Period doubling as an indicator for ecosystem sensitivity to climate extremes

Tzuk, Omer; Ujjwal, Sangeeta Rani; Fernandez-Oto, C.; Seifan, Merav; Meron, Ehud

doi:10.1038/s41598-019-56080-z

Cited by 14 publications

(10 citation statements)

References 52 publications

(51 reference statements)

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“…Examples of such applications include mechanical resonators (NEMS and MEMS) [34,35,36], catalytic surface reactions [26] and plasmonic architectures [13]. An example of a more diverse application is plant communities subjected to seasonal forcing, where plant species constitute damped oscillators distributed inhomogeneously in trait space [52,53,54]. The properties of the profile of localized oscillations studied here can be related to community-level properties such as community composition (profile location), functional diversity (profile width) and resilience to environmental changes (profile asymmetry).…”

Section: Resultsmentioning

confidence: 99%

Spatial asymmetries of resonant oscillations in periodically forced heterogeneous media

Edri

Meron

Yochelis

2020

Physica D: Nonlinear Phenomena

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Spatially localized oscillations in periodically forced systems are intriguing phenomena. They may occur in homogeneous media (oscillons), but quite often they emerge in heterogeneous media, such as the auditory system, where asymmetrical localized oscillations are believed to play an important role in frequency discrimination of incoming sound waves. In this paper, we use an amplitude-equation approach to study the asymmetry of the oscillations amplitude and the factors that affect it. More specifically, we use a variant of the forced complex Ginzburg-Landau (FCGL) equation that describes an oscillatory system below the Hopf bifurcation with space-dependent Hopf frequency, subjected to both parametric and additive forcing. We show that spatial heterogeneity combined with bistability of system states result in asymmetry of the localized oscillations. We further identify parameters that control that asymmetry, and characterize the spatial profile of the oscillations in terms of maximal amplitude, location, width and asymmetry. Our results bare qualitative similarities to empirical observation trends that have found in the auditory system.

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Section: Resultsmentioning

confidence: 99%

Spatial asymmetries of resonant oscillations in periodically forced heterogeneous media

Edri

Meron

Yochelis

2020

Physica D: Nonlinear Phenomena

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“…To what extent do these results remain valid under more general conditions of environmental stochasticity, such as due to fluctuating rainfall? To answer this question we studied the model equations using a precipitation rate that changes annually, with random values taken from a Gamma distribution [49] We compared three cases: no noise, weak noise and strong noise, realizations of which are shown in Fig 5a . For each case we considered initial conditions involving superpositions of two states as follows: increasing portions of a periodic-pattern component in a superposition with uniform vegetation ("pattern share") for the grazing management problem (vertical axis in Fig 5b ), and increasing portions of a rhombic-pattern component in a superposition with a stripe pattern ("rhombic share") for the rehabilitation problem (vertical axis in Fig 5c). The basic states in these mixed initial conditions, i.e.…”

Section: Robustness To Environmental Stochasticitymentioning

confidence: 99%

High-integrity human intervention in ecosystems: Tracking self-organization modes

et al. 2021

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Humans play major roles in shaping and transforming the ecology of Earth. Unlike natural drivers of ecosystem change, which are erratic and unpredictable, human intervention in ecosystems generally involves planning and management, but often results in detrimental outcomes. Using model studies and aerial-image analysis, we argue that the design of a successful human intervention form calls for the identification of the self-organization modes that drive ecosystem change, and for studying their dynamics. We demonstrate this approach with two examples: grazing management in drought-prone ecosystems, and rehabilitation of degraded vegetation by water harvesting. We show that grazing can increase the resilience to droughts, rather than imposing an additional stress, if managed in a spatially non-uniform manner, and that fragmental restoration along contour bunds is more resilient than the common practice of continuous restoration in vegetation stripes. We conclude by discussing the need for additional studies of self-organization modes and their dynamics.

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“…The power spectrum has shown potential as a tool for detecting bifurcations from time-series data [ 11 , 21 – 24 ] and has a rich history in time-series analysis more generally [ 25 , 26 ]. A seminal study in the physics literature derived analytical approximations for its behaviour prior to bifurcations of periodic orbits [ 21 ], showing how different patterns emerge depending on the type of bifurcation.…”

Section: Introductionmentioning

confidence: 99%

Detecting and distinguishing tipping points using spectral early warning signals

Bury

Bauch

Anand

2020

J. R. Soc. Interface.

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Theory and observation tell us that many complex systems exhibit tipping points—thresholds involving an abrupt and irreversible transition to a contrasting dynamical regime. Such events are commonly referred to as critical transitions. Current research seeks to develop early warning signals (EWS) of critical transitions that could help prevent undesirable events such as ecosystem collapse. However, conventional EWS do not indicate the type of transition, since they are based on the generic phenomena of critical slowing down. For instance, they may fail to distinguish the onset of oscillations (e.g. Hopf bifurcation) from a transition to a distant attractor (e.g. Fold bifurcation). Moreover, conventional EWS are less reliable in systems with density-dependent noise. Other EWS based on the power spectrum (spectral EWS) have been proposed, but they rely upon spectral reddening, which does not occur prior to critical transitions with an oscillatory component. Here, we use Ornstein–Uhlenbeck theory to derive analytic approximations for EWS prior to each type of local bifurcation, thereby creating new spectral EWS that provide greater sensitivity to transition proximity; higher robustness to density-dependent noise and bifurcation type; and clues to the type of approaching transition. We demonstrate the advantage of applying these spectral EWS in concert with conventional EWS using a population model, and show that they provide a characteristic signal prior to two different Hopf bifurcations in data from a predator–prey chemostat experiment. The ability to better infer and differentiate the nature of upcoming transitions in complex systems will help humanity manage critical transitions in the Anthropocene Era.

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Period doubling as an indicator for ecosystem sensitivity to climate extremes

Cited by 14 publications

References 52 publications

Spatial asymmetries of resonant oscillations in periodically forced heterogeneous media

Spatial asymmetries of resonant oscillations in periodically forced heterogeneous media

High-integrity human intervention in ecosystems: Tracking self-organization modes

Detecting and distinguishing tipping points using spectral early warning signals

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