Impacts of self-organizing mechanism and topography on wetland ecosystem dynamics
Understanding the first order controls over resource cycling and limitation in ecosystems is critical for predicting ecosystem response to disturbances. Topography and vegetation self-organizing mechanisms are first order controls over resource fluxes across the landscape. Topography controls downsl...
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| Format: | Doctoral or Postdoctoral Thesis |
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Georgia Institute of Technology
2013
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| Online Access: | http://hdl.handle.net/1853/47705 |
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ftgeorgiatech:oai:repository.gatech.edu:1853/47705 |
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ftgeorgiatech:oai:repository.gatech.edu:1853/47705 2024-06-02T08:02:52+00:00 Impacts of self-organizing mechanism and topography on wetland ecosystem dynamics Cheng, Yiwei Stieglitz, Marc Aral, Mustafa Haas, Kevin Philip Roberts Turk, Greg Civil and Environmental Engineering 2013-05-09 application/pdf http://hdl.handle.net/1853/47705 unknown Georgia Institute of Technology http://hdl.handle.net/1853/47705 Topograhy Wetland ecosystem Water Self organization Ecosystem management Wetland ecology Ecological disturbances Restoration ecology Text Dissertation 2013 ftgeorgiatech 2024-05-06T11:59:02Z Understanding the first order controls over resource cycling and limitation in ecosystems is critical for predicting ecosystem response to disturbances. Topography and vegetation self-organizing mechanisms are first order controls over resource fluxes across the landscape. Topography controls downslope flow of resources (i.e water and nutrients). Through spatial feedbacks, vegetation is able to actively modify its environment and maximize resource flows towards it. To date, the impacts of these controls on ecosystem dynamics have mostly been investigated separately. As such, there is a knowledge gap in the understanding of how these first order controls together dictate the dynamics of the ecosystem. This dissertation aims to gain a better understanding of how self-organizing mechanisms and topography operate together to affect wetland ecosystem dynamics. A spatially explicit, wetland vegetation patterning model that includes for both vegetation self-organizing control and topographic control is developed (Nutrient Depletion Model, NDM). The model describes a scale dependent feedback between vegetation, transpiration and nutrient accumulation that drives the formation of vegetation patterns. The model is applied to investigate the effects of topography and self-organizing mechanisms on form and orientation of vegetation patterns and vegetation growth dynamics of wetland ecosystems. Results show that the two first order controls synergistically impact the formation of the various patterns as observed in wetland ecosystems. Results also show the following: (1) Self-organizing mechanisms result in a more efficient retention of resources, which result in higher biomass in the model that include for both self-organizing mechanism and topographic control (SO+TC) than in the model that that includes only for topographic control (TC). (2) However, when resources or topographic gradients increase or annual rainfall decrease, the vegetation growth dynamics of the TC+SO and TC models converge. The NDM is applied to arctic ... Doctoral or Postdoctoral Thesis Arctic Georgia Institute of Technology: SMARTech - Scholarly Materials and Research at Georgia Tech Arctic |
| institution |
Open Polar |
| collection |
Georgia Institute of Technology: SMARTech - Scholarly Materials and Research at Georgia Tech |
| op_collection_id |
ftgeorgiatech |
| language |
unknown |
| topic |
Topograhy Wetland ecosystem Water Self organization Ecosystem management Wetland ecology Ecological disturbances Restoration ecology |
| spellingShingle |
Topograhy Wetland ecosystem Water Self organization Ecosystem management Wetland ecology Ecological disturbances Restoration ecology Cheng, Yiwei Impacts of self-organizing mechanism and topography on wetland ecosystem dynamics |
| topic_facet |
Topograhy Wetland ecosystem Water Self organization Ecosystem management Wetland ecology Ecological disturbances Restoration ecology |
| description |
Understanding the first order controls over resource cycling and limitation in ecosystems is critical for predicting ecosystem response to disturbances. Topography and vegetation self-organizing mechanisms are first order controls over resource fluxes across the landscape. Topography controls downslope flow of resources (i.e water and nutrients). Through spatial feedbacks, vegetation is able to actively modify its environment and maximize resource flows towards it. To date, the impacts of these controls on ecosystem dynamics have mostly been investigated separately. As such, there is a knowledge gap in the understanding of how these first order controls together dictate the dynamics of the ecosystem. This dissertation aims to gain a better understanding of how self-organizing mechanisms and topography operate together to affect wetland ecosystem dynamics. A spatially explicit, wetland vegetation patterning model that includes for both vegetation self-organizing control and topographic control is developed (Nutrient Depletion Model, NDM). The model describes a scale dependent feedback between vegetation, transpiration and nutrient accumulation that drives the formation of vegetation patterns. The model is applied to investigate the effects of topography and self-organizing mechanisms on form and orientation of vegetation patterns and vegetation growth dynamics of wetland ecosystems. Results show that the two first order controls synergistically impact the formation of the various patterns as observed in wetland ecosystems. Results also show the following: (1) Self-organizing mechanisms result in a more efficient retention of resources, which result in higher biomass in the model that include for both self-organizing mechanism and topographic control (SO+TC) than in the model that that includes only for topographic control (TC). (2) However, when resources or topographic gradients increase or annual rainfall decrease, the vegetation growth dynamics of the TC+SO and TC models converge. The NDM is applied to arctic ... |
| author2 |
Stieglitz, Marc Aral, Mustafa Haas, Kevin Philip Roberts Turk, Greg Civil and Environmental Engineering |
| format |
Doctoral or Postdoctoral Thesis |
| author |
Cheng, Yiwei |
| author_facet |
Cheng, Yiwei |
| author_sort |
Cheng, Yiwei |
| title |
Impacts of self-organizing mechanism and topography on wetland ecosystem dynamics |
| title_short |
Impacts of self-organizing mechanism and topography on wetland ecosystem dynamics |
| title_full |
Impacts of self-organizing mechanism and topography on wetland ecosystem dynamics |
| title_fullStr |
Impacts of self-organizing mechanism and topography on wetland ecosystem dynamics |
| title_full_unstemmed |
Impacts of self-organizing mechanism and topography on wetland ecosystem dynamics |
| title_sort |
impacts of self-organizing mechanism and topography on wetland ecosystem dynamics |
| publisher |
Georgia Institute of Technology |
| publishDate |
2013 |
| url |
http://hdl.handle.net/1853/47705 |
| geographic |
Arctic |
| geographic_facet |
Arctic |
| genre |
Arctic |
| genre_facet |
Arctic |
| op_relation |
http://hdl.handle.net/1853/47705 |
| _version_ |
1800747342246182912 |