%0 Journal Article %J Remote Sensing %D 2019 %T Estimating Aboveground Biomass and Its Spatial Distribution in Coastal Wetlands Utilizing Planet Multispectral Imagery %A Miller, G.J. %A Morris, J.T. %A Wang, C. %K biomass %K LTER-PIE %K planet satellites %K population dynamics %K primary production %K salt marsh %K Spartina alterniflora %K vegetation index %B Remote Sensing %V 11 %G eng %M PIE485 %3 LTREB-654853, OCE-1637630 %] NSF-LTER-PIE %R 10.3390/rs11172020 %F Journal Article %0 Journal Article %J PLoS ONE %D 2019 %T Short-term effect of simulated salt marsh restoration by sand-amendment on sediment bacterial communities %A Thomas, Francois %A Morris, J.T. %A Wigand, C. %A Sievert, S.M. %K 16S rDNA %K bacteria communities %K inundation %K LTER-PIE %K population dynamics %K salt marsh %K sea level %B PLoS ONE %V 14 %G eng %M PIE470 %3 OCE 1673630 %] NSF-LTER-PIE %R 10.1371/journal.pone.0215767 %F Journal Article %0 Journal Article %J Journal of Geophysical Research %D 2018 %T Lateral Marsh Edge Erosion as a Source of Sediments for Vertical Marsh Accretion %A Hopkinson, C.S. %A Morris, J.T. %A Fagherazzi, S. %A Wollheim, W.M. %A Raymond, P. A. %K disturbance %K erosion %K LTER-PIE %K organic carbon %K organic matter %K salt marsh accretion %K sea-level rise %K sediment %K watershed %B Journal of Geophysical Research %G eng %M PIE449
%3 OCE-1237733, OCE-1637630, LTREB-654853 %] NSF-LTER-PIE %R 10.1029/2017JG004358 %F Journal Article %0 Journal Article %J Ecology %D 2017 %T Regulation of salt marsh mosquito populations by the 18.6-year lunar-nodal cycle %A Rochlin, I. %A Morris, J.T. %K 18.6-year lunar-nodal cycle %K Aedes sollicitans %K disturbance %K LTER-PIE %K mosquitos %K salt marsh fauna %B Ecology %G eng %M PIE431 %3 DEB-1052636, OCE-1238212 %] NSF-LTER-PIE %R 10.1002/ecy.1861 %F Journal Article %0 Journal Article %J Earth's Future %D 2016 %T Contributions of organic and inorganic matter to sediment volume and accretion in tidal wetlands at steady state %A Morris, J.T. %A Barber, D.C. %A Callaway, J.C. %A Chambers, R. %A Hagen, S.C. %A Hopkinson, C.S. %A Johnson, B.J. %A Megonigal, P. %A Neubauer, S.C. %A Troxler, T. %A Wigand, C. %K accretion %K LTER-PIE %K organic matter %K primary production %K sea level %K wetlands %B Earth's Future %V 4 %P 110-121 %G eng %M PIE421 %3 NSF OCE-1238212, NOAA NA10NOS4780146, NSF DEB grants 1052636, 0620409, 9910514, 1237517, 1127958, 0950090, 1457100 and 1355059, NSF EAR grants 1322859 and 1322658, NICCR grant DE-FC02-06ER64298, NASA grant NNH14AY67, %] NSF-LTER-PIE %R 10.1002/2015EF000334 %F Journal Article %0 Journal Article %J Oecologia %D 2015 %T Global environmental change and the nature of aboveground net primary productivity responses: insights from long‑term experiments %A Smith, M.D. %A La Pierre, K.J. %A Collins, S.L. %A Knapp, A.K. %A Gross, K.L. %A Barrett, J.E. %A Frey, S.D. %A Gough, L. %A Miller, R.J. %A Morris, J.T. %A Rustad, L.E. %A Yarie, J. %K aboveground productivuty %K disturbance %K hierarchial respopnse framework %K long-term ecological research network %K LTER-PIE %K nutrient addition %K precipitation manipulation %K primary production %B Oecologia %G eng %M PIE381 %] NSF-LTER-PIE %R 10.1007/s00442-015-3230-9 %F Journal Article %0 Journal Article %J Marine Ecological Progress Series %D 2015 %T Ulva additions alter soil biogeochemistry and negatively impact Spartina alterniflora growth %A Watson, E.B. %A Wigand, C. %A Oczkowski, A.J. %A Sundberg, K. %A Vendettuoli, D. %A Jayaraman, S. %A Saliba, K. %A Morris, J.T. %K allelochemicals %K allelopathy %K disturbance %K eutrophic estuary %K LTER-PIE %K primary production %K salt marsh %K salt marsh loss %B Marine Ecological Progress Series %V 532 %P 59-72 %G eng %M PIE395 %] NSF-LTER-PIE %R 10.3354/meps11334 %F Journal Article %0 Book Section %B Long-Term Environmental Research: Changing the Nature of Scientists %D 2015 %T Perspectives on a 30-Year Career of Salt Marsh Research %A Morris, J.T. %E Willig, M.R. %E Walker, L.R. %K ecology %K long-term %K LTER-PIE %K research funding %B Long-Term Environmental Research: Changing the Nature of Scientists %I Oxford University Press %@ 9780199380213 %G eng %M PIE392 %] NSF-LTER-PIE %& 33 %F Book Section %0 Journal Article %J Wetlands %D 2013 %T Brinson Review: Perspectives on the influence of nutrients on the sustainability of coastal wetlands %A Morris, J.T. %A Shaffer, J.A. %A Nynam, J.A. %K inorganic nutrients %K LTER-PIE %K primary production %K salt marsh %K wetland sustainability %B Wetlands %V 33 %P 975-988 %G eng %M PIE340 %] NSF-LTER-PIE %R 10.1007/s13157-013-0480-3 %F Journal Article %0 Book Section %B Treatise on Geomorphology %D 2013 %T Ecogeomorphology of Salt Marshes %A Fagherazzi, S. %A FitzGerald, D.M. %A Fulweiler, R.W. %A Hughes, Z. %A Wiberg, P.L. %A McGlathery, K.J. %A Morris, J.T. %A Tolhurst, T.J. %A Deegan, L.A. %A Johnson, D.S. %E Shroder, J. %E Butler, D. %E Hubb, C. %K disturbance %K geomorphology %K LTER-PIE %K nutrients %K salt marsh %B Treatise on Geomorphology %I Elsevier %V 12 %P 180-200 %G eng %M PIE300 %] NSF-LTER-PIE %F Book Section %0 Book Section %B Treatise on Geomorphology %D 2013 %T Ecogeomorphology of Tidal Flats %A Fagherazzi, S. %A FitzGerald, D.M. %A Fulweiler, R.W. %A Hughes, Z. %A Wiberg, P.L. %A McGlathery, K.J. %A Morris, J.T. %A Tolhurst, T.J. %A Deegan, L.A. %A Johnson, D.S. %E Shroder, J. %E Butler, D. %E Hubb, C. %K disturbance %K estuary %K geomorphology %K LTER-PIE %K tidal flats %B Treatise on Geomorphology %I Elsevier %V 12 %P 201-220 %G eng %M PIE301 %] NSF-LTER-PIE %F Book Section %0 Book %D 2013 %T An Ecosystem Services Approach to Assessing the Impacts of the Deepwater Horizon Oil Spill in the Gulf of Mexico %A Mayer, L.A. %A Boufadel, M.C. %A Brenner, J. %A Carney, R.S. %A Cooper, C.K. %A Deming, J.W. %A Die, D.J. %A Eagle, J. %A Geraci, J.R. %A Knuth, B.A. %A Lee, K. %A Morris, J.T. %A Polasky, S. %A Rabalais, N.N. %A Stahl Jr., R.G. %A Yoskowitz, D. %A Waddell, K. %E National Research Council of the National Academies %Y National Research Council of the National Academies %K disturbance %K ecosystem services %K LTER-PIE %K resilience %K restoration %K wetlands %I National Academies Press %C Washington, D.C. %P 246 %G eng %M PIE373 %] NSF-LTER-PIE %F Book %0 Journal Article %J Oceanography %D 2013 %T Salt marsh primary production and its responses to relative sea level and nutrients %A Morris, J.T. %A Sundberg, K. %A Hopkinson, C.S. %K disturbance %K inorganic nutrients %K LTER-PIE %K primary production %K salt marshes %K sea level %B Oceanography %V 26 %P 78-84 %G eng %M PIE331 %] NSF-LTER-PIE %R 10.5670/oceanog.2013.48 %F Journal Article %0 Book Section %B Recarbonization of the Bioshpere: Ecosystem and Global Carbon Cycle. %D 2012 %T Assessment of Carbon Sequestration Potential in Coastal Wetlands. %A Morris, J.T. %A Edwards, J. %A Crooks, S. %A Reyes, E. %E Lal, R. %E Lorenz, K. %E Hüttl, R. %E Schneider, B.U. %E von Braun, J. %K anthropogenic disturbance %K autochthonous %K carbon sequestration %K carbon stocks %K coastal ecosystems %K coastal wetlands %K digital elevation model %K diking %K disturbance %K drainage %K holocene %K LTER-PIE %K mangroves %K marsh equilibrium model %K organic matter %K organic rich soil %K primary production %K sea level rise %K subsidence %K suspended solids %K tidal amplitude %K tidal marshes %K tide range %B Recarbonization of the Bioshpere: Ecosystem and Global Carbon Cycle. %I Springer %P 517-531 %G eng %M PIE303 %] NSF-LTER-PIE %R 10.1007/978-94-007-4159-1_24 %F Book Section %0 Journal Article %J Journal of Geophysical Research %D 2010 %T How does vegetation affect sedimentation on tidal marshes? Investigating particle capture and hydrodynamic controls on biologically mediated sedimentation %A Mudd, S.M. %A D'Alpaos, A. %A Morris, J.T. %K disturbance %K hydrodynamics %K LTER-PIE %K salt marshes %K sedimentation %B Journal of Geophysical Research %V 115 %G eng %M PIE259 %] NSF-LTER-PIE %R 10.1029/2009JF001566 %F Journal Article %0 Journal Article %J Marine Ecology Progress Series %D 2010 %T Variability in dimethylsulfoniopropionate (DMSP) in Spartina alterniflora and its effect on Littoraria irrorata. %A Kiehn, W.M. %A Morris, J.T. %K attractant %K deterrent %K disturbance %K DMSP %K Littoraria irrorata %K LTER-PIE %K population dynamics %K salt marsh %K salt marsh dieback %K Spartina alterniflora %K stress hormone %B Marine Ecology Progress Series %V 406 %P 47-55 %G eng %M PIE244 %] NSF-LTER-PIE %R 10.3354/meps08548 %F Journal Article %0 Journal Article %J Estuarine, Coastal and Shelf Science %D 2009 %T Impact of the dynamic feedback between sedimentation, sea level rise, and biomass production on near surface marsh stratigraphy and carbon accumulation %A Mudd, S.M. %A Howell, S. %A Morris, J.T. %K accretion %K belowground biomass %K carbon storage %K disturbance %K LTER-PIE %K organic matter %K organic sediments %K primary production %K salt marsh %K sea-level rise %B Estuarine, Coastal and Shelf Science %V 82 %P 377-389 %G eng %M PIE212 %] NSF-LTER-PIE %R 10.1016/j.ecss.2009.01.028 %F Journal Article %0 Journal Article %J Global Change Biology %D 2009 %T Latitudinal trends in Spartina alterniflora productivity and the response of coastal marshes to global change %A Kirwan, M.L. %A Guntenspergen, G.R. %A Morris, J.T. %K biomass %K climate %K disturbance %K LTER-PIE %K organic matter %K primary production %K sea level %K temperature %K warming %K wetland %B Global Change Biology %G eng %M PIE213 %3 OCE 0423565 and DEB 0316429 %] NSF-LTER-PIE %R 10.1111/j.1365-2486.2008.01834.x %F Journal Article %0 Journal Article %J Aquatic Ecology %D 2009 %T Nutrient cycling relative to δ15N and δ13C natural abundance in a coastal wetland with long-term nutrient additions %A Bernot, M.J. %A Bernot, R.J. %A Morris, J.T. %K coastal wetland %K disturbance %K inorganic nutrients %K LTER-PIE %K natural abundance %K nitrogen %K nutrient loading %K nutrient uptake %K phosphorus %K δ13C %K δ15N %B Aquatic Ecology %G eng %M PIE208 %] NSF-LTER-PIE %R 10.1007/s10452-008-9221-8 %F Journal Article %0 Journal Article %J Wetlands %D 2009 %T Relationships Between Spartina alterniflora and Littoraria irrorata in a South Carolina Salt Marsh %A Kiehn, W.M %A Morris, J.T. %K bottom-up %K detritivore %K herbivory %K Littoraria irrorata %K LTER-PIE %K population dynamics %K primary production %K Spartina %K top-down %B Wetlands %V 29 %P 818-825 %G eng %M PIE214 %] NSF-LTER-PIE %R 10.1672/08-178.1 %F Journal Article %0 Journal Article %J Estuaries and Coasts %D 2008 %T Consequences of climate change on the ecogeomorphology of coastal wetlands %A Day, J.W. %A Christian, R.R. %A Boesch, D.M. %A Yanez-Arancibia, A. %A Morris, J.T. %A Twilley, R.R. %A Naylor, L. %A Schaffner, L. %A Stevenson, C. %K climate change %K coastal wetlands %K disturbance %K ecogeomorphology %K LTER-PIE %K organic matter %K primary production %B Estuaries and Coasts %V 31 %P 477-491 %G eng %M PIE198 %] NSF-LTER-PIE %R 10.1007/s12237-008-9047-6 %F Journal Article %0 Book Section %B Principles and Standards for Measuring Primary Production %D 2007 %T Estimating net primary production of salt marsh macrophytes %A Morris, J.T. %E Fahey, T.J. %E Knapp, A.K. %K allometry %K harvest %K intertidal zone %K LTER-PIE %K primary production %K salt marsh %K stem turnover %B Principles and Standards for Measuring Primary Production %I Oxford University Press %P 106-119 %G eng %M PIE196 %] NSF-LTER-PIE %R 10.1093/acprof:oso/9780195168662.003.0007 %F Book %0 Journal Article %J Estuarine and Coastal Shelf Science %D 2006 %T Competition among marsh macrophytes by means of geomorphological displacement in the intertidal zone. %A Morris, J.T. %K accretion %K geomorphology %K intertidal zone %K LTER-PIE %K salt marsh %K sea level %B Estuarine and Coastal Shelf Science %V 69 %P 395-402 %G eng %M PIE160 %] NSF-LTER-PIE %R 10.1016/j.ecss.2006.05.025 %F Journal Article %0 Book Section %B Aquatic Food Webs: an Ecosystem Approach %D 2005 %T Analysis of size and complexity of randomly constructed food webs by information theoretic metrics. %A Morris, J.T. %A Christian, R.R. %A Ulanowicz, R.E. %E A. Belgrano %E U. M. Scharler %E J. Dunne %E R. E. Ulanowicz %K food web %K LTER-PIE %K modeling %B Aquatic Food Webs: an Ecosystem Approach %I Oxford University Press %P 73-85 %G eng %M PIE153 %] NSF-LTER-PIE %F Book Section %0 Journal Article %J Marine Ecological Progress Series %D 2005 %T Distribution of phosphatase activity in marsh sediments along an estuarine salinity gradient. %A Huang, X. %A Morris, J.T. %K acid phosphatase activity %K estuary %K inorganic nutrients %K LTER-PIE %K marsh sediment %K primary production %K salinity gradient %B Marine Ecological Progress Series %V 292 %P 75-83 %G eng %M PIE150 %] NSF-LTER-PIE %R 10.3354/meps292075 %F Journal Article %0 Conference Proceedings %B UNESCO Proceeding Series on Lagoons and Coastal Wetlands in the Global Change Context: Impact and Management Issues %D 2005 %T Effects of changes in sea level and productivity on the stability of intertidal marshes. %A Morris, J.T. %E Lasserre, P. %E Viaroli, P. %E Campostrini P. %K LTER-PIE %K productivity %K salt marsh %K sea level %K wetlands %B UNESCO Proceeding Series on Lagoons and Coastal Wetlands in the Global Change Context: Impact and Management Issues %C Venice %P 121-127 %8 April 26-28, 2004 %G eng %M PIE151 %] NSF-LTER-PIE %F Other %0 Book Section %B The Ecogeomorphology of Tidal Marshes %D 2004 %T Flow, sedimentation, and biomass production on a vegetated salt marsh in South Carolina: toward a predictive model of marsh morphologic and ecologic evolution. %A Mudd, S.M. %A Fagherazzi, S. %A Morris, J.T. %A Furbish, D.J. %E S. Fagherazzi %E A. Marani %E L.K. Blum %K LTER-PIE %K marsh geomorphology %K salt marsh biomass %K sedimentation %B The Ecogeomorphology of Tidal Marshes %I American Geophysical Union %C Washington, D.C. %P 165-187 %G eng %M PIE128 %] NSF-LTER-PIE %F Book Section %0 Journal Article %J Science %D 2003 %T Phosphorus Limitation of Coastal Ecosystem Processes %A Sundareshwar, P.V. %A Morris, J.T. %A Koepfler, E.K. %A Fornwalt, B. %K LTER-PIE %K nutrient limitation %K phosphorus %K salt marsh %B Science %V 299 %G eng %M PIE111 %] NSF-LTER-PIE %R 10.1126/science.1079100 %F Journal Article %0 Journal Article %J Limnology and Oceanography %D 2001 %T Occurrence and Ecological Implications of Pyrophosphate in Estuaries %A Sundareshwar, P.V. %A Morris, J.T. %A Pellechia, P.J. %A Cohen, H.J. %A Porter, D.E. %A Jones, B.C. %K estuary %K LTER-PIE %K pyrophosphate %K salt marsh %B Limnology and Oceanography %V 46 %P 1570-1577 %G eng %M PIE69 %] NSF-LTER-PIE %R 10.4319/lo.2001.46.6.1570 %F Journal Article %0 Book Section %B Concepts and Controversies in Tidal Marsh Ecology %D 2000 %T Ecophysiological controls on the growth of Spartina alterniflora %A Mendelssohn, I. A. %A Morris, J.T. %E M. P. Weinstein %E D. A. Kreeger %K LTER-PIE %K salt marsh %K Spartina %B Concepts and Controversies in Tidal Marsh Ecology %I Kluwer Academic Publishers %C Dordredt, the Netherlands. %P 59-80 %G eng %M PIE42 %] NSF-LTER-PIE %F Book Section %0 Journal Article %J Global Biogeochemical Cycles %D 2000 %T Marsh nutrient export supplied by ground water discharge: Evidence from radium measurements %A Krest, J. M. %A Moore, W.S. %A Gardner, L.R. %A Morris, J.T. %K ground water %K LTER-PIE %K marsh %K nurient export %K radium %B Global Biogeochemical Cycles %V 14 %P 167-176 %G eng %M PIE41 %] NSF-LTER-PIE %R 10.1029/1999GB001197 %F Journal Article