Property:Description of your CSDMS-related interests member

- Numerical Forward Modeling - Seismic Forward Modeling - Carbonate platform in sin-rift setting  +

- PhD in Environmental Sciences - hydrodynamic modelling of transitional and coastal areas - involved in the Preparatory Phase project for the DANUBIUS Research Infrastructure - Modelling Node and Po Delta and North Adriatic Lagoons Supersite (www.danubius-ri.eu/).  +

- Terrestrial ecosystem modeling and assimilation of multi-source remote sensing data to improve these models.  +

- distributed rainfall-runoff model - urban storm runoff model  +

1) Glacial retreat and advances 2) Isostasy and glacio-isostatic modelling 3) Interactions between tectonics and volcanism 4) Links between surface processes (particularly erosion and volcanic/glacial loading) and subsurface crustal response 5) Volcanic hazard mapping and pyroclastic flow modelling 6) Ice sheet - Subglacial volcano - Climate - Crust feedback cycles  +

1) use of models to explore coastal and submarine morphodynamics for teaching and research 2) use of models to explore evolution of sedimentary fabric and structure for education and research  +

3D hydrodynamics numerical model developing  +

A farame work coupoling ofr Topoflow and the WRF model.  +

A quantitative understanding of marine systems from the continental shelf to the supratidal zone, with a focus on estuarine morphodynamics  +

ADCIRC  +

Active tectonics, topographic evolution  +

After my professional experience (17 years) as a university professor of a wide spectrum of disciplines (e.g., Ecology, General Microbiology, Human Anatomy and Physiology, Cell Biology, Classical Genetics and Evolutionary Biology), I became aware of the necessity of developing an interdisciplinary understanding of ecosystem functioning based on physics. Therefore, my current research activity is addressed to develop a general model of ecosystem functioning based on plausible theoretical links between principles of ecosystem ecology, thermodynamics, thermostatistics and quantum mechanics. The main part of the results from this effort are included in several articles published in the journal Ecological Modelling. The main advantage of the above-mentioned set of models is its validity for almost any kind of ecosystem following a fractal structure. From my research experience in economics, it seems to be that this model, with certain modifications, could be also useful to understand macroeconomics performance as well as economic development processes, in a sort of TOE which would interconnect Physics, Biology and Social Sciences.  +

Agent Based Modelling  +

Agent-based modeling of complex systems and applications toward sustainable development, co-generation of knowledge, and decision making.  +

Agricultural/Environmental Modeling  +

Aid in advancing/refining landscape evolution & hydrology models as a result of their outputs when applied to my geomorphic research.  +

All models providing results on coastal : wave, current, water level, morphodynamics, shoreline evolution. From small to large scales.  +

Am very interested in hydrological modeling and surface runoff at the global scale.  +

An internal bore is a type of large-scale geophysical flow where a shock-like height discontinuity propagates along an interface between two fluids of different densities. Internal bores are responsible for many complex and interesting atmospheric and oceanographic phenomena. The most visually striking and well-known example of an internal bore is the Morning Glory cloud formation off the northern coast of Australia (pictured at left), which is formed by the interaction of a sea-breeze with a temperature inversion layer. Internal bores can also be formed in the atmosphere by cold outflows from thunderstorms. In marine environments, internal bores can arise from several mechanisms such as the interaction of the tides with ocean floor topography, or by gravity current flows past submarine obstacles. For the last 60 years, people have been developing and refining analytical models to describe the propagation of internal bores. If the densities of the two fluids are very different, as is the case for a tidal bore, which propagates along an interface between water and air, a very accurate model describing a bore's propagation as a function of its size can be obtained by conserving mass and momentum across a control volume encompassing the more dense layer of fluid. However, if the densities are very similar, the upper fluid cannot be neglected. In this case, there is not enough information to come up with a closed form model from a control volume analysis unless we make some assumption about the energy loss across the bore. That's where we come in. To gain insight into how energy evolves and dissipates within an internal bore, we simulate them using two and three-dimensional direct numerical simulations. An example of one of our two-dimensional simulations is shown below. These simulations allow us to directly measure the energy and how it evolves as the bore propagates. Based on our results, we are able to propose a new analytical model for internal bores which takes into account mixing at the interface between the two layers. Our new model accurately predicts internal bore's propagation velocities, and can also predict the amount of energy lost to mixing. These results will soon be published in the Journal of Fluid Mechanics. We are now working on extending our model and simulations to non-Boussinesq internal bores so we can bridge the gap between Boussinesq and single-layer bores.  

Anthropogenic activities on tidal range variations in the Delaware River  +

Application of Sedflux and Hydrotrend for the modeling of martian ancient fluvial reaches and formation of river deltas  +

Application of hydrodynamic numerical models  +

Application of open-source modeling to fluvial geomorphology  +

Applications of modeling to erosion processes, geodesy, and active tectonics.  +

Apply S2S in Venezuela through research papers (thesis)  +

Apply to my research  +

Arctic related research  +

Art, Music,Sports and Computers.  +

As a beginner in ocean Modelling, I would like to setup and study the ocean modelling  +

As a general interest, colloboration and knowledge-transfer in this group sems extremely atractive to me.As more specific interest, I have seen the necessity of interdisciplinary approach on environmental issues. Solely picking one phase; such as saturated zone groundwater modeling, almost never results in a sustainable management choice. I want to first learn the modeling very well, then contribute to the more comprehensive studies on modeling/simulation in especially hydrological related cases, both water/sediment and solute transport.  +

At the Netherlands eSciencecenter we are working on an e-infrastructure for hydrological models, together with Delft University of Technology. We are interested in CSDMS as it offers similar functionality. Maybe there are opportunities for collaboration.  +

BING  +

Basin simulation  +

Be ready to race with updated world  +

Beach  +

Beach-dune interaction, coastal morphodynamics, wave-driven processes, aeolian sand transport, natural and human-impacted coastal dynamics, bio-physical processes, nature restoration  +

Better modeling  +

Bio-geomorphology, wetlands, coastal dunes  +

Biogeochemical Ocean Modeling, HABs Modeling.  +

Broad interests are the impacts on coastal environments, environmental changes in coastal zones, socio-economic and ecological vulnerability of deltas, urban vulnerability, coastal management and sustainable management of coastal and tropical environments. More specific research topics are related with vulnerability of the cities within the Amazon Delta and Estuary, urban infrastructure, socio-economic indicators and flood risk assessment.  +

CSDMS 2022 Annual Meeting, "Environmental Extremes and Earthscape Evolution (E4) is a great opportunity to learn about environmental hazards from the top scientist in the world. It is a unique opportunity for networking and finding out new discoveries in this field.  +

CSDMS Executive Assistant  +

CSDMS is a useful learning environment for my marine dynamics research where I am joined the groups that I love.  +

CSDMS standard names  +

CSDMS tools are going to be a great resource for me as I work to complete my masters project. We have mapped an artificial reef site on the inner continental shelf with five repeat Multibeam and sidescan surveys from ship and AUV platforms. There is clear evidence of scour around the 900+ reef objects, especially post Hurricane Sandy and multiple Nor'easters. I have a good and growing background in Matlab and Python and some C++, yet I have found I still struggle with understanding some concepts in computer science such as model compiling and optimization (especially for a multi-processor cluster or supercomputer). Colleagues at the Center for Coastal and Ocean Mapping have been developing great visualization tools, which I have starting working on for my masters. We have run some simple models in COAWST, yet I realize we need to move into more advanced modeling. By removing the concern, time, and effort to couple models and with high-power computing resources, CSDMS tools will greatly advance our goals of taking coupled modeled results into our developing visualization products. I also expect the growing collaboration in CSDMS community will again find me using these resources in my future career - in whatever surface dynamics projects I become involved. It was a great surprise to come across this resource at a key time in my developing career.  +

Carbon Cycle, phenology, air pollution  +

Carbon cycle  +

Carbon cycling in the terrestrial marine interface. Global scale biogeochemical cycling  +

Carbonate models  +

Carbonate sedimentology and Stratigraphy  +

Carbonates diagenesis modelling  +

Chesapeake Bay hydrodynamics  +

Climate and landscape dynamics  +

Climate, hydrology and atmospheric activity of the Holocene in North America.  +

Climate, tectonics, and biotic effects on topographic evolution, over geologic timescales.  +

Climatic and tectonic control on chemical weathering and physical erosion rates Landscape evolution models Environmental fluid dynamics  +

Co-chair of HD  +

Coastal & littoral evolution, processes & morphodynamics Tsunami & storm deposits Optical dating Sedimentology & Petrophysics  +

Coastal Hazard Modelling  +

Coastal Model  +

Coastal and estuaries dynamics  +

Coastal and terrestrial geomorphological modelling, with a particular interest in understanding the influence of geology (lithology & structure) in the modelling of landforms and landscapes  +

Coastal change hazards, sediment transport modeling, nature-based adaptation  +

Coastal circulation/tidal modeling; Sediment transport  +

Coastal evolution over decadal and centennial timescales; marine sediment transport  +

Coastal geomorphic change, Slope stability  +

Coastal hazards, and other climate change related impacts  +

Coastal hazards, coastal management, fluvial sediments  +

Coastal hydrology  +

Coastal modelling  +

Coastal morphodynamics (PhD student)  +

Coastal morphodynamics, coupled human-landscape dynamics.  +

Coastal morphodynamics, large-scale features  +

Coastal morphologic modelling  +

Coastal ocean/watershed coupling; Hydrotrend  +

Coastal oceanography, extreme events, and coastal management  +

Collaboration with Albert Kettner and James Syvitski on applying the (BQ)ART model on small river systems in Europe  +

Combined analysis of Glacial/proglacial/fluvial adjustment to climate change  +

Computational Fluid Dynamics; Coastal and Fluvial Hydraulics; Sediment Transport; Geomorphology  +

Computational Investigation of geophysical flows. Computational research in the general area of fluid dynamics and transport phenomena, with a special emphasis on geophysical fluid dynamics. Highly resolved direct numerical simulations are to be conducted, in order to obtain insight into the physical mechanisms that govern the evolution of gravity and turbidity currents.  +

Computational modelling of sediment-laden density currents  +

Connecting the CSDMS community to USGS water data  +

Contaminant Transport in unsaturated media  +

Contribution, exposure, and learning from researchers.  +

Costal geomorpholoy and sedimentology  +

Coupled Human-Natural Systems, Surface Process Modeling, Agent-Based Modeling, Complex Adaptive Systems  +

Coupled climate and silicate Earth systems  +

Coupled human-natural modeling for coastal protection strategy  +

Coupled numerical modelling of surface and deeper processes.  +

Coupling atmospheric models with CSDMS model components.  +

Coupling geodynamics with landscape evolution  +

Coupling surface dynamics with surface flows  +

Critical zone, water transport in fractures, SPAC  +

Cryosphere  +

Cryosphere. I don't see a Cryosphere Focus Research Group here.  +

Currently I'm interested in using the PLUME model to test some hypothesis about sediment clearance from the Elwha River plume. The study is largely observational, but the PLUME model may add some insights regarding natural variability.  +

DEM and for landslide and flows, sediments tranport  +

Dear Sir/ Madam I am so thankful if you add me as one of the members in the group list. My research Interests would be Tropical Meteorology, Indian Monsoons, Hurricane/ Cyclone prediction, Ocean Surface studies, Air Quality Modeling, Remote Sensing  +

Debris Flows, critical zone interactions, wildfire  +

Debris flow erosion modelling  +

Decision Making related to coastal flood hazards and risk  +

Deep-water  +

Delta morphology and stratigraphy  +

Delta processes, fluvial processes, coastal processes  +

Delta sensitivity to environmental change, coastal zone oceanography  +

Deltas Simulation  +

Denudation chronology  +

Deslizamientos de tierras producto de modificaciones antropicas  +

Develop new collaborations for research  +

Developer of the ANUGA flood and tsunami software package.  +

Developer on Landlab  +

Development and application of eco-geohydrological models  +

Development of GEOCLAW, geophysical fluid simulation software  +

Digital terrain and Earth surface process modeling for geohazard and risk assessment in both terrestrial and marine settings.  +

Distributed Hydrological model  +

Distributed hydrologic, snow redistribution, and landscape evolution modeling. In particular, the use of RHESSys / Noah / other hydrologic models to simulate bark beetle impacts on hydrology, the use of SNOWMODEL to analyze snow redistribution and it's potential effects on ice core isotopic composition, and a new model to simulate the evolution of Coral Atolls.  +

Distributed hydrology models  +

Doing tsunami modelling using the GeoClaw code  +

Drought, Water Resources Management, Wind Erosion and Dust Storm in Arid and Semi-Arid Areas  +

Dune Dynamic Models  +

Dynamic Model  +

Dynamic coastal changes, overnight and over years  +

ESPIn  +

Earth Surface Processes Modeling  +

Earth Surface Processes, Geophyisics, Programming  +

Earth surface dynamics  +

Earth-surface processes and basin sedimentation; undergraduate science education  +

Earthquake-induced landslides and landscape dynamics  +

Eco-hydrological modeling, droughts, fire  +

Ecogeomorphology & Landscape evolution; Quaternary fluvial environments  +

Ecohydrological Modelling in agricultural systems  +

Ecological modeling, Aquatic systems, integrated coastal modeling  +

Ecosystem modeling and coastal restoration, Toxicology  +

Effects of anthropogenic activities on the dynamics of geomorphological processes in arid zones. Modeling. Debris flows generation. Landscape and geomorphic restoration  +

Environmental Management of Landscapes  +

Environmental hydraulics sediment transport multiphase flow CFD  +

Erosion modelling, UAV data acquisition, spatial analysis, vegetation growth modelling, coupling models of human and natural systems  +

Ethnography of Flooding and Flood Control Geoscience as Material Culture  +

Exploring CSDMS models and practices  +

Fault modeling  +

Feedbacks between tectonics and surface processes.  +

Fjord sedimentation / IRD modelling  +

Flood Geomorphology  +

Flood hazard, scour  +

Fluvial Geomorphology, River Networks, Complexity, Self-Organization, Landscape Evolution  +

Fluvial and Shallow Marine stratigraphy  +

Fluvial and coastal processes. Numerical modelling, laboratory and field work. Fluid dynamics and sediment transport.  +

Fluvial and deltaic surface processes along with resultant stratigraphy  +

Fluvial dynamics, hydraulics, sedimentology  +

Fluvial geomorphology  +

Fluvial modelling  +

Fluvial, coastal and deltaic modeling  +

Fluvial, estuarine, deltaic, coastal and marine environments  +

For a class I am taking.  +

For my thesis  +

For use at the NCED Summer Institute  +

Forward modeling of marine basins  +

GENESIS Model  +

GEODYNAMICS ,BASIN , MARINE , HYDROLOGY  +

GIS Hydrologic Modeling of Surface Dynamics  +

GLOF modeling  +

Geodynamic processes modelling  +

Geodynamics, tectonics, landforms, tectonic geomorphology  +

Geohazard Mitigation  +

Geohazard prevention, landslide and debris flow  +

Geomorphic change and fluvial sediment dynamics in tectonically active landscapes.  +

Geomorphic change detection, modeling, and prediction  +

Geomorphic modeling, SIESD  +

Geomorphology  +

Geomorphology  +

Geomorphology of human disturbance and related risks by natural disasters  +

Geomorphology, Hillslope erosion, hydrology, Critical zone science  +

Geomorphology, community modeling  +

Geomorphology, fluvial geomorphology, sediment transport, landscape evolution, GIS  +

Geomorphology, hydrology, modelling  +

Geomorphology, landform evolution, river basin studies  +

Getting a better understanding of the available models and appropriate applications for future water resorce decision making in the Walla Walla  +

Glacial Isostatic Adjustment, Meandering Rivers  +

Glacial erosion, inverse models  +

Glacial landscape evolution; coastal change  +

Glacial modelling  +

Glacier dynamics; climate change  +

Glacier erosion & sedimentation  +

Glacier modelling; Quaternary climate change; geomorphology; geochronology  +

Glacier-hydrology interactions  +

Global-scale coupling of the Water Balance Model (WBM) to 2-D LISFLOOD-FP inundation modeling for long-term event-continuous flood simulations.  +

Groundwater  +

Groundwater sustainability in agroecosystems focusing on vadose-zone and groundwater hydrology, contaminant transport and fate, data-driven and physics-based modeling, and engineering solutions including managed aquifer recharge and green infrastructure.  +

Growing technical network, help people, access resources and ask problems  +

Growth, history and ecology of coral reefs  +

HIDRODINAMIC  +

HPC, computational science and engineering education  +

Hello, I am an undergraduate student at the University of Victoria who is working on completing her honours in Geography. For my project, I am hoping to use the model Hydrotrend to model change in river discharge and sediment load in the Skeena watershed in British Columbia.  +

Help with content  +

High-performance computing applications in coastal sediment transport, environmental fluid mechanics  +

Highly parallel benchmarking and computing  +

Highly parallel benchmarking and computing  +

Hydraulics and sediment transport.  +

Hydraulics, sediment transport, and river-driven landscape evolution  +

Hydro-Trend Modelling  +

Hydro-geomorphologic modeling  +

Hydrodynamic Model  +

Hydrogeochemistry, hydrology and Environmental Engineering  +

Hydrogeology Geomorphology Sedimentology  +

Hydrolody and mathematicals models  +

Hydrologic and Hydraulic Modeling  +

Hydrologic modeling, flood forecasting, cyber infrastructure  +

Hydrological Applications with remote sensing  +

Hydrological Modelling, Automation, Geo-spatial Modelling  +

Hydrological and Hydraulic modelling for flood simulation and management and Machine learning to improve model predictions  +

Hydrological modeling, 2D models, Wetlands hydrology, Wadi hydrology. Modelling in ungaged basins. Lisflood-Fp, SWAT, GIS and modelling  +

Hydrological modelling  +

Hydrological modelling, fluvial morphology, watershed erosion, and coastal morphodynamics, and education.  +

Hydrological models, precipitation models, topographic information processing  +

Hydrology  +

Hydrology .. integration of hydro and economics  +

Hydrology and Hydrogeology  +

Hydrology model  +

Hydrology, Glaciology, Porous Media  +

Hydrology, geomorphology, and ecology  +

Hydrology, rivers, and BMI  +

I am PI/organizer of the Coupling Surface and Tectonic Processes workshop (25-27 April 2018, Boulder)  +

I am PhD student I am looking for any research about Ocean energy with focusing on the wave energy.  +

I am a Master's student in geomorphology at San Jose State University, and am interested in modeling earth surface processes.  +

I am a PhD at INSTAAR, using simple glacier models to reconstruct past glacier fluctuations and explore the climate sensitivity of small glacier and ice cap systems at high latitudes.  +

I am a PhD student and I am currently working on understanding the keen relationship between granular systems and fluid dynamics to explain how cohesion influences fluvial erosion. I am currently fashioning the skills in computational techniques to model and stimulate cohesive grains coupled with CFD; thus, the interest in CSDMS.  +

I am a PhD student who does climate, biogeochemistry, and marine ecosystem modeling, largely with a focus on paleoclimate and future climate change.  +

I am a college student of Geology,so I want to acquire the latest news of CSDMS,so please  +

I am a computer scientist interested in building scientific models that combine domain expertise with data.  +

I am a developer of SIGNUM, a landscape evolution model hosted on CSDMS. My main interest is remote sensing, with applications to hazard monitoring.  +

I am a doctoral student at the University of Minnesota under Donna Whitney and Christian Teyssier. I am focused on designing and executing numerical experiments on the development of continental lithosphere under extension. I am currently working on a suite of numerical experiments that test the relative importance of sedimentation and lithospheric rheology on the localisation of strain within rifts.  +

I am a geomorphologist by profession and I am new to learning modelling. CSDMS will help me fulfill my desire to be a landscape modeller.  +

I am a geomorphologist, PhD student in Eötvös Loránd University, Budapest. My topic is related to drainage network development in karstic areas, mainly focus on the formation of deep and steep walled valleys. I'm interested in topics in connection with karst, landscape evolution, valley developement, gorges, climate caused landform changes.  +

I am a grad student at CSDMS  +

I am a graduate student at National University of Science and Technology, Islamabad, Pakistan. I am doing my research on developing GIS based flood awareness system and I need to experiment on various hydrological models. I will be using the models on data of my region. I will contribute code optimisation or a GUI component based on the model for benefit of the community.  +

I am a model developer and user undertaking research and consultancy in New Zealand rivers and coasts. I am particularly interested in morphological modelling of braided gravel bed rivers.  +

I am a new professor and I am currenlty building my working network  +

I am a postdoctoral researcher in the fields of fluvial geomorphology, landscape evolution and hydrology.  +

I am a sedimentologist and I use recent to ancient field datasets to say something 'reasonably quantitative' about our Earth's past. Vague huh? I'd like to get involved with CSDMS to explore possibilities of using models to test specific hypothesis through collaboration with modellers. I am also interested in using 'big data' to place bounds on sedimentary system behavior from a simplified viewpoint.  +

I am a student of geology at Colorado College, learning how to build landscape models.  +

I am a tectonic geomorphologist, particularly intrigued by tectonic and surface processes patterns within subduction zone forearcs. I have been working with cosmogenic nuclides and I am generally a field geologist, but I am increasingly interested in learning numerical skills to complement my research profile.  +

I am an environmental engineering undergrad working on a research project in earth systems dynamics.  +

I am an intern in the Risk Assessment department of the INL. The Risk Assessment department is currently trying to assess the risk and damage that occurs when a nuclear plant is flooded—whether by tsunami, dam or levee break, or rainfall.  +

I am an underwater archaeology who reconstructs past environments on the continental shelf.  +

I am assisting with the NCED summer institute taking place mid August at the St. Anthony Falls Labratory in Minneapolis.  +

I am currently a PhD student at the University of Florida. As a part of my proposed PhD work, I am considering the use of WBMsed to assess the cumulative effects dams, climate change, and land use/cover change on the Madeira Basin sediment loads. With results from my proposed two-model exercise, I will assess the sedimentation rate of the Jirau Dam in Brazil along the Madeira River.  +

I am dedicated to research in hydrology, numerical methods and geoprocessing  +

I am doing a presentation on Coastal Modelling for my Adv. Dipl. in GIS at BCIT.  +

I am enrolled in a Irina Overeem's surface modeling course this semester.  +

I am insterested in modeling techiniques and its applications. As research and education tools.  +