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Bowen J.L., Ward B.B., Morrison H.G., Hobbie J.E., Valiela I., Deegan L.A., Sogin M.L.. 2011. Microbial community composition in salt marsh sediments resists perturbation by nutrient enrichment. The ISME Journal. 5:1540-1548.

Bouillon S., Boschker H.T.S.. 2006. Bacterial carbon sources in coastal sediments: a cross-system analysis based on stable isotope data of biomarkers. Biogeosciences. 3:175-185.

Bortolus A, Adam P, Adams JB, Ainouche ML, Ayres D, Bertness MD, Bouma TJ, Bruno JF, Caçador I, Carlton JT et al.. 2019. Supporting \textitSpartina} : Interdisciplinary perspective shows \textitSpartina} as a distinct solid genus. Ecology. 100

Booth H.S.. 2013. Does Chronic Nutrient Enrichment Result in a Trophic Bottleneck in a Salt Marsh? Honors, BS

Bogdan P, Caetano-Anollés G, Jolles A, Kim H, Morris J, Murphy CA, Royer C, Snell EH, Steinbrenner A, Strausfeld N. 2022. Biological Networks across Scales—The Theoretical and Empirical Foundations for Time-Varying Complex Networks that Connect Structure and Function across Levels of Biological Organization. Integrative and Comparative Biology. 61:1991–2010.

Blanchard S., Pontius, Jr. R.G., Urban K.M.. 2015. Implications of using 2m versus 30 m spatial resolution data for suburban residential land change modeling. Journal of Environmental Informatics. 25:1-13.

Blanchard S.. 2010. Implications of using fine versus coarse spatial resolution data in LUCC. MS Degree

Bernot M.J., Bernot R.J., Morris J.T.. 2009. Nutrient cycling relative to δ15N and δ13C natural abundance in a coastal wetland with long-term nutrient additions. Aquatic Ecology.

Bernhard A., Landry Z.C., Blevins A., Torre J.R.de al, Giblin A.E., Stahl D.A.. 2010. Abundance of ammonia-oxidizing Archaea and Bacteria along an estuarine salinity gradient in relationship to potential nitrification rates.. Applied and Environmental Microbiology. 76:1285-1289.

Bernhard A., Donn T.M., Giblin A.E., Stahl D.A.. 2005. Loss of Diversity of Ammonia-Oxidizing Bacteria Correlates with Increasing Salinity in an Estuary System.. Environmental Microbiology. 7:1289-1297.

Bernhard A.E., Tucker J., Giblin A.E., Stahl D.A.. 2007. Functionally distinct communities of ammonia-oxidizing bacteria along an estuarine salinity gradient. Environmental Microbiology. 9:1439-1447.

Beaulieu J.J, Tank J.L., Hamilton S.K, Wollheim W., Hall R., Mulholland P., Peterson B., Ashkenas L., Cooper L., Dahm C. et al.. 2011. Nitrous oxide emission from denitrification in stream and river networks. Proceedings of the National Academy of Science. 108:214-219.

Bauer J.E., Cai W-J., Raymond P.A, Bianchi T.S., Hopkinson C.S., Regnier P.A.G.. 2013. The changing carbon cycle of the coastal ocean.. Nature. 504:61-70.

Bauer C.. 2018. Interacting effects of genotype and the environment on tallform Spartina alterniflora. MS

Battin T.J., Kaplan L., Findlay S., Hopkinson C., Marti E., Packman A., Newbold J.D., Sabater F.. 2008. Biophysical controls on organic carbon fluxes in fluvial networks. Nature Geoscience. 1:95-100.

Barnes R.T., Raymond P.A. 2009. The contribution of agricultural and urban activities to inorganic carbon fluxes within temperate watersheds.. Chemical Geology. 266:318-327.

Baker H.K., Nelson J, Leslie H.M.. 2016. Quantifying striped bass (Morone saxatilis) dependence on saltmarsh-derived productivity using stable isotope analysis. Estuaries and Coasts.

Baker R, Taylor MD, Able KW, Beck MW, Cebrian J, Colombano DD, Connolly RM, Currin C, Deegan LA, Feller IC et al.. 2020. Fisheries rely on threatened salt marshes. Science. 370:670–671.

Bain D.J., Hale R.L., Wollheim W.M.. 2012. Urban Geochemistry: Hotbeds of Biogeochemical Diversity: Insights from Urban Long-Term Ecological Research Sites. Elements. 8:435-438.

Bain D., Green M.B., Campbell J., Chamblee J., Fraterrigo J., Kaushal S.S., Martin S., Jordan T., Parolari A., Sobczak W.V. et al.. 2012. Legacy effects material flux: structural catchment changes predate long-term studies.. Bioscience. 62:575-584.

Bahr M., Crump B.C., Klepac-Ceraj V., Teske A.P., Sogin M.L., Hobbie J.E.. 2005. Molecular characterization of sulfate-reducing bacteria in a New England salt marsh.. Environmental Microbiology. 7:1175-1185.

Babitch JW, Nelson JA, Deegan LA, Sullivan H, Stauffer BA. 2021. Resolving Estuarine Nitrogen Use by Phytoplankton Communities Using a Whole Ecosystem Tracer Approach. Estuaries and Coasts. 44:1883–1898.

A

Avolio M.L, La Pierre K.J., Houseman G.R., Koerner S.E., Grman E., Isbell F., Johnson D.S., Wilcox K.R.. 2015. A framework for quantifying the magnitude and variability of community responses to global change drivers. Ecosphere. 6

Avolio ML, Komatsu KJ, Collins SL, Grman E, Koerner SE, Tredennick AT, Wilcox KR, Baer S, Boughton EH, Britton AJ et al.. 2021. Determinants of community compositional change are equally affected by global change. Ecology Letters. 24:1892–1904.

Alpern J.. 2010. How to tell when map difference indicates land change. MS Degree

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