Item talk:Q227403

{

 "@context": "http://schema.org/",
 "@type": "WebPage",
 "additionalType": "Project",
 "url": "https://www.usgs.gov/centers/california-water-science-center/science/influence-geomorphology-sediment-accretion-and-soil",
 "headline": "The influence of geomorphology on sediment accretion and soil carbon development in a restored tidal wetland, White Slough, Humboldt Bay National Refuge, CA",
 "datePublished": "February 4, 2022",
 "author": [
   {
     "@type": "Person",
     "name": "Jennifer A.  Curtis",
     "url": "https://www.usgs.gov/staff-profiles/jennifer-a-curtis",
     "identifier": {
       "@type": "PropertyValue",
       "propertyID": "orcid",
       "value": "0000-0001-7766-994X"
     }
   }
 ],
 "description": [
   {
     "@type": "TextObject",
     "text": "To address these problems, former tidelands are being restored to functional tidal wetlands using two methods that can increase carbon accumulation rates. The beneficial re-use of sediment to fill subsided areas and restore elevations that support salt marsh vegetation and breaching of the historic dikes to restore tidal hydrology."
   },
   {
     "@type": "TextObject",
     "text": "Though tidal wetlands are smaller in size when compared to inland ecosystems (like forests) they have the ability to sequester more carbon per unit area, making them an incredible climate change mitigation tool. Because of the connection of these coastal habitats to the ocean, the carbon in these areas is frequently referred to as blue carbon."
   },
   {
     "@type": "TextObject",
     "text": "This project involves research conducted by the California Water Science Center and the Western Ecological Research Center in an area of the Humboldt Bay National Wildlife Refuge called the White Slough Unit (WSU)."
   },
   {
     "@type": "TextObject",
     "text": "Is the restoration site depositional? (Wetland Sediment Accretion) - Sediment deposition and accretion measurements will be made using surface elevation table (SET) and marker horizons (MH). To do this, a network of 12 SET-MHs will be installed within the restored areas of the WSU. Data gathered from this task will help determine whether the site is depositional and whether accretion co-varies with elevation and distance from sediment source."
   },
   {
     "@type": "TextObject",
     "text": "How does soil carbon develop? (Soil Carbon Development) - After establishing a network of soil coring sites, three or more soil cores will be collected at each site throughout the duration of the study. Lab analysis of shallow cores (10 cm) will include particle size, bulk density, and total organic carbon (TOC). Samples will also be compared to additional cores collected in two control sites (a natural and formerly restored tidal wetland). Results from this task will be used to determine whether there are measurable increases in TOC and to compare carbon accumulation with the control sites. To determine the extent to which hydroperiod, salinity, and vegetation are drivers of carbon accumulation these variables will be measured to whether these drivers co-vary with the accumulation of TOC."
   },
   {
     "@type": "TextObject",
     "text": "In 2015, a phased restoration of 40 acres of diked brackish wetland began in the White Slough Unit (WSU) of the Humboldt Bay National Wildlife Refuge (NWR). The non-engineered earthen dikes in the WSU were experiencing seepage, erosion, and spill over, and the former tidelands behind the dikes had experienced 3 feet of land-surface subsidence. The California State Coastal Conservancy (SCC), with funding provided by California Department of Fish and Wildlife (CDFW) Wetlands Restoration for Greenhouse Gas Reduction (GHG) Program, will determine the net greenhouse gas benefit of the White Slough Tidal Wetland Restoration Project. The USGS is aiding this effort by conducting post-project monitoring and investigating the influence of geomorphology on marsh formation and carbon accumulation rates."
   },
   {
     "@type": "TextObject",
     "text": "This study will contribute to regional and national tidal wetland assessments. Tidal wetlands function as blue carbon sinks in the long term, but the uncertainties are large and focused post-project monitoring is needed. The proposed work will reduce uncertainty and fill important knowledge gaps regarding the role and the timescale of tidal wetland restoration for mitigating greenhouse gas emissions and determining risks to coastal infrastructure from sea-level rise."
   },
   {
     "@type": "TextObject",
     "text": "The proposed work is divided into four tasks, each addressing one of the questions mentioned above:"
   },
   {
     "@type": "TextObject",
     "text": "Tidal wetlands contribute to blue carbon sequestration and provide important habitat for fish, invertebrates, shorebirds, and waterfowl while also acting as a filter for pollutants and buffering adjacent lands from flood tides, storms and increase the resiliency of coastal ecosystems to storms and rising sea levels. The California State Coastal Conservancy will use the monitoring results to estimate the net carbon benefit of the restored tidal wetlands and to develop guidance documents for tidal wetlands restoration."
   },
   {
     "@type": "TextObject",
     "text": "Coastal vegetated habitats, such as tidal wetlands, play an active role in the global carbon cycle. This is done through the removal of CO2 by living vegetation through photosynthesis and by the decay of organic matter and its burial for hundreds to thousands of years."
   },
   {
     "@type": "TextObject",
     "text": "In California, tidal wetlands soils sequester about 0.08% of one year\u2019s state-wide greenhouse gas (GHG) emissions. However, they store about 23% of the annual CO2 emissions in their soils. San Francisco Bay has the largest area of tidal wetlands in California. However, further north, Humboldt Bay has the second largest tidal wetlands area and is an important contributor to the blue carbon stock."
   },
   {
     "@type": "TextObject",
     "text": "How does site topography evolve? (Topographic Change) \u2013 Time-lapse cameras will be installed near the breached locations to document any short-term topographic changes. Annual topographic surveys across the restoration site will be used to measure elevation changes and rates of compaction and to determine elevation changes and whether deposition and accretion rates outpace compaction."
   },
   {
     "@type": "TextObject",
     "text": "How does geomorphology influence rates of sediment accretion and carbon accumulation? (Eco-geomorphic Feedback) - The geomorphology of the restored areas fundamentally determines how carbon is transported into and out of restored salt marshes. Eco-geomorphic feedbacks results in an equilibrium elevation where plant productivity and sediment trapping are maximized. This task will investigate the influence of topography on sediment accretion and organic carbon accumulation using the monitoring data collected in Tasks 1, 2, and 3."
   },
   {
     "@type": "TextObject",
     "text": "The accumulation of carbon in tidal wetlands is highly dependent on local variations in geomorphology and soil processes. Over the long-term, the restored tidal wetlands will create a carbon sink for sequestering greenhouse gases. This study will investigate geomorphic processes that fundamentally influence carbon cycling in a restored tidal wetland. The proposed work is divided into four tasks with each task addressing a key question."
   },
   {
     "@type": "TextObject",
     "text": "1.    Is the restoration site depositional and acting as a sink for sediment and carbon?\n2.    How does soil carbon develop, is there a positive trend, and what are the local drivers?\n3.    How does site topography evolve, is there compaction, or formation of tidal channels?\n4.    How does the geomorphology influence the rates of sediment accretion and carbon accumulation?"
   },
   {
     "@type": "TextObject",
     "text": "During the late 19th and early 20th centuries, diking and drainage of salt marshes was done to convert such lands to agricultural use. This practice created arable land by preventing tidal water exchange but also reduced the flow of sediment, carbon, and nutrients both into and out of marshes and resulted in subsidence (loss of elevation) related to oxidation of soils and agricultural practices."
   }
 ],
 "funder": {
   "@type": "Organization",
   "name": "California Water Science Center",
   "url": "https://www.usgs.gov/centers/california-water-science-center"
 },
 "about": [
   {
     "@type": "Thing",
     "name": "Restoration"
   },
   {
     "@type": "Thing",
     "name": "Science Technology"
   },
   {
     "@type": "Thing",
     "name": "blue carbon"
   },
   {
     "@type": "Thing",
     "name": "Aquatic Ecosystems"
   },
   {
     "@type": "Thing",
     "name": "Information Systems"
   },
   {
     "@type": "Thing",
     "name": "Land Use"
   },
   {
     "@type": "Thing",
     "name": "Measuring and Monitoring"
   },
   {
     "@type": "Thing",
     "name": "Methods and Analysis"
   },
   {
     "@type": "Thing",
     "name": "geoecology"
   },
   {
     "@type": "Thing",
     "name": "Geology"
   },
   {
     "@type": "Thing",
     "name": "Ecosystems"
   },
   {
     "@type": "Thing",
     "name": "Water"
   },
   {
     "@type": "Thing",
     "name": "Coasts"
   },
   {
     "@type": "Thing",
     "name": "Energy"
   },
   {
     "@type": "Thing",
     "name": "Geomorphology"
   },
   {
     "@type": "Thing",
     "name": "Environmental Health"
   }
 ]

}