Unifying framework for quantifying regime shifts in complex ecosystems
- Yanbin Hao,
- Tong Zhao,
- Xin Wang,
- Kai Xue,
- Jianqing Du,
- Xiaoyong Cui,
- Yanfen Wang
Jianqing Du
University of the Chinese Academy of Sciences
Author ProfileXiaoyong Cui
University of the Chinese Academy of Sciences
Author ProfileAbstract
Complex ecosystems exhibit more nonlinearity and stochasticity than the
simple ones, rendering timely and accurate detection regime shifts in
complex dynamic ecosystems a challenge. To resolve this dilemma, one of
the most critical steps is to determine and quantify the equilibrium
states reached by complex ecosystems under a given disturbance. This
study utilizes the energy-transfer-network equilibrium model based on
Nash-equilibrium theory and the maximum power principle to quantify and
predict the equilibrium state of a complex ecosystem with multiple
trophic levels. The model successfully simulated ecosystem energy
transfer under equilibrium and quantified ecosystem state. The
application of the model to monitor the aboveground biomass of a
long-term dataset of un-grazed steppe achieved the description and
prediction of the regime shift. This approach can possibly be used not
only to find the equilibrium state for complex and simple ecosystems but
also to remove the limitations of current methods to determine the
attraction domain or stable points through statistical or difference
equations in regime shift studies.