Fwd: QLS Guest seminar - Friday, 16 February
Sarnataro Erica
esarnata at ictp.it
Wed Feb 14 11:45:02 CET 2018
QUANTITATIVE LIFE SCIENCES GUEST SEMINAR
Friday, 16 February 2018 at 11:00,
ICTP, Central Area, 2nd floor, old SISSA building
Speaker: Silvia Zaoli - École polytechnique fédérale de Lausanne (EPFL)
Title: A Finite-size Scaling Framework Uncovers the Covariations of
Ecological Scaling Laws
Abstract:
Scaling laws in ecology are recurrent and pervasive patterns observed in
ecosystems, intended both as functional relationships among
ecologically-relevant quantities and the probability distributions that
characterize their occurrence. Well-known examples include the
Species-Area relationship (SAR), quantifying the increase of
biodiversity with ecosystem area, and Kleiber’s law, the allometric
relation between organismic size and metabolic rate. The interest in
these laws lies in their intrinsic predictive power: how many species
would go extinct if the ecosystem shrinks to half its size? What is the
mass of the largest organisms inhabiting ecosystems of different extent?
Are there more large-sized or small-sized organisms and species? Scaling
laws observed empirically often conform to power-laws, /A=B^a /, where
/a/ is the scaling exponent. Although their functional form appears to
be ubiquitous, empirical scaling exponents may vary with ecosystem type
and resource supply rate.
While ecological laws have been often studied independently, simple
heuristic reasonings show that they are linked. Such reasonings,
however, do not allow accounting for finite-size effects, restricting
the range for power-law behavior in finite ecosystem due to ecological
or biological constraints on organismic size, or for other deviations
from pure power-laws. These limits demand for a different approach. The
ubiquity of power-laws and the presence of finite-size constraints
suggest finite-size scaling theory as a useful tool in this context. A
scaling hypothesis for the joint probability distribution of abundance
and body mass of species inhabiting an ecosystem of finite size is
proposed and used to derive macroecological patterns. The hypothesis is
supported by a broad class of resource-limited community dynamics
stochastic models. Precise linkages among ecological laws were derived
from the proposed scaling hypothesis, in the form of algebraic
relationships among scaling exponents. Such relationships rationalize
the observed variability of ecological exponents across ecosystems,
clarifying how changes in one ecological pattern affect the remaining
ones. Predicted covariations were verified on empirical data. This
model-free approach allows investigating the effects of different
ecological or biological assumptions on the covariation of scaling
exponents.
Indico web page: http://indico.ictp.it/event/8521/
Everyone interested is most welcome to attend!
--
Erica Sarnataro
Group Secretary
Quantitative Life Sciences
The Abdus Salam International Centre for Theoretical Physics (ICTP)
Trieste, Italy
Tel. +39-040-2240623
www.ictp.it/research/qls.aspx
e-mail:qls at ictp.it
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