Anticipating land surface change

The interplay of human actions and natural processes over varied spatial and temporal scales can result in abrupt transitions between contrasting land surface states. Understanding these transitions is a key goal of sustainability science because they can represent abrupt losses of natural capital....

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Bibliographic Details
Published in:Proceedings of the National Academy of Sciences
Main Authors: Streeter, Richard Thomas, Dugmore, Andrew
Format: Article in Journal/Newspaper
Language:English
Published: 2013
Subjects:
BIFURCATIONS
geomorphology
ICELAND
Resilience
TEPHROCHRONOLOGY
Iceland
Online Access:https://research-portal.st-andrews.ac.uk/en/researchoutput/anticipating-land-surface-change(3b76fbea-7f81-4609-9389-d77ad5c5a383).html
https://doi.org/10.1073/pnas.1220161110
Description
Summary:The interplay of human actions and natural processes over varied spatial and temporal scales can result in abrupt transitions between contrasting land surface states. Understanding these transitions is a key goal of sustainability science because they can represent abrupt losses of natural capital. This paper recognizes flickering between alternate land surface states in advance of threshold change and critical slowing down in advance of both threshold changes and noncritical transformation. The early warning signals we observe are rises in autocorrelation, variance, and skewness within millimeter- resolution thickness measurements of tephra layers deposited in A.D. 2010 and A.D. 2011. These signals reflect changing patterns of surface vegetation, which are known to provide early warning signals of critical transformations. They were observed toward migrating soil erosion fronts, cryoturbation limits, and expanding deflation zones, thus providing potential early warning signals of land surface change. The record of the spatial patterning of vegetation contained in contemporary tephra layers shows how proximity to land surface change could be assessed in the widespread regions affected by shallow layers of volcanic fallout (those that can be subsumed within the existing vegetation cover). This insight shows how we could use tephra layers in the stratigraphic record to identify “near misses,” close encounters with thresholds that did not lead to tipping points, and thus provide additional tools for archaeology, sustainability science, and contemporary land management.

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