Beaver-driven peatland ecotone dynamics: Impoundment detection using Lidar and geomorphon analysis
Background/Question/Methods Beaver (Castor spp.) are renowned for their role as ecosystem engineers. Their ponds and vegetation consumption can greatly alter local hydrology and ratios of meadow to woodland. Beaver also actively buffer their environments against drought and wildfire susceptibility,...
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Ecological Society of America
2021
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| Online Access: | http://hdl.handle.net/10919/105158 |
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ftvirginiatec:oai:vtechworks.lib.vt.edu:10919/105158 |
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ftvirginiatec:oai:vtechworks.lib.vt.edu:10919/105158 2023-05-15T15:19:20+02:00 Beaver-driven peatland ecotone dynamics: Impoundment detection using Lidar and geomorphon analysis Swift, Troy P. Kennedy, Lisa M. West Virginia 2021-08-05 application/pdf http://hdl.handle.net/10919/105158 en eng Ecological Society of America https://cdmcd.co/w3Q4ad http://hdl.handle.net/10919/105158 Kennedy, Lisa [0000-0002-4076-1184] In Copyright http://rightsstatements.org/vocab/InC/1.0/ Conference proceeding 2021 ftvirginiatec 2022-03-24T18:34:56Z Background/Question/Methods Beaver (Castor spp.) are renowned for their role as ecosystem engineers. Their ponds and vegetation consumption can greatly alter local hydrology and ratios of meadow to woodland. Beaver also actively buffer their environments against drought and wildfire susceptibility, and can influence important climate parameters like carbon retention and methanogenesis. Beaver impoundments tend to follow a multiyear cycle of construction, maintenance, degradation, and fallow. Flooding is the primary agent of destruction. This investigation focused on remotely detecting beaver impacts on the boreal peatland ecotones enmeshing Cranberry Glades Botanical Area, a National Natural Landmark in mountainous West Virginia adjacent to Cranberry Wilderness, and contained entirely by Monongahela National Forest. The Glades are perched at ~1000 m elevation and occupy ~300 ha. Literature suggests that beaver activity may have had an important role in the formation and maintenance of peatland conditions at Cranberry Glades. Aerial Lidar/photography were analyzed in tandem in order to identify and reconstruct shifting hydrological patterns associated with beaver dams and ponds. We rasterized aerial Lidar data from Nov/Dec 2018 for the entire Glades at 1-meter resolution, including a bare-earth Digital Terrain Model (RMSE vertical accuracy ~10cm) and a canopy height model sufficient to discern between trees, shrubs, and near-surface. We developed a novel method of geomorphon analysis to detect ponds and dams by exploiting their occupancy of the incised stream channels typical of these wetlands. Aerial color-infrared and RGB photography, gathered during a variety of seasons, enabled complementary identification of beaver-related infrastructure by visual inspection. Results/Conclusions Geomorphon DTM analysis successfully revealed low ridges closely bracketing inter-glade stream channels featuring free-flowing water, manifesting as a ridge/valley/ridge cross-channel sequence. This signal is conspicuously absent along stretches flooded by beaver ponds; an abrupt transition between the two states also occurs at dams. A survey using these methods counted 13 ponds in Winter 2013-14 and 17 ponds in Summer 2016. This multi-year interval worked well, allowing time for widespread changes in beaver infrastructure while conserving utility of reference imagery. Future work will include analysis of the most recent beaver activity, refinement of classification workflows, generation of more accurate physical models using drone-acquired Lidar, and more complete incorporation of historical imagery. Much remains to be understood about the full role of beaver in this rare and imperiled Arctic island of the southern High Alleghenies. Yes, abstract only (Peer reviewed?) Conference Object Arctic VTechWorks (VirginiaTech) Arctic Arctic Island ENVELOPE(-74.766,-74.766,62.234,62.234) Beaver Ponds ENVELOPE(-57.841,-57.841,49.642,49.642) |
| institution |
Open Polar |
| collection |
VTechWorks (VirginiaTech) |
| op_collection_id |
ftvirginiatec |
| language |
English |
| description |
Background/Question/Methods Beaver (Castor spp.) are renowned for their role as ecosystem engineers. Their ponds and vegetation consumption can greatly alter local hydrology and ratios of meadow to woodland. Beaver also actively buffer their environments against drought and wildfire susceptibility, and can influence important climate parameters like carbon retention and methanogenesis. Beaver impoundments tend to follow a multiyear cycle of construction, maintenance, degradation, and fallow. Flooding is the primary agent of destruction. This investigation focused on remotely detecting beaver impacts on the boreal peatland ecotones enmeshing Cranberry Glades Botanical Area, a National Natural Landmark in mountainous West Virginia adjacent to Cranberry Wilderness, and contained entirely by Monongahela National Forest. The Glades are perched at ~1000 m elevation and occupy ~300 ha. Literature suggests that beaver activity may have had an important role in the formation and maintenance of peatland conditions at Cranberry Glades. Aerial Lidar/photography were analyzed in tandem in order to identify and reconstruct shifting hydrological patterns associated with beaver dams and ponds. We rasterized aerial Lidar data from Nov/Dec 2018 for the entire Glades at 1-meter resolution, including a bare-earth Digital Terrain Model (RMSE vertical accuracy ~10cm) and a canopy height model sufficient to discern between trees, shrubs, and near-surface. We developed a novel method of geomorphon analysis to detect ponds and dams by exploiting their occupancy of the incised stream channels typical of these wetlands. Aerial color-infrared and RGB photography, gathered during a variety of seasons, enabled complementary identification of beaver-related infrastructure by visual inspection. Results/Conclusions Geomorphon DTM analysis successfully revealed low ridges closely bracketing inter-glade stream channels featuring free-flowing water, manifesting as a ridge/valley/ridge cross-channel sequence. This signal is conspicuously absent along stretches flooded by beaver ponds; an abrupt transition between the two states also occurs at dams. A survey using these methods counted 13 ponds in Winter 2013-14 and 17 ponds in Summer 2016. This multi-year interval worked well, allowing time for widespread changes in beaver infrastructure while conserving utility of reference imagery. Future work will include analysis of the most recent beaver activity, refinement of classification workflows, generation of more accurate physical models using drone-acquired Lidar, and more complete incorporation of historical imagery. Much remains to be understood about the full role of beaver in this rare and imperiled Arctic island of the southern High Alleghenies. Yes, abstract only (Peer reviewed?) |
| format |
Conference Object |
| author |
Swift, Troy P. Kennedy, Lisa M. |
| spellingShingle |
Swift, Troy P. Kennedy, Lisa M. Beaver-driven peatland ecotone dynamics: Impoundment detection using Lidar and geomorphon analysis |
| author_facet |
Swift, Troy P. Kennedy, Lisa M. |
| author_sort |
Swift, Troy P. |
| title |
Beaver-driven peatland ecotone dynamics: Impoundment detection using Lidar and geomorphon analysis |
| title_short |
Beaver-driven peatland ecotone dynamics: Impoundment detection using Lidar and geomorphon analysis |
| title_full |
Beaver-driven peatland ecotone dynamics: Impoundment detection using Lidar and geomorphon analysis |
| title_fullStr |
Beaver-driven peatland ecotone dynamics: Impoundment detection using Lidar and geomorphon analysis |
| title_full_unstemmed |
Beaver-driven peatland ecotone dynamics: Impoundment detection using Lidar and geomorphon analysis |
| title_sort |
beaver-driven peatland ecotone dynamics: impoundment detection using lidar and geomorphon analysis |
| publisher |
Ecological Society of America |
| publishDate |
2021 |
| url |
http://hdl.handle.net/10919/105158 |
| op_coverage |
West Virginia |
| long_lat |
ENVELOPE(-74.766,-74.766,62.234,62.234) ENVELOPE(-57.841,-57.841,49.642,49.642) |
| geographic |
Arctic Arctic Island Beaver Ponds |
| geographic_facet |
Arctic Arctic Island Beaver Ponds |
| genre |
Arctic |
| genre_facet |
Arctic |
| op_relation |
https://cdmcd.co/w3Q4ad http://hdl.handle.net/10919/105158 Kennedy, Lisa [0000-0002-4076-1184] |
| op_rights |
In Copyright http://rightsstatements.org/vocab/InC/1.0/ |
| _version_ |
1766349509536776192 |