Pages that link to "Item:Q45227"

The following pages link to Joel Carr, Ph.D. (Q45227):

Displayed 30 items.

• Quantifying slopes as a driver of forest to marsh conversion using geospatial techniques: Application to Chesapeake Bay coastal-plain, USA (Q145739) ‎ (← links)
• Global virtual water trade and the hydrological cycle: Patterns, drivers, and socio-environmental impacts (Q149890) ‎ (← links)
• GPS data from 2019 and 2020 campaigns in the Chesapeake Bay region towards quantifying vertical land motions (Q150358) ‎ (← links)
• Mangroves provide blue carbon ecological value at a low freshwater cost (Q150479) ‎ (← links)
• Spatially explicit feedbacks between seagrass meadow structure, sediment and light: Habitat suitability for seagrass growth (Q151648) ‎ (← links)
• Sea level driven marsh expansion in a coupled model of marsh erosion and migration (Q153085) ‎ (← links)
• Progress Through Partnerships - Chesapeake Bay Vertical Land Motion Project (Q227269) ‎ (← links)
• The Response of Coastal Wetlands to Sea-level Rise: Understanding how Macroscale Drivers Influence Local Processes and Feedbacks (Q227868) ‎ (← links)
• The response of coastal wetlands to sea-level rise: Understanding how macroscale drivers influence local processes and feedbacks (Q227876) ‎ (← links)
• Virginia Coast Reserve Long Term Ecological Research VII (Q227888) ‎ (← links)
• Tree island pattern formation in the Florida Everglades (Q238249) ‎ (← links)
• Biophysical drivers of coastal treeline elevation (Q253764) ‎ (← links)
• The Global food‐energy‐water nexus (Q254492) ‎ (← links)
• Experimental tree mortality does not induce marsh transgression in a Chesapeake Bay low-lying coastal forest (Q266098) ‎ (← links)
• Impacts of seagrass dynamics on the coupled long-term evolution of barrier-marsh-bay systems (Q267950) ‎ (← links)
• Modelling marsh-forest boundary transgression in response to storms and sea-level rise (Q268512) ‎ (← links)
• Modeling marsh dynamics using a 3-D coupled wave-flow-sediment model (Q270266) ‎ (← links)
• Rising seas could cross thresholds for initiating coastal wetland drowning within decades across much of the United States (Q272011) ‎ (← links)
• Exploring the impacts of seagrass on coupled marsh-tidal flat morphodynamics (Q279837) ‎ (← links)
• Variability in marsh migration potential determined by topographic rather than anthropogenic constraints in the Chesapeake Bay region (Q284572) ‎ (← links)
• Foundations of modeling resilience of tidal saline wetlands to sea-level rise along the U.S. Pacific Coast (Q293986) ‎ (← links)
• Microtopographic variation as a potential early indicator of ecosystem state change and vulnerability in salt marshes (Q295809) ‎ (← links)
• Planning hydrological restoration of coastal wetlands: Key model considerations and solutions (Q296474) ‎ (← links)
• Climatic controls on the distribution of foundation plant species in coastal wetlands of the conterminous United States: Knowledge gaps and emerging research needs (Q311182) ‎ (← links)
• When and where could rising seas cross thresholds for initiating wetland drowning across conterminous United States? (Q318115) ‎ (← links)
• Surface Elevation Tablet Measurements from 10 USGS Sites Along the US Atlantic Coast (2005-2020) (Q318749) ‎ (← links)
• Mangrove Elevation and Species' Responses to Sea-level Rise Across Pohnpei, Federated States of Micronesia (ver. 1.1, December 2021) (Q324835) ‎ (← links)
• Water levels (November 11 2016 through November 11 2017) for four wells and Light intensity data (October 1 2015 through September 2019): from marsh to upland forest, for Moneystump Marsh, Blackwater National Wildlife Refuge, Maryland (Q325636) ‎ (← links)
• Environmental and Vegetation Data from Marsh-Forest Transgression Experiment at Blackwater National Wildlife Refuge, MD, USA (Q326921) ‎ (← links)
• LEAN-Corrected Chesapeake Bay Digital Elevation Models, 2019 (Q330856) ‎ (← links)