CSDMS - User contributions [en]

User:Lroberge

2026-03-21T19:39:15Z

Lroberge:

{{Signup information member
|First name member=Laurent
|Last name member=Roberge
|Institute member=Geological Survey of Canada
|City member=Vancouver
|Country member=Canada
|Confirm email member=lroberge@tulane.edu
|Working group member=Terrestrial Working Group, Hydrology Focus Research Group, River Network Modeling Initiative
|Emaillist group member=yes
|Description of your CSDMS-related interests member=Landscape evolution, surface processes, information propagation, emergence
|Memberagreement=I have read and agree to the Privacy Policy
}}

2026 CSDMS meeting-034

2026-03-21T19:29:14Z

Lroberge: Created page with "{{CSDMS meeting personal information template-2026 |CSDMS meeting first name=Laurent |CSDMS meeting last name=Roberge |CSDMS meeting institute=Geological Survey of Canada |CSDMS meeting city=Vancouver |CSDMS meeting country=Canada |CSDMS meeting email address=lroberge@tulane.edu }} {{CSDMS meeting select clinics1 2026 |CSDMS_meeting_select_clinics1_2026=4) The Art of Modeling: From Concept to Math with Balance Equations }} {{CSDMS meeting select clinics2 2026 |CSDMS_meet..."

{{CSDMS meeting personal information template-2026
|CSDMS meeting first name=Laurent
|CSDMS meeting last name=Roberge
|CSDMS meeting institute=Geological Survey of Canada
|CSDMS meeting city=Vancouver
|CSDMS meeting country=Canada
|CSDMS meeting email address=lroberge@tulane.edu
}}
{{CSDMS meeting select clinics1 2026
|CSDMS_meeting_select_clinics1_2026=4) The Art of Modeling: From Concept to Math with Balance Equations
}}
{{CSDMS meeting select clinics2 2026
|CSDMS_meeting_select_clinics2_2026=3) Using Machine Learning for Landscape Feature Detection: Beaver Dams and Beyond!
}}
{{CSDMS meeting select clinics3 2026
|CSDMS_meeting_select_clinics3_2026=1) TopoRivBlender: Reproducible 3D Visualizations in Blender and Python
}}
{{CSDMS meeting abstract yes no 2026
|CSDMS meeting abstract submit 2026=No
}}
{{CSDMS meeting abstract poster Epub 2026}}
{{CSDMS meeting abstract title temp2026}}
{{CSDMS meeting abstract template 2026}}
{{blank line template}}

2024 CSDMS meeting-016

2024-01-22T18:02:38Z

Lroberge: Created page with "{{CSDMS meeting personal information template-2024 |CSDMS meeting first name=Laurent |CSDMS meeting last name=Roberge |CSDMS meeting institute=Tulane University |CSDMS meeting city=New Orleans |CSDMS meeting country=United States |CSDMS meeting state=Louisiana |CSDMS meeting email address=lroberge@tulane.edu }} {{CSDMS meeting select clinics1 2024 |CSDMS_meeting_select_clinics1_2024=2) Vegetation as ecogeomorphic features }} {{CSDMS meeting select clinics2 2024 |CSDMS_me..."

{{CSDMS meeting personal information template-2024
|CSDMS meeting first name=Laurent
|CSDMS meeting last name=Roberge
|CSDMS meeting institute=Tulane University
|CSDMS meeting city=New Orleans
|CSDMS meeting country=United States
|CSDMS meeting state=Louisiana
|CSDMS meeting email address=lroberge@tulane.edu
}}
{{CSDMS meeting select clinics1 2024
|CSDMS_meeting_select_clinics1_2024=2) Vegetation as ecogeomorphic features
}}
{{CSDMS meeting select clinics2 2024
|CSDMS_meeting_select_clinics2_2024=4) Coupling biological and surface processes in landscape evolution models
}}
{{CSDMS meeting select clinics3 2024
|CSDMS_meeting_select_clinics3_2024=4) A Hands-On Workshop on GPU-Based Landscape Evolution Modeling
}}
{{CSDMS meeting abstract yes no 2024
|CSDMS meeting abstract submit 2024=No
}}
{{CSDMS meeting abstract poster Epub 2024}}
{{CSDMS meeting abstract title temp2024}}
{{CSDMS meeting abstract template 2024}}
{{blank line template}}

Lab-0024

2021-10-27T19:25:58Z

Lroberge:

{{Labbasics
|Labtitle=Including wildfires in a landscape evolution model
|LabCOModule=1 of 1
|LabDateContributedOrUpdated=2021-10-27
|LabDescriptionShort=Explore the effect of stochastic wildfires on riverine sediment flux. We use the SPACE model to simulate fluvial processes and introduce a stochastic wildfire model. Students can experiment by changing the rate of fires and other parameters.
|LabCODuration=1.0 hrs
|LabModelDocumentation=SPACE
|LabAssociatedLesson=Jupyter Notebook
|LabURLStartNotebook=https://csdms.rc.colorado.edu/hub/user-redirect/git-pull?repo=https%3A%2F%2Fgithub.com%2Fjkpierce%2Ffirescapes&urlpath=tree%2Ffirescapes%2Ffires_sediment.ipynb&branch=main
}}
{{LabContributorData
|LabContributorName=Kevin Pierce
|LabContributorInstitute=University of British Columbia
}}
{{LabContributorData
|LabContributorName=Laurent Roberge
|LabContributorInstitute=Tulane University
}}
{{LabContributorData
|LabContributorName=Nishani Moragoda
|LabContributorInstitute=University of Alabama
}}
{{LabIntro
|LabDescription=This lab is appropriate for advanced undergraduates and graduate students majoring in earth science/engineering.

We will use Landlab to generate a grid, use two different landscape evolution models (LEMs) to evolve a synthetic landscape, apply stochastic wildfires that increase erodibility, and plot various maps and graphs. Though no real-world data are used, the landscape relief is statistically realistic and roughly approximate to the Wasatch mountains in Utah.
|LabPicture=BurnedAreaM.jpg
}}
{{LabClassroomOrganization
|LabCOIntro=This Jupyter Notebook is best for people who already have a conceptual understanding of earth surface processes and want to learn how these apply to numerical modeling, landscape evolution, and sediment flux. Although no Python skills are required to run the notebook, those with an intermediate understanding of Python will be able to learn more by reading the code.

This lab can be run on the CSDMS JupyterHub. (Follow the instructions here to create an account if you don't already have one: https://csdms.colorado.edu/wiki/JupyterHub.) Run the Jupyter Notebook by clicking the "start" link under the Run online heading at the top of this page.

If you have questions, please contact us through the CSDMS Help Desk: https://github.com/csdms/help-desk.
}}
{{LabLearningObjectivesSkills
|LabSkill=Use Landlab to generate a grid
}}
{{LabLearningObjectivesSkills
|LabSkill=Use Fastscape and SPACE for landscape evolution
}}
{{LabLearningObjectivesSkills
|LabSkill=Create plots
}}
{{Headerplaceholder}}
{{LabTopicalLearningObjectives
|LabTopicalLearningObjective=Landscape evolution
}}
{{LabTopicalLearningObjectives
|LabTopicalLearningObjective=Stream Power equation
}}
{{LabTopicalLearningObjectives
|LabTopicalLearningObjective=Wildfires
}}
{{LabTopicalLearningObjectives
|LabTopicalLearningObjective=Sediment flux
}}
{{LabNotes
|LabNotesInstructions=You can run the Jupyter Notebook by clicking "start" under "Run online" at the top of this page. Alternatively, the lab can be downloaded using the "download" link at the top of the page.
|LabAcknowledgements=This lab was created during CSDMS's ESPIn 2021 summer workshop. Thank you to everyone involved in organizing and teaching ESPIn.
}}
{{LabReferences
|LabReferences=Braun, J., Willett, S. (2013). A very efficient O(n), implicit and parallel method to solve the stream power equation governing fluvial incision and landscape evolution. Geomorphology 180-181(C), 170-179. https://dx.doi.org/10.1016/j.geomorph.2012.10.008
}}
{{LabReferences
|LabReferences=Shobe, C. M., Tucker, G. E., and Barnhart, K. R.: The SPACE 1.0 model: a Landlab component for 2-D calculation of sediment transport, bedrock erosion, and landscape evolution, Geosci. Model Dev., 10, 4577–4604, https://doi.org/10.5194/gmd-10-4577-2017, 2017.
}}

Lab-0024

2021-10-27T18:34:00Z

Lroberge:

{{Labbasics
|Labtitle=Including wildfires in a landscape evolution model
|LabCOModule=1 of 1
|LabDateContributedOrUpdated=2021-10-27
|LabDescriptionShort=Explore the effect of stochastic wildfires on riverine sediment flux. We use the SPACE model to simulate fluvial processes and introduce a stochastic wildfire model. Students can experiment by changing the rate of fires and other parameters.
|LabCODuration=1.0 hrs
|LabModelDocumentation=SPACE
|LabAssociatedLesson=Jupyter Notebook
}}
{{LabContributorData
|LabContributorName=Kevin Pierce
|LabContributorInstitute=University of British Columbia
}}
{{LabContributorData
|LabContributorName=Laurent Roberge
|LabContributorInstitute=Tulane University
}}
{{LabContributorData
|LabContributorName=Nishani Moragoda
|LabContributorInstitute=University of Alabama
}}
{{LabIntro
|LabDescription=This lab is appropriate for advanced undergraduates and graduate students majoring in earth science/engineering.

We will use Landlab to generate a grid, use two different landscape evolution models (LEMs) to evolve a synthetic landscape, apply stochastic wildfires that increase erodibility, and plot various maps and graphs. Though no real-world data are used, the landscape relief is statistically realistic and roughly approximate to the Wasatch mountains in Utah.
|LabPicture=BurnedAreaM.jpg
}}
{{LabClassroomOrganization
|LabCOIntro=This Jupyter Notebook is best for people who already have a conceptual understanding of earth surface processes and want to learn how these apply to numerical modeling, landscape evolution, and sediment flux. Although no Python skills are required to run the notebook, those with an intermediate understanding of Python will be able to learn more by reading the code.

This lab can be run on the CSDMS JupyterHub. (Follow the instructions here to create an account if you don't already have one: https://csdms.colorado.edu/wiki/JupyterHub.) Run the Jupyter Notebook by clicking the "start" link under the Run online heading at the top of this page.

If you have questions, please contact us through the CSDMS Help Desk: https://github.com/csdms/help-desk.
}}
{{LabLearningObjectivesSkills
|LabSkill=Use Landlab to generate a grid
}}
{{LabLearningObjectivesSkills
|LabSkill=Use Fastscape and SPACE for landscape evolution
}}
{{LabLearningObjectivesSkills
|LabSkill=Create plots
}}
{{Headerplaceholder}}
{{LabTopicalLearningObjectives
|LabTopicalLearningObjective=Landscape evolution
}}
{{LabTopicalLearningObjectives
|LabTopicalLearningObjective=Stream Power equation
}}
{{LabTopicalLearningObjectives
|LabTopicalLearningObjective=Wildfires
}}
{{LabTopicalLearningObjectives
|LabTopicalLearningObjective=Sediment flux
}}
{{LabNotes
|LabNotesInstructions=You can run the Jupyter Notebook by clicking "start" under "Run online" at the top of this page. Alternatively, the lab can be downloaded using the "download" link at the top of the page.
|LabAcknowledgements=This lab was created during CSDMS's ESPIn 2021 summer workshop. Thank you to everyone involved in organizing and teaching ESPIn.
}}
{{LabReferences
|LabReferences=Braun, J., Willett, S. (2013). A very efficient O(n), implicit and parallel method to solve the stream power equation governing fluvial incision and landscape evolution. Geomorphology 180-181(C), 170-179. https://dx.doi.org/10.1016/j.geomorph.2012.10.008
}}
{{LabReferences
|LabReferences=Shobe, C. M., Tucker, G. E., and Barnhart, K. R.: The SPACE 1.0 model: a Landlab component for 2-D calculation of sediment transport, bedrock erosion, and landscape evolution, Geosci. Model Dev., 10, 4577–4604, https://doi.org/10.5194/gmd-10-4577-2017, 2017.
}}

Lab-0024

2021-10-27T18:32:34Z

Lroberge:

{{Labbasics
|Labtitle=Including wildfires in a landscape evolution model
|LabCOModule=1 of 1
|LabDateContributedOrUpdated=2021-10-27
|LabDescriptionShort=Explore the effect of stochastic wildfires on riverine sediment flux. We use the SPACE model to simulate fluvial processes and introduce a stochastic wildfire model. Students can experiment by changing the rate of fires and other parameters.
|LabCODuration=1.0 hrs
|LabModelDocumentation=SPACE
|LabAssociatedLesson=Jupyter Notebook
}}
{{LabContributorData
|LabContributorName=Kevin Pierce
|LabContributorInstitute=University of British Columbia
}}
{{LabContributorData
|LabContributorName=Laurent Roberge
|LabContributorInstitute=Tulane University
}}
{{LabContributorData
|LabContributorName=Nishani Moragoda
|LabContributorInstitute=University of Alabama
}}
{{LabIntro
|LabDescription=This lab is appropriate for advanced undergraduates and graduate students majoring in earth science/engineering.

We will use Landlab to generate a grid, use two different landscape evolution models (LEMs) to evolve a synthetic landscape, apply stochastic wildfires that increase erodibility, and plot various maps and graphs. Though no real-world data are used, the landscape relief is statistically realistic and roughly approximate to the Wasatch mountains in Utah.

This Jupyter Notebook is best for people who already have a conceptual understanding of earth surface processes and want to learn how these apply to numerical modeling, landscape evolution, and sediment flux. Although no Python skills are required to run the notebook, those with an intermediate understanding of Python will be able to learn more by reading the code.
|LabPicture=BurnedAreaM.jpg
}}
{{LabClassroomOrganization
|LabCOIntro=This lab can be run on the CSDMS JupyterHub. (Follow the instructions here to create an account if you don't already have one: https://csdms.colorado.edu/wiki/JupyterHub.) Run the Jupyter Notebook by clicking the "start" link under the Run online heading at the top of this page.

If you have questions, please contact us through the CSDMS Help Desk: https://github.com/csdms/help-desk.
}}
{{LabLearningObjectivesSkills
|LabSkill=Use Landlab to generate a grid
}}
{{LabLearningObjectivesSkills
|LabSkill=Use Fastscape and SPACE for landscape evolution
}}
{{LabLearningObjectivesSkills
|LabSkill=Create plots
}}
{{Headerplaceholder}}
{{LabTopicalLearningObjectives
|LabTopicalLearningObjective=Landscape evolution
}}
{{LabTopicalLearningObjectives
|LabTopicalLearningObjective=Stream Power equation
}}
{{LabTopicalLearningObjectives
|LabTopicalLearningObjective=Wildfires
}}
{{LabTopicalLearningObjectives
|LabTopicalLearningObjective=Sediment flux
}}
{{LabNotes
|LabNotesInstructions=You can run the Jupyter Notebook by clicking "start" under "Run online" at the top of this page. Alternatively, the lab can be downloaded using the "download" link at the top of the page.
|LabAcknowledgements=This lab was created during CSDMS's ESPIn 2021 summer workshop. Thank you to everyone involved in organizing and teaching ESPIn.
}}
{{LabReferences
|LabReferences=Braun, J., Willett, S. (2013). A very efficient O(n), implicit and parallel method to solve the stream power equation governing fluvial incision and landscape evolution. Geomorphology 180-181(C), 170-179. https://dx.doi.org/10.1016/j.geomorph.2012.10.008
}}
{{LabReferences
|LabReferences=Shobe, C. M., Tucker, G. E., and Barnhart, K. R.: The SPACE 1.0 model: a Landlab component for 2-D calculation of sediment transport, bedrock erosion, and landscape evolution, Geosci. Model Dev., 10, 4577–4604, https://doi.org/10.5194/gmd-10-4577-2017, 2017.
}}

Lab-0024

2021-10-27T18:32:17Z

Lroberge:

{{Labbasics
|Labtitle=Including wildfires in a landscape evolution model
|LabCOModule=1 of 1
|LabDateContributedOrUpdated=2021-10-27
|LabDescriptionShort=Explore the effect of stochastic wildfires on riverine sediment flux. We use the SPACE model to simulate fluvial processes and introduce a stochastic wildfire model. Students can experiment by changing the rate of fires and other parameters.
|LabCODuration=1.0 hrs
|LabModelDocumentation=SPACE
|LabAssociatedLesson=Jupyter Notebook
}}
{{LabContributorData
|LabContributorName=Kevin Pierce
|LabContributorInstitute=University of British Columbia
}}
{{LabContributorData
|LabContributorName=Laurent Roberge
|LabContributorInstitute=Tulane University
}}
{{LabContributorData
|LabContributorName=Nishani Moragoda
|LabContributorInstitute=University of Alabama
}}
{{LabIntro
|LabDescription=This lab is appropriate for advanced undergraduates and graduate students majoring in earth science/engineering.

We will use Landlab to generate a grid, use two different landscape evolution models (LEMs) to evolve a synthetic landscape, apply stochastic wildfires that increase erodibility, and plot various maps and graphs. Though no real-world data are used, the landscape relief is statistically realistic and roughly approximate to the Wasatch mountains in Utah.

This Jupyter Notebook is best for people who already have a conceptual understanding of earth surface processes and want to learn how these apply to numerical modeling, landscape evolution, and sediment flux. Although no Python skills are required to run the notebook, those with an intermediate understanding of Python will be able to learn more by reading the code.
|LabPicture=BurnedAreaM.jpg
}}
{{LabClassroomOrganization
|LabCOIntro=This lab can be run on the CSDMS JupyterHub. (Follow the instructions here to create an account if you don't already have one: https://csdms.colorado.edu/wiki/JupyterHub.) Run the Jupyter Notebook by clicking the "start" link under the Run online heading at the top of this page.

If you have questions, please contact us through the CSDMS Help Desk: https://github.com/csdms/help-desk.
}}
{{LabLearningObjectivesSkills
|LabSkill=Use Landlab to generate a grid
}}
{{LabLearningObjectivesSkills
|LabSkill=Use Fastscape and SPACE for landscape evolution
}}
{{LabLearningObjectivesSkills
|LabSkill=Create plots
}}
{{Headerplaceholder}}
{{LabTopicalLearningObjectives
|LabTopicalLearningObjective=Landscape evolution
}}
{{LabTopicalLearningObjectives
|LabTopicalLearningObjective=Stream Power equation
}}
{{LabTopicalLearningObjectives
|LabTopicalLearningObjective=Wildfires
}}
{{LabTopicalLearningObjectives
|LabTopicalLearningObjective=Sediment flux
}}
{{LabNotes
|LabNotesInstructions=You can run the Jupyter Notebook by clicking "start" under "Run online" at the top of this page. Alternatively, the lab can be downloaded using the "download" link at the top of the page.
|LabAcknowledgements=This lab was created during CSDMS's ESPIn 2021 summer workshop. Thank you to everyone involved in organizing and teaching ESPIn.
}}
{{LabReferences
|LabReferences=Braun, J., Willett, S. (2013). A very efficient O(n), implicit and parallel method to solve the stream power equation governing fluvial incision and landscape evolution. Geomorphology 180-181(C), 170-179. https://dx.doi.org/10.1016/j.geomorph.2012.10.008
}}
{{LabReferences
|LabReferences=Shobe, C. M., Tucker, G. E., and Barnhart, K. R.: The SPACE 1.0 model: a Landlab component for 2-D calculation of sediment transport, bedrock erosion, and landscape evolution, Geosci. Model Dev., 10, 4577–4604, https://doi.org/10.5194/gmd-10-4577-2017, 2017.
}}

Lab-0024

2021-10-27T18:31:44Z

Lroberge:

{{Labbasics
|Labtitle=Including wildfires in a landscape evolution model
|LabCOModule=1 of 1
|LabDateContributedOrUpdated=2021-10-27
|LabDescriptionShort=Explore the effect of stochastic wildfires on riverine sediment flux. We use the SPACE model to simulate fluvial processes and introduce a stochastic wildfire model. Students can experiment by changing the rate of fires and other parameters.
|LabCODuration=1.0 hrs
|LabModelDocumentation=SPACE
|LabAssociatedLesson=Jupyter Notebook
}}
{{LabContributorData
|LabContributorName=Kevin Pierce
|LabContributorInstitute=University of British Columbia
}}
{{LabContributorData
|LabContributorName=Laurent Roberge
|LabContributorInstitute=Tulane University
}}
{{LabContributorData
|LabContributorName=Nishani Moragoda
|LabContributorInstitute=University of Alabama
}}
{{LabIntro
|LabDescription=This lab is appropriate for advanced undergraduates and graduate students majoring in earth science/engineering.

We will use Landlab to generate a grid, use two different landscape evolution models (LEMs) to evolve a synthetic landscape, apply stochastic wildfires that increase erodibility, and plot various maps and graphs. Though no real-world data are used, the landscape relief is statistically realistic and roughly approximate to the Wasatch mountains in Utah.

This Jupyter Notebook is best for people who already have a conceptual understanding of earth surface processes and want to learn how these apply to numerical modeling, landscape evolution, and sediment flux. Although no Python skills are required to run the notebook, those with an intermediate understanding of Python will be able to learn more by reading the code.
|LabPicture=BurnedAreaM.jpg
}}
{{LabClassroomOrganization
|LabCOIntro=This lab can be run on the CSDMS JupyterHub. (Follow the instructions here to create an account if you don't already have one: https://csdms.colorado.edu/wiki/JupyterHub.)

Run the Jupyter Notebook by clicking the "start" link under the Run online heading at the top of this page.

If you have questions, please contact us through the CSDMS Help Desk: https://github.com/csdms/help-desk.
}}
{{LabLearningObjectivesSkills
|LabSkill=Use Landlab to generate a grid
}}
{{LabLearningObjectivesSkills
|LabSkill=Use Fastscape and SPACE for landscape evolution
}}
{{LabLearningObjectivesSkills
|LabSkill=Create plots
}}
{{Headerplaceholder}}
{{LabTopicalLearningObjectives
|LabTopicalLearningObjective=Landscape evolution
}}
{{LabTopicalLearningObjectives
|LabTopicalLearningObjective=Stream Power equation
}}
{{LabTopicalLearningObjectives
|LabTopicalLearningObjective=Wildfires
}}
{{LabTopicalLearningObjectives
|LabTopicalLearningObjective=Sediment flux
}}
{{LabNotes
|LabNotesInstructions=You can run the Jupyter Notebook by clicking "start" under "Run online" at the top of this page. Alternatively, the lab can be downloaded using the "download" link at the top of the page.
|LabAcknowledgements=This lab was created during CSDMS's ESPIn 2021 summer workshop. Thank you to everyone involved in organizing and teaching ESPIn.
}}
{{LabReferences
|LabReferences=Braun, J., Willett, S. (2013). A very efficient O(n), implicit and parallel method to solve the stream power equation governing fluvial incision and landscape evolution. Geomorphology 180-181(C), 170-179. https://dx.doi.org/10.1016/j.geomorph.2012.10.008
}}
{{LabReferences
|LabReferences=Shobe, C. M., Tucker, G. E., and Barnhart, K. R.: The SPACE 1.0 model: a Landlab component for 2-D calculation of sediment transport, bedrock erosion, and landscape evolution, Geosci. Model Dev., 10, 4577–4604, https://doi.org/10.5194/gmd-10-4577-2017, 2017.
}}

Lab-0024

2021-10-27T18:31:09Z

Lroberge:

{{Labbasics
|Labtitle=Including wildfires in a landscape evolution model
|LabCOModule=1 of 1
|LabDateContributedOrUpdated=2021-10-27
|LabDescriptionShort=Explore the effect of stochastic wildfires on riverine sediment flux. We use the SPACE model to simulate fluvial processes and introduce a stochastic wildfire model. Students can experiment by changing the rate of fires and other parameters.
|LabCODuration=1.0 hrs
|LabModelDocumentation=SPACE
|LabAssociatedLesson=Jupyter Notebook
}}
{{LabContributorData
|LabContributorName=Kevin Pierce
|LabContributorInstitute=University of British Columbia
}}
{{LabContributorData
|LabContributorName=Laurent Roberge
|LabContributorInstitute=Tulane University
}}
{{LabContributorData
|LabContributorName=Nishani Moragoda
|LabContributorInstitute=University of Alabama
}}
{{LabIntro
|LabDescription=This lab is appropriate for advanced undergraduates and graduate students majoring in earth science/engineering.

We will use Landlab to generate a grid, use two different landscape evolution models (LEMs) to evolve a synthetic landscape, apply stochastic wildfires that increase erodibility, and plot various maps and graphs. Though no real-world data are used, the landscape relief is statistically realistic and roughly approximate to the Wasatch mountains in Utah.

This Jupyter Notebook is best for people who already have a conceptual understanding of earth surface processes and want to learn how these apply to numerical modeling, landscape evolution, and sediment flux. Although no Python skills are required to run the notebook, those with an intermediate understanding of Python will be able to learn more by reading the code.
|LabPicture=BurnedAreaM.jpg
}}
{{LabClassroomOrganization
|LabCOIntro=This lab can be run on the CSDMS JupyterHub. (Follow the instructions here to create an account if you don't already have one: https://csdms.colorado.edu/wiki/JupyterHub.)

Run the Jupyter Notebook by clicking the "start" link under the Run online heading at the top of this page.

If you have questions, please contact us through the CSDMS Help Desk: https://github.com/csdms/help-desk.
}}
{{LabLearningObjectivesSkills
|LabSkill=Use Landlab to generate a grid
}}
{{LabLearningObjectivesSkills
|LabSkill=Use Fastscape and SPACE for landscape evolution
}}
{{LabLearningObjectivesSkills
|LabSkill=Create plots
}}
{{Headerplaceholder}}
{{LabTopicalLearningObjectives
|LabTopicalLearningObjective=Landscape evolution
}}
{{LabTopicalLearningObjectives
|LabTopicalLearningObjective=Stream Power equation
}}
{{LabTopicalLearningObjectives
|LabTopicalLearningObjective=Wildfires
}}
{{LabTopicalLearningObjectives
|LabTopicalLearningObjective=Sediment flux
}}
{{LabNotes
|LabNotesInstructions=You can run the Jupyter Notebook by clicking "start" under "Run online" at the top of this page. Alternatively, the lab can be downloaded using the "download" link at the top of the page.
|LabAcknowledgements=This lab was created during CSDMS's ESPIn 2021 summer workshop. Thank you to everyone involved in organizing and teaching ESPIn.
}}
{{LabReferences
|LabReferences=Braun, J., Willett, S. (2013). A very efficient O(n), implicit and parallel method to solve the stream power equation governing fluvial incision and landscape evolution. Geomorphology 180-181(C), 170-179. https://dx.doi.org/10.1016/j.geomorph.2012.10.008
}}
{{LabReferences
|LabReferences=Shobe, C. M., Tucker, G. E., and Barnhart, K. R.: The SPACE 1.0 model: a Landlab component for 2-D calculation of sediment transport, bedrock erosion, and landscape evolution, Geosci. Model Dev., 10, 4577–4604, https://doi.org/10.5194/gmd-10-4577-2017, 2017.
}}

Lab-0024

2021-10-27T18:19:15Z

Lroberge:

{{Labbasics
|Labtitle=Including wildfires in a landscape evolution model
|LabCOModule=1 of 1
|LabDateContributedOrUpdated=2021-10-27
|LabDescriptionShort=Explore the effect of stochastic wildfires on riverine sediment flux. We use the SPACE model to simulate fluvial processes and introduce a stochastic wildfire model. Students can experiment by changing the rate of fires and other parameters.
|LabCODuration=1.0 hrs
|LabModelDocumentation=SPACE
|LabAssociatedLesson=Jupyter Notebook
}}
{{LabContributorData
|LabContributorName=Kevin Pierce
|LabContributorInstitute=University of British Columbia
}}
{{LabContributorData
|LabContributorName=Laurent Roberge
|LabContributorInstitute=Tulane University
}}
{{LabContributorData
|LabContributorName=Nishani Moragoda
|LabContributorInstitute=University of Alabama
}}
{{LabIntro
|LabDescription=This lab is appropriate for advanced undergraduates and graduate students majoring in earth science/engineering.

We will use Landlab to generate a grid, use two different landscape evolution models (LEMs) to evolve a synthetic landscape, apply stochastic wildfires that increase erodibility, and plot various maps and graphs. Though no real-world data are used, the landscape relief is statistically realistic and roughly approximate to the Wasatch mountains in Utah.

This Jupyter Notebook is best for people who already have a conceptual understanding of earth surface processes and want to learn how these apply to numerical modeling, landscape evolution, and sediment flux. Although no Python skills are required to run the notebook, those with an intermediate understanding of Python will be able to learn more by reading the code.
|LabPicture=BurnedAreaM.jpg
}}
{{LabClassroomOrganization
|LabCOIntro=PARAPHRASED FROM IRINA's NOTEBOOK:

This lab can be run on the CSDMS JupyterHub. (Follow the instructions here to create an account if you don't already have one: https://csdms.colorado.edu/wiki/JupyterHub.)

Run the Jupyter Notebook by clicking the "start" link under the Run online heading at the top of this page.

If you have questions, please contact us through the CSDMS Help Desk: https://github.com/csdms/help-desk.
}}
{{LabLearningObjectivesSkills
|LabSkill=Use Landlab to generate a grid
}}
{{LabLearningObjectivesSkills
|LabSkill=Use Fastscape and SPACE for landscape evolution
}}
{{LabLearningObjectivesSkills
|LabSkill=Create plots
}}
{{Headerplaceholder}}
{{LabTopicalLearningObjectives
|LabTopicalLearningObjective=Landscape evolution
}}
{{LabTopicalLearningObjectives
|LabTopicalLearningObjective=Stream Power equation
}}
{{LabTopicalLearningObjectives
|LabTopicalLearningObjective=Wildfires
}}
{{LabTopicalLearningObjectives
|LabTopicalLearningObjective=Sediment flux
}}
{{LabNotes
|LabNotesInstructions=Run the Jupyter Notebook by clicking the "start" link under the Run online heading at the top of this page.
|LabAcknowledgements=This lab was created during CSDMS's ESPIn 2021 summer workshop. Thank you to everyone involved in organizing and teaching ESPIn.
}}

File:BurnedAreaM.jpg

2021-10-27T18:18:02Z

Lroberge: Example of a burned area in a catchment.

== Summary ==
Example of a burned area in a catchment.

Lab-0024

2021-10-27T18:08:36Z

Lroberge: Created page with "{{Labbasics |Labtitle=Including wildfires in a landscape evolution model |LabCOModule=1 of 1 |LabDateContributedOrUpdated=2021-10-27 |LabDescriptionShort=Explore the effect of..."

{{Labbasics
|Labtitle=Including wildfires in a landscape evolution model
|LabCOModule=1 of 1
|LabDateContributedOrUpdated=2021-10-27
|LabDescriptionShort=Explore the effect of stochastic wildfires on riverine sediment flux. We use the SPACE model to simulate fluvial processes and introduce a stochastic wildfire model. Students can experiment by changing the rate of fires and other parameters.
|LabCODuration=1.0 hrs
|LabModelDocumentation=SPACE
|LabAssociatedLesson=Jupyter Notebook
}}
{{LabContributorData
|LabContributorName=Kevin Pierce
|LabContributorInstitute=University of British Columbia
}}
{{LabContributorData
|LabContributorName=Laurent Roberge
|LabContributorInstitute=Tulane University
}}
{{LabContributorData
|LabContributorName=Nishani Moragoda
|LabContributorInstitute=University of Alabama
}}
{{LabIntro
|LabDescription=This lab is appropriate for advanced undergraduates and graduate students majoring in earth science/engineering.

We will use Landlab to generate a grid, use two different landscape evolution models (LEMs) to evolve a synthetic landscape, apply stochastic wildfires that increase erodibility, and plot various maps and graphs. Though no real-world data are used, the landscape relief is statistically realistic and roughly approximate to the Wasatch mountains in Utah.

This Jupyter Notebook is best for people who already have a conceptual understanding of earth surface processes and want to learn how these apply to numerical modeling, landscape evolution, and sediment flux. Although no Python skills are required to run the notebook, those with an intermediate understanding of Python will be able to learn more by reading the code.
|LabPicture=image.jpg
}}
{{LabClassroomOrganization
|LabCOIntro=PARAPHRASED FROM IRINA's NOTEBOOK:

This lab can be run on the CSDMS JupyterHub. (Follow the instructions here to create an account if you don't already have one: https://csdms.colorado.edu/wiki/JupyterHub.)

Run the Jupyter Notebook by clicking the "start" link under the Run online heading at the top of this page.

If you have questions, please contact us through the CSDMS Help Desk: https://github.com/csdms/help-desk.
}}
{{LabLearningObjectivesSkills
|LabSkill=Use Landlab to generate a grid
}}
{{LabLearningObjectivesSkills
|LabSkill=Use Fastscape and SPACE for landscape evolution
}}
{{LabLearningObjectivesSkills
|LabSkill=Create plots
}}
{{Headerplaceholder}}
{{LabTopicalLearningObjectives
|LabTopicalLearningObjective=Landscape evolution
}}
{{LabTopicalLearningObjectives
|LabTopicalLearningObjective=Stream Power equation
}}
{{LabTopicalLearningObjectives
|LabTopicalLearningObjective=Wildfires
}}
{{LabTopicalLearningObjectives
|LabTopicalLearningObjective=Sediment flux
}}
{{LabNotes
|LabNotesInstructions=Run the Jupyter Notebook by clicking the "start" link under the Run online heading at the top of this page.
|LabAcknowledgements=This lab was created during CSDMS's ESPIn 2021 summer workshop. Thank you to everyone involved in organizing and teaching ESPIn.
}}

User:Lroberge

2021-03-26T20:24:08Z

Lroberge: Created page with "{{Signup information member |First name member=Laurent |Last name member=Roberge |Institute member=Tulane University |City member=New Orleans |Country member=United States |St..."

{{Signup information member
|First name member=Laurent
|Last name member=Roberge
|Institute member=Tulane University
|City member=New Orleans
|Country member=United States
|State member=Louisiana
|Confirm email member=lroberge@tulane.edu
|Working group member=Terrestrial Working Group, Hydrology Focus Research Group
|Emaillist group member=yes
|Description of your CSDMS-related interests member=Landscape evolution
|Memberagreement=I have read and agree to the Privacy Policy
}}

2021 CSDMS meeting-088

2021-03-26T20:21:05Z

Lroberge: Created page with "{{CSDMS meeting personal information template-2021 |CSDMS meeting first name=Laurent |CSDMS meeting last name=Roberge |CSDMS meeting institute=Tulane University |CSDMS meeting..."

{{CSDMS meeting personal information template-2021
|CSDMS meeting first name=Laurent
|CSDMS meeting last name=Roberge
|CSDMS meeting institute=Tulane University
|CSDMS meeting city=New Orleans
|CSDMS meeting country=United States
|CSDMS meeting state=Louisiana
|CSDMS meeting email address=lroberge@tulane.edu
|CSDMS meeting phone=5043356992
}}
{{CSDMS meeting select clinics1 2021
|CSDMS_meeting_select_clinics1_2021=2) Do the work: Building a more equitable research unit
}}
{{CSDMS meeting select clinics2 2021
|CSDMS_meeting_select_clinics2_2021=4) CSDMS at Hydroshare
}}
{{CSDMS meeting select clinics3 2021
|CSDMS_meeting_select_clinics3_2021=1) Landscape Evolution Modeling with TerrainBento and Landlab
}}
{{CSDMS meeting abstract yes no 2021
|CSDMS meeting abstract submit=No
}}
{{CSDMS meeting abstract title temp2021}}
{{CSDMS meeting abstract template 2021}}
{{blank line template}}