| Presenter | Title |
|---|
| Anarde, Katherine |
Parameterizing human dynamics in geomorphic models: learning from coastal barrier evolution models |
| Austermann, Jacky |
Solving the sea level equation: Earth’s response to ice and ocean load changes |
| Baart, Fedor |
Digital Twins in Earth Sciences |
| Balaji, Pavan |
HPCC Clinic I: Introduction to Parallel Programming with MPI (Level I) |
| Bangerth, Wolfgang |
The finite element method (FEM) |
| Banihirwe, Anderson |
Xarray for Scalable Scientific Data Analysis |
| Barnes, Richard |
Using GPUs to Solve Science Problems Faster |
| Barnes, Richard |
A Hands-On Workshop on GPU-Based Landscape Evolution Modeling |
| Barnhart, Katy |
Model sensitivity analysis and optimization with Dakota and Landlab |
| Barnhart, Katy |
Model sensitivity analysis and optimization with Dakota and Landlab |
| Barnhart, Katy |
Model Calibration with Dakota |
| Batchelor, Rebecca |
Inclusive Mentoring |
| Best, Kelsea |
Introduction to agent-based modeling for socio-environmental systems |
| Bhatt, Gopal |
Accessing National Data and Distributed Models for Catchment Simulation |
| Bovy, Benoît |
Building Interactive Dashboards for Earth Surface Processes Modeling with Python and Jupyter |
| Brown, Jed |
Building solvers for sustainable performance |
| Burgess, Peter |
Three carbonate sedimentation models for CSDMS |
| Buscombe, Daniel |
Image Segmentation using Deep Learning and Human-In-the-Loop Machine Learning |
| Buscombe, Daniel |
Part II: Landcover and landform classification using deep neural networks |
| Buscombe, Daniel |
Part I: Landcover and landform classification using deep neural networks |
| Buscombe, Daniel |
Landcover and landform classification using deep neural networks |
| Callaghan, Kerry |
Using Fill-Spill-Merge to understand and analyze landscape depressions |
| Campforts, Benjamin |
Looking Under the Hood: Landscape Evolution Modeling with TerrainBento and Landlab |
| Cheng, Zhen |
Modeling Coastal Sediment Transport Using OpenFOAM® |
| Choi, Eunseo |
SNAC: A 3D parallel explicit finite element code for long-term lithospheric deformation modeling |
| Clow, Gary |
Introduction to the Weather Research & Forecasting (WRF) System, a High-Resolution Atmospheric Model |
| Edmonds, Doug |
An Introduction to using Google Earth Engine |
| Edmonds, Doug |
An Introduction to using Google Earth Engine |
| Eric Barefoot, Andrew Moodie & |
Using the collaborative sandpiper toolchain to support interoperability in geomorphology research |
| Filatova, Tatiana |
Spatial agent-based models: introducing individual interacting actors in environmental models |
| Fleming, Jason |
Real Time ADCIRC Modelling for Coastal Zone Decision Support |
| Gabel, Vanessa |
Clinic 2: Introduction to Landlab: Getting to know the Grid and Coupling Components |
| Gan, Tian |
CSDMS@HydroShare: find, access, operate and couple data-model integration tools for reproducible research |
| Gasparini, Nicole |
Do the work: Building a more equitable research unit |
| Gasparini, Nicole |
Landlab with Hydroshare |
| Gasparini, Nicole |
Modeling the Ecosphere using Landlab |
| Gasparini, Nicole |
Modeling Earth-Surface Dynamics with Landlab 1.0 |
| Gold, Anne |
Building and Maintaining a Diverse and Inclusive Research Team |
| Goodall, Jon |
Integrated Modeling Concepts |
| Gutmann, Ethan |
Making Use of Climate Model Output: Downscaling for Regional Applications |
| Haedrich, Caitlin |
Coastal evolution analysis and inundation modeling with GRASS GIS |
| Haedrich, Caitlin |
An Introduction to GRASS GIS and Tangible Landscape |
| Hamman, Joseph |
Pangeo: Scalable Geoscience Tools in Python — Xarray, Dask, and Jupyter |
| Hariharan, Jayaram |
Rapid hypothesis testing and analysis with the open-source delta model pyDeltaRCM |
| Harris, Courtney |
Regional Ocean Modeling System (ROMS): An introductory web-based model implementation |
| Harris, Courtney |
Regional Ocean Modeling System (ROMS) |
| Hauser, Thomas |
Python for Matlab users clinic |
| Hill, Mary |
MODFLOW: Example applications and what we can learn from this amazingly successful piece of environmental modeling software. |
| Hill, Mary |
Toward Transparent, Refutable Hydrologic Models in Kansas or Oz |
| Hsu, Leslie |
Making your models and data FAIR - Findable, Accessible, Interoperable, and Reusable |
| Hutton, Eric |
Clinic 3: Component Creation with Landlab |
| Hutton, Eric |
Wrapping existing models with the Basic Model Interface |
| Hutton, Eric |
Hands-on with the Python Modeling Toolkit |
| Hutton, Eric |
Part II: Exploring Surface Processes using CSDMS Tools: How to Build Coupled Models |
| Hutton, Eric |
Part I: Exploring Surface Processes using CSDMS Tools: How to Build Coupled Models |
| Hutton, Eric |
BMI: Live! |
| Jagers, Bert |
Morphological modelling using Delft3D Flexible Mesh |
| Jenkins, Chris |
Training Datasets for Modeling with AI across the Deep-Ocean Seafloor |
| Jenkins, Chris |
Forum on Artificial Intelligence & Machine Learning: What lies ahead for Earth Surface Modeling? |
| Jenkins, Chris |
Carbonate Models Clinic - carbo* suite |
| Kazanci, Caner |
Ecological Network Analysis/EcoNet |
| Kim, Wonsuck |
SEN: Take only measurements. Leave only data |
| Koontz, Michael |
An introduction to Google Earth Engine— the planetary-scale GIS for everyone |
| LeVeque, Randall |
Finite Volume Methods for Surface Dynamics Modeling |
| LeVeque, Randy |
GeoClaw Software for Depth Average Flow |
| LeVeque, Randy |
New features and basic usage of the GeoClaw software for depth-averaged flow |
| Lee, Allen |
Good enough practices for reproducible scientific computation |
| Lee, Allen |
Git good with FAIR enough practices for scientific software development |
| Lee, Allen |
The Last FAIR Clinic You'll Ever Need* |
| Lee, Allen |
Get lazy with LLMs |
| Lenard, Sebastien |
How to Route Flow in a Landscape with Landlab? |
| Liao, Chang |
Variable resolution mesh based flow direction and hydrologic modeling: An introduction to HexWatershed |
| Liao, Chang |
Mesh independent flow direction modeling using HexWatershed 3.0 |
| Liu, Xiaofeng |
Modeling of Earth Surface Dynamics and Related Problems using OpenFOAM®. |
| Ludaescher, Bertram |
Publishing Reproducible Computational Research with the Whole Tale |
| Lunacek, Monte |
Interactive Data Analysis with Python |
| Lunacek, Monte |
Interactive Data Analysis with Python (PANDAS) |
| Lyons, Nathan |
Model sensitivity analysis using SALib |
| Madoff, Risa |
Communicating convergent heterogeneous themes in your research |
| Marder, Eyal |
Coupling biological and surface processes in landscape evolution models |
| Martin, Raleigh |
Sediment Experimentalist Network (SEN) - Wrangling your research data |
| Martin, Raleigh |
The Sediment Experimentalist Network (SEN) Knowledge Base |
| Maxwell, Reed |
Beyond Groundwater Modeling: Integrated Simulation of Watershed Systems using ParFlow |
| McDonald, Richard |
An introduction to hydraulic modeling with the Python Modeling Toolkit |
| Meiburg, Eckart |
TURBINS using PETSc |
| Mesehle, Ehab |
Coastal Ecosystem Integrated Compartment Model (ICM): Modeling Framework |
| Mitasova, Helena |
Modeling and analysis of evolving landscapes in GRASS GIS |
| Moodie, Andrew |
Developing and teaching interactive sedimentology and stratigraphy computer activities |
| Moriarty, Julia |
Introduction to Cloud Computing for Geoscientists |
| Mudd, Simon |
LSDtopotools |
| Murray, Brad |
Coastline Evolution Model (CEM) |
| Naliboff, John |
Coupling models of lithospheric deformation and surface processes with the Advanced Solver for Planetary Evolution, Convection, and Tectonics (ASPECT) - Part 2 |
| Naliboff, John |
Coupling models of lithospheric deformation and surface processes with the Advanced Solver for Planetary Evolution, Convection, and Tectonics (ASPECT) - Part 1 |
| Naliboff, John |
Coupling models of lithospheric deformation and surface processes with the Advanced Solver for Problems in Earth's Convection and Tectonics (ASPECT) |
| Olive, Jean-Arthur |
Introduction to coupled geodynamics-surface process modeling with SiStER |
| Over, Jin-Si |
Introduction to Structure-from-Motion Photogrammetry for Mapping Landscapes |
| Overeem, Irina |
Using TopoFlow in the classroom |
| Overeem, Irina |
Permafrost Toolbox |
| Overeem, Irina |
Teaching with Jupyter NoteBooks |
| Overeem, Irina |
Accelerating Glacier and Surface Processes Modeling with Machine Learning and New Python Libraries |
| Overeem, Irina |
Clinic: Using the CSDMS Modeling Tool |
| Overeem, Irina |
Exploring the influence of fault damage and fault slip on the patterns and rates of fluvial incision using CHILD and Matlab |
| Overeem, Irina |
CMT clinic |
| Overeem, Irina |
Modeling Permafrost; a new software toolbox to explore frozen grounds |
| Overeem, Irina |
Bringing CSDMS Models into the Classroom |
| Peckham, Scott |
Geoscience Paper of the Future: Training Session on Best Practices for Publishing Your Research Products |
| Peckham, Scott |
CSDMS Developer Clinic |
| Peckham, Scott |
Introduction to the Basic Model Interface and CSDMS Standard Names |
| Peckham, Scott |
Introduction to the Basic Model Interface and CSDMS Standard Names |
| Peckham, Scott |
Component-based Hydrologic Modeling: Getting Started with the TopoFlow 3.6 Python Package |
| Perez, Fernando |
From Exploration to Publication: Geospatial Research in the Jupyter Ecosystem |
| Perignon, Mariela |
ANUGA - An open-source model of river flood morphodynamics (and other hydrological disasters) |
| Pfeiffer, Allison |
Landlab’s NetworkSedimentTransporter: A Lagrangian model for riverbed material transport dynamics |
| Pierce, Ethan |
Introduction to Landlab |
| Piper, Mark |
BMI Live! |
| Piper, Mark |
WMT and the Dakota iterative systems analysis toolkit |
| Piper, Mark |
WMT: The CSDMS Web Modeling Tool |
| Piper, Mark |
BMI Live! |
| Piper, Mark |
BMI: Live! |
| Piper, Mark |
What can CSDMS do for you?
A clinic on CSDMS Products and Services |
| Pollak, Jon |
Data Access and Publication with the CUAHSI Water Data Center |
| Rajaram, Hari |
A very basic introduction to numerical methods for scientific computing |
| Reniers, Ad |
Dune erosion and overwash with XBeach |
| Roberts, Steve |
Hydrodynamic modeling using the open source package ANUGA |
| Roop, Heidi |
Communication & Engagement: Tips, Tricks, Traps and Opportunities |
| Rossi, Matthew |
Integrating Agent-Based Models into Landlab via pyNetLogo |
| Roth, Danica |
Environmental seismology and distributed acoustic sensing (DAS) |
| Roy, Samapriya |
Introduction & Building with Google Earth Engine: Batteries Included |
| Roy, Sam |
Exploring the influence of fault damage and fault slip on the patterns and rates of fluvial incision using CHILD and Matlab |
| Said, Mohamed Fathi |
Integrating CNN with LSTM Models for Capturing Spatiotemporal Dynamics of Flood Modeling |
| Schumann, Guy |
LISFLOOD-FP Clinic: Introduction to Flood Hazard Modeling |
| Schwenk, Jon |
Exploring river and delta channel networks with RivGraph |
| Shapero, Daniel |
Simulating glacier flow with ICEPACK |
| Sherwood, Chris |
How to make accurate digital elevation models using imagery from drones - or even walking around |
| Signell, Rich |
Emerging open-source Python-based infrastructure for scalable, data-proximate analysis and visualization of model output |
| Sotiropoulos, Fotis |
The SAFL Virtual StreamLab (VSL3D): High Resolution Simulation of Turbulent Flow, Sediment Transport, and Morphodynamics in Waterways |
| Swannack, Todd M. |
Accelerating multidisciplinary environmental research to application: integrating multiple models through mediated modeling |
| Swannack, Todd |
Vegetation as ecogeomorphic features: incorporating vegetation into Earth Surface Models |
| Swartz, John |
Exploring surface processes and landscape connectivity through high-resolution topography: integration of high resolution data in numerical modeling |
| Swiler, Laura |
Dakota: A Toolkit for Sensitivity Analysis, Uncertainty Quantification, and Calibration |
| Thurber, Travis |
Modeling Water Movement and Reservoir Operations with mosartwmpy |
| Tijerina, Daniella |
CUAHSI Services for Hydrologic Modeling and Data |
| Tucker, Greg |
Clinic 1: The Art of Modeling: From Concept to Math with Mass, Energy, and Momentum Balance |
| Tucker, Greg |
Landlab: A Python library for building, exploring, and coupling 2D surface-process models |
| Tucker, Greg |
Creative computing with Landlab: A flexible Python package for rapidly building and exploring 2D surface-dynamics models |
| Tucker, Greg |
Modeling Earth-Surface Dynamics with LandLab |
| Vernon, Chris |
GCAM and Demeter: A global, integrated human-Earth systems perspective to modeling land projections |
| Vernon, Chris |
GCAM and Demeter: A global, integrated human-Earth systems perspective to modeling land projections |
| Vetsch, David |
River morphodynamic modelling across scales using BASEMENT software |
| Volker Grimm, Steve Railsback & |
Pattern-oriented agent-based modeling to achieve structural realism and testable predictions |
| Watts, Joshua |
Agent-Based Modeling Research: Topics, Tools, and Methods |
| Wobus, Cam |
Physical and Socio-Economic Data for Natural Hazards |
| Wu, Wei |
Introduction to R programming and R applications in landscape ecology |
| Yang, Yang |
An Introduction to CUDA-enabled DES3D |
| Zellner, Moira |
Decision Framing |
| Zellner, Moira |
Fora.ai: Reshaping collaboration for climate and social impact |
| Zellner, Moira |
Fora.ai: A participatory modeling platform to reshape how we collaborate for climate and social impact. |
| Zellner, Moira |
Fora.ai: Embedding earth systems modeling in a collaborative framework for innovative, impactful and resilient solution-building |
| Zellner, Moira |
Fora.ai: A participatory modeling platform to reshape how we collaborate for climate and social impact |
| Zhou, Zheyu |
Modeling coastal processes using OpenFOAM |
| de Mutsert, Kim |
Introduction to Ecopath with Ecosim |
| de Mutsert, Kim |
Introduction to EcoPath with Ecosim |
