PIE LTER Publications

Export 629 results:
Journal Article
Donatelli C., Ganju N.K., Kalra T.S., Fagherazzi S., Leonardi N..  2019.  Changes in hydrodynamics and wave energy as a result of seagrass decline along the shoreline of a microtidal back-barrier estuary.. Advances in Water Resources. 128:183-192.
Buchsbaum R., Catena E.H., James-Pirri M.J..  2006.  Changes in salt marsh vegetation, Phragmites australis, and nekton in response to increased tidal flushing in a New England salt marsh.. Wetlands. 26:544-557.
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.
Paynter I, Schaaf C, Bowen J, Deegan L, Peri F, Cook B.  2019.  Characterizing a New England Saltmarsh with NASA G-LiHT Airborne Lidar. Remote Sensing. 11:509.
Paynter I., Schaaf C., Bowen J.L., Deegan L., Peri F., Cook B..  2019.  Characterizing a New England Saltmarsh with NASA G-LiHT Airborne Lidar. Remote Sensing. 11:509-539.
Johnson D.S., Short M.I..  2013.  Chronic nutrient enrichment increases the density and biomass of the mudsnail, Nassarius obsoletus.. Estuaries and Coasts. 36:28-35.
Sun S., Fagherazzi S., Liu Y..  2018.  Classification mapping of salt marsh vegetation byflexible monthly NDVItime-series using Landsat imagery. Estuarine and Coastal Shelf Science. 213:61-80.
Colombano DD, Litvin SY, Ziegler SL, Alford SB, Baker R, Barbeau MA, Cebrian J, Connolly RM, Currin CA, Deegan LA et al..  2021.  Climate Change Implications for Tidal Marshes and Food Web Linkages to Estuarine and Coastal Nekton. Estuaries and Coasts. 44:1637–1648.
Johnson D.S., Shields J.D., Doucette D., Heard R..  2020.  A climate migrant escapes its parasites. Marine Ecological Progress Series. 641:111-121.
Morse N.B., Wollheim W.M..  2014.  Climate variability masks the impacts of land use change on nutrient export in a suburbanizing watershed. Biogeochemistry.
Deegan L.A., Johnson D.S., Warren R.S., Peterson B.J., Fleeger J.W., Fagherazzi S., Wollheim W.M..  2012.  Coastal eutrophication as a driver of salt marsh loss. Nature. 490:388-392.
Törnqvist TE, Cahoon DR, Morris JT, Day JW.  2021.  Coastal Wetland Resilience, Accelerated Sea‐Level Rise, and the Importance of Timescale. AGU Advances. 2
Törnqvist TE, Cahoon DR, Morris JT, Day JW.  2021.  Coastal Wetland Resilience, Accelerated Sea-Level Rise, and the Importance of Timescale. AGU Advances. 2:e2020AV000334.
Salgado J., Costa M-J., Cabral H., Deegan L..  2004.  Comparison of fish assemblages in tidal salt marsh creeks and in adjoining mudflat areas in the Tejo estuary.. Cahiers de Biologie Marine. 45:213-224.
Huang B., Huang J., Pontius, Jr. R.G., Tu Z..  2018.  Comparison of Intensity Analysis and the land use dynamic degrees to measure land changes outside versus inside the coastal zone of Longhai, China. Ecological Indicators. 89:336-347.
Huang B, Huang J, Pontius RGilmore, Tu Z.  2018.  Comparison of Intensity Analysis and the land use dynamic degrees to measure land changes outside versus inside the coastal zone of Longhai, China. Ecological Indicators. 89:336–347.
Morris J.T..  2006.  Competition among marsh macrophytes by means of geomorphological displacement in the intertidal zone.. Estuarine and Coastal Shelf Science. 69:395-402.
Pontius RGilmore.  2019.  Component intensities to relate difference by category with difference overall. International Journal of Applied Earth Observation and Geoinformation. 77:94–99.
Pontius, Jr. R.G..  2019.  Component intensities to relate difference by category with difference overall. International Journal of Applied Earth Observation and Geoinformation.
Iwaniec DM, Gooseff M, Suding KN, Johnson DSamuel, Reed DC, Peters DPC, Adams B, Barrett JE, Bestelmeyer BT, Castorani MCN et al..  2021.  Connectivity: insights from the U.S. Long Term Ecological Research Network. Ecosphere. 12
Day J.W., Christian R.R., Boesch D.M., Yanez-Arancibia A., Morris J.T., Twilley R.R., Naylor L., Schaffner L., Stevenson C..  2008.  Consequences of climate change on the ecogeomorphology of coastal wetlands. Estuaries and Coasts. 31:477-491.
Forbrich I., Giblin A.E., Hopkinson C.S..  2018.  Constraining Marsh Carbon Budgets Using Long-Term C Burial and Contemporary Atmospheric CO2 Fluxes. Journal of Geophysical Research: Biogeosciences. 123:867-878.
Liu Z, Fagherazzi S, Ma X, Xie C, Li J, Cui B.  2020.  Consumer control and abiotic stresses constrain coastal saltmarsh restoration. Journal of Environmental Management. 274:111110.
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.
Morris J.T., Barber D.C., Callaway J.C., Chambers R., Hagen S.C., Hopkinson C.S., Johnson B.J., Megonigal P., Neubauer S.C., Troxler T. et al..  2016.  Contributions of organic and inorganic matter to sediment volume and accretion in tidal wetlands at steady state. Earth's Future. 4:110-121.

Pages