r.sim.terrain 1.0: a landscape evolution model with dynamic hydrology

Harmon, Brendan Alexander; Mitasova, Helena; Petrasova, Anna; Petras, Vaclav

doi:https://doi.org/10.5194/gmd-12-2837-2019

Articles | Volume 12, issue 7

https://doi.org/10.5194/gmd-12-2837-2019

© Author(s) 2019. This work is distributed under
the Creative Commons Attribution 4.0 License.

https://doi.org/10.5194/gmd-12-2837-2019

© Author(s) 2019. This work is distributed under
the Creative Commons Attribution 4.0 License.

Articles | Volume 12, issue 7

Model description paper

|

11 Jul 2019

Model description paper |

| 11 Jul 2019

r.sim.terrain 1.0: a landscape evolution model with dynamic hydrology

Brendan Alexander Harmon, Helena Mitasova, Anna Petrasova, and Vaclav Petras

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Final revised paper (published on 11 Jul 2019)
Preprint (discussion started on 25 Feb 2019)

Interactive discussion

Status: closed

AC: Author comment | RC: Referee comment | SC: Short comment | EC: Editor comment

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- Supplement

SC1: 'Executive Editor comment on gmd-2019-18', Astrid Kerkweg, 14 Mar 2019
RC1: 'Referee comment for: r.sim.terrain: a dynamic landscape evolution model', Anonymous Referee #1, 20 Mar 2019
RC2: 'Referee comment', Anonymous Referee #2, 04 Apr 2019
- AC1: 'Model Diagram & re-running the model', Brendan Harmon, 18 Apr 2019
RC3: 'A valuable new contribution to erosion modeling software', Anonymous Referee #3, 08 Apr 2019
AC2: 'Final Author Response', Brendan Harmon, 15 May 2019

Peer-review completion

AR: Author's response | RR: Referee report | ED: Editor decision

AR by Brendan Harmon on behalf of the Authors (12 Jun 2019) Author's response Manuscript

ED: Publish subject to technical corrections (17 Jun 2019) by Bethanna Jackson

Short summary

The numerical model, r.sim.terrain, simulates how overland flows of water and sediment shape topography over short periods of time. We tested the model by comparing runs of the simulation against a time series of airborne lidar surveys for our study landscape. Through these tests, we demonstrated that the model can simulate gully evolution including processes such as channel incision, channel widening, and the development of scour pits, rills, and depositional ridges.