PIE LTER Publications

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Journal Article

Mudd S.M., Howell S., Morris J.T.. 2009. Impact of the dynamic feedback between sedimentation, sea level rise, and biomass production on near surface marsh stratigraphy and carbon accumulation. Estuarine, Coastal and Shelf Science. 82:377-389.

Morris J.T, Porter D., Neet M., Noble P.A., Schmidt L., Lapine L.A., Jensen J.. 2005. Integrating LIDAR, multispectral imagery and neural network modeling techniques for marsh classification.. International Journal of Remote Sensing. 26:5221-5234.

Watson E.B., Wigand C., Oczkowski A.J., Sundberg K., Vendettuoli D., Jayaraman S., Saliba K., Morris J.T.. 2015. Ulva additions alter soil biogeochemistry and negatively impact Spartina alterniflora growth. Marine Ecological Progress Series. 532:59-72.

Kirwan M.L., Guntenspergen G.R., Morris J.T.. 2009. Latitudinal trends in Spartina alterniflora productivity and the response of coastal marshes to global change. Global Change Biology.

Mozdzer T.J., McGlathery K.J., Mills A.L., Zieman J.C.. 2014. Latitudinal variation in the availability and use of dissolved organic nitrogen in Atlantic coast salt marshes. Ecology.

Forbrich I., Giblin A.E.. 2015. Marsh-atmosphere exchange of CO2 in a New England salt marsh. Journal of Geophysical Research- Biogeosciences. 120

Holmes R.M, Peterson B.J., Deegan L., Hughes J., Fry B.. 2000. Nitrogen biogeochemistry in the oligohaline zone of a New England estuary.. Ecology. 81:416-432.

Hughes J.E, Deegan L.A., Peterson B.J., Holmes R.M., Fry B.. 2000. Nitrogen flow through the food web in the oligohaline zone of a New England estuary.. Ecology. 81:433-452.

Howard E.M., Spivak A.C., Karolewski J.S., Gosslein K.M., Sandwidth Z.O., Manning C.C., Stanley R.H.R. 2020. Oxygen and Triple Oxygen Isotope Measurements Provide Different Insights into Gross Oxygen Production in a Shallow Salt Marsh Pond.. Estuaries and Coasts.

Drake D.C., Peterson B.J., Deegan L.A., Harris L.A., Miller E.E., Warren R.S.. 2008. Plant nitrogen dynamics in fertilized and natural New England saltmarshes: a paired 15N tracer study. Marine Ecology Progress Series. 354:35-46.

Fagherazzi S., Mariotti G., Banks A.T., Morgan E.J., Fulweiler R.W.. 2014. The relationships among hydrodynamics, sediment distribution, and chlorophyll in a mesotidal estuary.. Estuarine and Coastal Shelf Science. 144:54-64.

Kiehn W.M, Morris J.T.. 2009. Relationships Between Spartina alterniflora and Littoraria irrorata in a South Carolina Salt Marsh. Wetlands. 29:818-825.

Drake D.C., Peterson B.J., Galván K.A., Deegan L.A., Fleeger J.W., Hopkinson C., Johnson J.M., Koop-Jakobsen K., Lemay L.E., Miller E.E. et al.. 2009. Salt marsh ecosystem biogeochemical responses to nutrient enrichment: A paired ¹⁵N tracer study.. Ecology. 90:2535-2546.

Crosby S.C., Sax D., Palmer M.E., Booth H.S., Deegan L.A., Bertness M.D., Leslie H.M.. 2016. Salt marsh persistence is threatened by predicted sea-level rise. Estuarine and Coastal Shelf Science. 181:93-99.

Spivak A.C., Denmark A., Gosselin K., Sylva S.P.. 2020. Salt Marsh Pond Biogeochemistry Changes Hourly to Yearly but Does Not Scale With Dimensions or Geospatial Position. Journal of Geophysical Research: Biogeosciences. 125

Morris J.T., Sundberg K., Hopkinson C.S.. 2013. Salt marsh primary production and its responses to relative sea level and nutrients. Oceanography. 26:78-84.

Johnson D.S., Warren R.S., Deegan L.A., Mozdzer T.J.. 2016. Saltmarsh plant responses to eutrophication. Ecological Applications.

Spivak A.C., Gosselin K., Howard E., Mariotti G., Forbrich I., Stanley R., Sylva S.P.. 2017. Shallow ponds are heterogeneous habitats within a temperate salt marsh ecosystem. Journal of Geophysical Research: Biogeosciences. 122

Crosby S.C., Angermeyer A., Adler J.M., Bertness M.D., Deegan L.A., Sibinga N., Leslie H.M.. 2016. Spartina alterniflora biomass allocation and temperature: implications for salt marsh persistence with sea-level rise. Estuaries and Coasts.

Galvan K., Fleeger J.W., Fry B.. 2008. Stable isotope addition reveals dietary importance of phytoplankton and microphytobenthos to saltmarsh infauna. Marine Ecology Progress Series. 359:37-49.

Deegan L.A., Bowen J.L., Drake D.C., Fleeger J.W., Friedrichs C.T., Galván K.A., Hobbie J.E., Hopkinson C., Johnson D.S., Johnson J.M. et al.. 2007. Susceptibility of salt marshes to nutrient enrichment and predator removal. Ecological Applications. 17:S-42-S63.

Feagin A., Forbrich I., Huff T.P., Barr J.G, Ruiz-Plancarte J., Fuentes J.D, NaJJar R.G, Vargas R., Vázquez‐Lule A., L. W‐M. et al.. 2020. Tidal Wetland Gross Primary Production Across the Continental United States, 2000–2019.. Global Biogeochemical Cycles. 34

Fleeger J.W., Johnson D.S., Galván K.A., Deegan L.A.. 2008. Top-down and bottom-up control of infauna varies across the saltmarsh landscape. Journal of Experimental Marine Biology and Ecology. 357:20-34.

Johnson D.S., Fleeger J.W.. 2009. Weak response of saltmarsh infauna to ecosystem-wide nutrient enrichment and fish predator reduction: A four-year study. Journal of Experimental Marine Biology and Ecology. 373:35-44.

Thesis

Jr. J.D.Edwards. 2016. Applicability of LiDAR Technology in Saltmarshes: Landscape-Scale Predictive Models to Local-Scale Biomass Estimation. M.S.:134.

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