HelioWebCiaran J. Harman
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A[Ciaran J. Harman]
AC["Associated Concepts (23)"]
AW["Authored Works (16)"]
CA["Linked Co-Authors (19)"]
CI["Linked Collaborating Institutions (18)"]
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AW== author ==>CA
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click AW "#authored-works"
click CA "#co-authors"
click CI "#collaborating-institutions"
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- ORCiD
- https://orcid.org/0000-0002-3185-002X
- OpenAlex ID
- https://openalex.org/A5019794106 (API record)
Associated Concepts [?]
- Geology
- Engineering
- Environmental science
- Geotechnical engineering
- Biology
- Hydrology (agriculture)
- Physics
- Geography
- Computer science
- Ecology
- Mathematics
- Cartography
- Quantum mechanics
- Drainage basin
- Geometry
- Geomorphology
- Soil science
- Oceanography
- Surface runoff
- Paleontology
- Meteorology
- Groundwater
- Mechanics
Authored Works
sorted by decreasing year, and then by display-name
- Transit Times and StorAge Selection Functions at the Hillslope Scale: Model Development, Experimental Observations, and Applications of the Model
- The Geomorphic Origins of Variable Source Area Hydrology
- Looking for the Fill-and-Spill Mechanism with Ground Penetrating Radar-Panola Mountain, Georgia
- DupuitLEM and the Search for Fundamental Insights into the Coevolution of Landscape Hydrology and Geomorphology
- Defining Spatial Heterogeneity: Using Ground Penetrating Radar to Map the Boundaries between Soil, Saprolite, and Bedrock in the Critical Zone
- A parsimonious and scalable approach for linking water quality to water age in unsteady hydrologic systems
- Variation in Hillslope Sediment Size Controlled by Differences in Subsurface Weathering in a Transient Piedmont Landscape, South Carolina, USA.
- The Hydrogeomorphic Evolution of Variable Source Areas
- Strong Anisotropy in the Critical Zone: Evidence that Weathering Enhances Seismic Anisotropy in Saprolite and that Permeability Anisotropy may be Related
- Panola Mountain revisited: intensive geophysical and geochemical studies reveal the structure of the deep critical zone at a classic hydrologic study site
- Growing an Oasis: The Role of Trees in Driving Regolith Production in a Bedrock Landscape, Panola Mountain, Georgia
- Geophysical imaging reveals lithologic controls on weathering at the Panola Mountain Research Watershed, Georgia, USA
- Estimating the transit time distribution in a forested watershed with a bimodal hydrologic response using MESAS
- Controls on critical zone thickness in the Appalachian Piedmont: lithology, vegetation, and state of stress
- Connecting the deep and shallow critical zone: Quantifying inherited heterogeneity of the CZ structure
- Between-catchment variations in recession curves explained by geological diversity
Linked Co-Authors
- Bradley J. Carr
- Brady Flinchum
- C. S. Riebe
- D. Litwin
- David Dralle
- Esther Xu Fei
- G. E. Tucker
- Harihar Rajaram
- J. L. Hayes
- Kamini Singha
- Katherine R. Barnhart
- L. S. Sklar
- Minseok Kim
- R. P. Callahan
- Seulgi Moon
- Stanley B. Grant
- W. Jesse Hahm
- W. Steven Holbrook
- Yadi Wang
Linked Collaborating Institutions
- Clemson University, South Carolina
- Colorado School of Mines
- Concordia University, Canada
- Dickinson College, Pennsylvania
- Duke University, North Carolina
- Eidgenossische Technische Hochschule, Zurich, Switzerland
- Georgia Institute of Technology
- Johns Hopkins University, Maryland
- San Francisco State University, California
- Simon Fraser University, Canada
- U.S. Geological Survey
- University of Arizona
- University of California, Los Angeles
- University of Colorado, Boulder
- University of Kentucky
- University of Texas, Austin
- University of Wyoming
- Virginia Polytechnic Institute and State University
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