomeck, Upper Mattaponi, and Rappahannock tribes. This work was supported through the Field, Measurements, and Experiments (FME) component of the Coastal Observations, Mechanisms, and Predictions Across Systems and Scales (COMPASS) project ( https://compass.pnnl.gov/ ). COMPASS‐FME is a multi‐institutional project supported by the US Department of Energy, Office of Science, Biological and Environmental Research as part of the Environmental System Science Program. This project is led by Pacific Northwest National Laboratory which is operated for DOE by Battelle Memorial Institute under contract DE‐AC05‐76RL01830. A portion of this research was performed on a project award (60602) from the Environmental Molecular Sciences Laboratory. This work was also supported by the Smithsonian Environmental Research Center. We thank Steven McMurray and Janice Kerns at the OWC/ODNR and Scott Lerberg and Alexander Demeo at CBNERR‐VA for facilitating site access. The region of Ohio we are studying is the ancestral homelands of the Seneca, Erie, Kaskaskia and Odawa, as well as places of trade for Indigenous peoples, including the Anishinaabe (Ojibwa, Pottawatomi), Kilatika, Lenape, Kaskaskia, Kickapoo, Miami, Munsee, Peoria, Piankashaw, Shawnee, Wea, and Wyandot. The region of the Chesapeake Bay we are studying is the ancestral homelands of the Cheroenhaka (Nottoway), Chickahominy, Eastern Chickahominy, Mattaponi, Monacan, Nansemond, Nottoway, Pamunkey, Patawomeck, Upper Mattaponi, and Rappahannock tribes.

Keywords

ghost forest
marsh
redox
soil biogeochemistry
wetland

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10.1029/2025JG008978

Cite this

Patel, K. F., Malhotra, A., Norris, C. G., McKever, S. A., Fields, D. M., Musci, J. I., Bandopadhyay, S., Bond-Lamberty, B., Chen, X., Day, D. J., Doro, K. O., Fluet-Chouinard, E., Garcia, M., Kemner, K. M., Machado-Silva, F., McDowell, N., Morris, K. A., Myers-Pigg, A., O’Loughlin, E. J., ... Bailey, V. L. (2025). Transition Zones at the Changing Coastal Terrestrial-Aquatic Interface. Journal of Geophysical Research: Biogeosciences, 130(11), Article e2025JG008978. https://doi.org/10.1029/2025JG008978

@article{00f346281b9843ceab5ad8376553cbc9,

title = "Transition Zones at the Changing Coastal Terrestrial-Aquatic Interface",

abstract = "Coastal soils are a significant but highly uncertain component of global biogeochemical cycles. These systems experience spatial and temporal variability in biogeochemical processes, driven by marsh-to-upland gradients and hydrological fluctuations. These fluctuations make it difficult to understand and predict biogeochemical processes in these highly dynamic systems. We studied coastal soil biogeochemistry and its variability (a) at regional scales and (b) across transects from upland forest to marsh, in two contrasting regions—Lake Erie, a freshwater lacustrine system, and Chesapeake Bay, a saltwater estuarine system. Salinity-related analytes were a key source of variability in soil biogeochemistry, not just in the saltwater system, but surprisingly, also in the freshwater system. We had hypothesized linear trends in biogeochemical parameters along the TAI—however, contrary to expectations, transition soils were not consistently intermediate between upland and marsh endmembers; the non-monotonic trends of C, P, Fe along our transects suggest that these do not behave as expected and may be difficult to model and predict—thus these are key analytes to study in our regions. Rapidly changing soil factors across coastal gradients (e.g., Ca, K, CEC, and TS) may act as precursors to ecosystem shifts. Our comprehensive soil characterization represents a snapshot of a single timepoint of surface soils and provides essential data for mechanistic modeling of ecosystem dynamics across coastal transects.",

keywords = "ghost forest, marsh, redox, soil biogeochemistry, wetland",

author = "Patel, \{Kaizad F.\} and Avni Malhotra and Norris, \{Cooper G.\} and McKever, \{Sophia A.\} and Fields, \{Devon M.\} and Musci, \{Jared I.\} and Sreejata Bandopadhyay and Ben Bond-Lamberty and Xingyuan Chen and Day, \{Donnie J.\} and Doro, \{Kennedy O.\} and Etienne Fluet-Chouinard and Marci Garcia and Kemner, \{Kenneth M.\} and Fausto Machado-Silva and Nate McDowell and Morris, \{Kendalynn A.\} and Allison Myers-Pigg and O{\textquoteright}Loughlin, \{Edward J.\} and Teri O{\textquoteright}Meara and Peixoto, \{Roberta B.\} and Pennington, \{Stephanie C.\} and Peter Regier and Roy Rich and Rod, \{Kenton A.\} and Benjamin Sulman and Peter Thornton and Nicholas Ward and Wilson, \{Stephanie J.\} and Weintraub, \{Michael N.\} and Megonigal, \{J. Patrick\} and Bailey, \{Vanessa L.\}",

note = "Publisher Copyright: {\textcopyright} 2025. UChicago Argonne, LLC. Oak Ridge National Laboratory. Smithsonian Institution. Battelle Memorial Institute and The Author(s). This article has been contributed to by U.S. Government employees and their work is in the public domain in the USA.",

year = "2025",

month = nov,

doi = "10.1029/2025JG008978",

language = "English",

volume = "130",

journal = "Journal of Geophysical Research: Biogeosciences",

issn = "2169-8953",

publisher = "American Geophysical Union",

number = "11",

}

Patel, KF, Malhotra, A, Norris, CG, McKever, SA, Fields, DM, Musci, JI, Bandopadhyay, S, Bond-Lamberty, B, Chen, X, Day, DJ, Doro, KO, Fluet-Chouinard, E, Garcia, M, Kemner, KM, Machado-Silva, F, McDowell, N, Morris, KA, Myers-Pigg, A, O’Loughlin, EJ, O’Meara, T, Peixoto, RB, Pennington, SC, Regier, P, Rich, R, Rod, KA, Sulman, B, Thornton, P, Ward, N, Wilson, SJ, Weintraub, MN, Megonigal, JP & Bailey, VL 2025, 'Transition Zones at the Changing Coastal Terrestrial-Aquatic Interface', Journal of Geophysical Research: Biogeosciences, vol. 130, no. 11, e2025JG008978. https://doi.org/10.1029/2025JG008978

TY - JOUR

T1 - Transition Zones at the Changing Coastal Terrestrial-Aquatic Interface

AU - Patel, Kaizad F.

AU - Malhotra, Avni

AU - Norris, Cooper G.

AU - McKever, Sophia A.

AU - Fields, Devon M.

AU - Musci, Jared I.

AU - Bandopadhyay, Sreejata

AU - Bond-Lamberty, Ben

AU - Chen, Xingyuan

AU - Day, Donnie J.

AU - Doro, Kennedy O.

AU - Fluet-Chouinard, Etienne

AU - Garcia, Marci

AU - Kemner, Kenneth M.

AU - Machado-Silva, Fausto

AU - McDowell, Nate

AU - Morris, Kendalynn A.

AU - Myers-Pigg, Allison

AU - O’Loughlin, Edward J.

AU - O’Meara, Teri

AU - Peixoto, Roberta B.

AU - Pennington, Stephanie C.

AU - Regier, Peter

AU - Rich, Roy

AU - Rod, Kenton A.

AU - Sulman, Benjamin

AU - Thornton, Peter

AU - Ward, Nicholas

AU - Wilson, Stephanie J.

AU - Weintraub, Michael N.

AU - Megonigal, J. Patrick

AU - Bailey, Vanessa L.

N1 - Publisher Copyright: © 2025. UChicago Argonne, LLC. Oak Ridge National Laboratory. Smithsonian Institution. Battelle Memorial Institute and The Author(s). This article has been contributed to by U.S. Government employees and their work is in the public domain in the USA.

PY - 2025/11

Y1 - 2025/11

N2 - Coastal soils are a significant but highly uncertain component of global biogeochemical cycles. These systems experience spatial and temporal variability in biogeochemical processes, driven by marsh-to-upland gradients and hydrological fluctuations. These fluctuations make it difficult to understand and predict biogeochemical processes in these highly dynamic systems. We studied coastal soil biogeochemistry and its variability (a) at regional scales and (b) across transects from upland forest to marsh, in two contrasting regions—Lake Erie, a freshwater lacustrine system, and Chesapeake Bay, a saltwater estuarine system. Salinity-related analytes were a key source of variability in soil biogeochemistry, not just in the saltwater system, but surprisingly, also in the freshwater system. We had hypothesized linear trends in biogeochemical parameters along the TAI—however, contrary to expectations, transition soils were not consistently intermediate between upland and marsh endmembers; the non-monotonic trends of C, P, Fe along our transects suggest that these do not behave as expected and may be difficult to model and predict—thus these are key analytes to study in our regions. Rapidly changing soil factors across coastal gradients (e.g., Ca, K, CEC, and TS) may act as precursors to ecosystem shifts. Our comprehensive soil characterization represents a snapshot of a single timepoint of surface soils and provides essential data for mechanistic modeling of ecosystem dynamics across coastal transects.

AB - Coastal soils are a significant but highly uncertain component of global biogeochemical cycles. These systems experience spatial and temporal variability in biogeochemical processes, driven by marsh-to-upland gradients and hydrological fluctuations. These fluctuations make it difficult to understand and predict biogeochemical processes in these highly dynamic systems. We studied coastal soil biogeochemistry and its variability (a) at regional scales and (b) across transects from upland forest to marsh, in two contrasting regions—Lake Erie, a freshwater lacustrine system, and Chesapeake Bay, a saltwater estuarine system. Salinity-related analytes were a key source of variability in soil biogeochemistry, not just in the saltwater system, but surprisingly, also in the freshwater system. We had hypothesized linear trends in biogeochemical parameters along the TAI—however, contrary to expectations, transition soils were not consistently intermediate between upland and marsh endmembers; the non-monotonic trends of C, P, Fe along our transects suggest that these do not behave as expected and may be difficult to model and predict—thus these are key analytes to study in our regions. Rapidly changing soil factors across coastal gradients (e.g., Ca, K, CEC, and TS) may act as precursors to ecosystem shifts. Our comprehensive soil characterization represents a snapshot of a single timepoint of surface soils and provides essential data for mechanistic modeling of ecosystem dynamics across coastal transects.

KW - ghost forest

KW - marsh

KW - redox

KW - soil biogeochemistry

KW - wetland

UR - https://www.scopus.com/pages/publications/105020597691

U2 - 10.1029/2025JG008978

DO - 10.1029/2025JG008978

M3 - Article

AN - SCOPUS:105020597691

SN - 2169-8953

VL - 130

JO - Journal of Geophysical Research: Biogeosciences

JF - Journal of Geophysical Research: Biogeosciences

IS - 11

M1 - e2025JG008978

ER -

Transition Zones at the Changing Coastal Terrestrial-Aquatic Interface

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