Investigating feedbacks in human-landscape systems: Lessons following a wildfire in Colorado, USA
Authored by Li An, Anne Chin, Joan L Florsheim, Laura R Laurencio, Richard A Marston, Anna P Solverson, Gregory L Simon, Emily Stinson, Ellen Wohl
Date Published: 2016
DOI: 10.1016/j.geomorph.2015.07.030
Sponsors:
United States National Science Foundation (NSF)
Platforms:
NetLogo
Model Documentation:
Other Narrative
Mathematical description
Model Code URLs:
Model code not found
Abstract
As human interactions with Earth systems continue to intensify, understanding the complex relationships among human activity, landscape
change, and societal responses to those changes becomes increasingly
important. Interdisciplinary research centered on the theme of
``feedbacks{''} in human-landscape systems serves as a promising focus
for unraveling these interactions. This paper examines the specific case
of the 2012 Waldo Canyon Fire of Colorado, where human responses after
the fire to perceived threats of hydro-geomorphological hazards included
construction of tall fences at the base of a burned watershed. These
actions prompted feedbacks that promoted further landscape change that
ultimately increased those hazards, rather than dampening the
hydro-geomorphological effects of fire. Geomorphic analysis showed that
the fences trapped particles that would naturally move through the
system by flows with recurrence intervals greater than 33 years. With
the particles blocked by the fences, the channel downstream became
erosive, because it was devoid of large particles that produce
substantial hydraulic resistance. Channel incision prompted a second
human response to pave the eroding channel, which led to further
incision downstream. This cycle of positive feedbacks between human
decision-making and landscape change eventually led to a complete
channelization of the stream channel downstream of the fences. The
explanation for the transformation of the post-fire landscape therefore
lies in the interacting human impacts and feedbacks, rather than the
expected post-fire hydro-geomorphological adjustments. An initial
agent-based model, capable of integrating social and
hydro-geomorphological data, simulates these interacting impacts and
feedbacks. Further refinement with more complete data input, especially
pertaining to human decision making at individual or local levels, is
required to fully demonstrate the utility and promise of this tool for
application to geomorphic analysis. (C) 2015 Elsevier B.V. All rights
reserved.
Tags
Evolution
resilience
runoff
Decisions
Challenges
Coupled human
Fire
Large woody debris
Mountain streams
Channels