The Hydrology Research Group at Duke University is looking for highly motivated PhD students in the field of hydrological processes, data analytics, optimization and modeling. Projects in the research group seek to provide information on the interaction between climate, vegetation, land use, topography and hydro-geology on the spatio-temporal variability of surface and subsurface hydrologic processes.
POSTDOCTORAL SCHOLAR POSITION OPENING (HYDROLOGY)
Apply: https://aprecruit.ucmerced.edu/apply/JPF00555. All application materials must be submitted through this website.
Open October 25th, 2017 through December 29th, 2017
Review begins December 29. Position will remain open until filled.
Terrestrial materials exported from coastal watersheds influence marine food-webs and carbon budgets across the globe, yet much is unknown about the fundamental processes of land-sea carbon cycling or system response to climate change. On an outer-coast island near the center of the Pacific Coastal Temperate Rainforest (PCTR) in North America, the Hakai Institute has developed a long-term coastal margin observatory to examine the flux of terrestrial materials from land to sea – the origins, pathways, processes and food web consequences – in the context of long-term environmental change.
Our study area is Kwakshua Channel and all the land that drains into the channel (approximately 7000 hectares) - a natural laboratory well suited to the study of terrestrial-marine coupling in the hypermaritime coast of western North America. The terrestrial environment is ecologically and physically diverse, varying from bogs and forested wetlands to productive riparian forests. Streams are characterized by high levels of terrestrial organic matter, with concentrations varying across time and space. Kwakshua channel itself is a well-defined and accessible marine waterbody in which to observe physical mixing, microbial processing, food web uptake and ecological interactions.
Beginning in 2013, we established an integrated and multi-disciplinary study across the land-sea gradient. We are using LiDAR and other remote sensing data to examine landscape controls on terrestrial ecosystems and watershed exports. Focusing in on the sources of dissolved organic matter on land, we established a network of terrestrial ecosystem plots across a landscape gradient. Plots are used to examine community composition, stand dynamics, and soil processes, with a subset of plots outfitted for remote monitoring of soil dynamics with sensors. At stream outlets, we use a year-round sampling program and sensor network to quantify, at high temporal resolution, the amount and character of terrestrial exports from seven focal watersheds. Nearshore oceanographic conditions and plankton communities are also monitored year round, adjacent to stream outlets and at other nearshore stations within and outside the channel. Similarly, we conduct year-round sampling of microbial communities - including bacteria and protists - across the terrestrial, freshwater and marine sites.
The Critical Zone - from bedrock to tree-top - indeed plays a critical role in controlling the export of organic materials from coastal watersheds. Consequently, we use the framework of a critical zone observatory to study the watersheds of Calvert Island.
For more information, please visit our webpage.
Vegetation structure and production; dynamics of detritus in terrestrial and aquatic ecosystems; atmosphere-terrestrial-aquatic ecosystem linkages; heterotroph population dynamics; effects of human activities on ecosystems.
The Hubbard Brook Experimental Forest (HBEF) is a 3,160 hectare reserve located in the White Mountain National Forest, near Woodstock, New Hampshire. The on-site research program is dedicated to the long-term study of forest and associated aquatic ecosystems.
The HBEF was established by the USDA Forest Service, Northeastern Research Station in 1955 as a major center for hydrologic research in New England. In the early 1960's, Dr. F. Herbert Bormann and others proposed the use of small watersheds to study element cycling. In 1963, the Hubbard Brook Ecosystem Study (HBES) was initiated by Bormann and Drs. Gene E. Likens and Noye M. Johnson, then on the faculty of Dartmouth College, and Dr. Robert S. Pierce of the USDA Forest Service. They proposed to use the small watershed approach at Hubbard Brook to study linkages between hydrologic and nutrient flux and cycling in response to natural and human disturbances, such as air pollution, forest cutting, land-use changes, increases in insect populations and climatic factors.