Organizing Principles for Vegetation Dynamics

Overview

Journal Nat Plants

Specialties Biology
Genetics

Date 2020 May 13

PMID 32393882

Citations 30

Authors

Oskar Franklin

Sandy P Harrison

Roderick Dewar

Caroline E Farrior

Ake Brannstrom

Ulf Dieckmann

Stephan Pietsch

Daniel Falster

Wolfgang Cramer

Michel Loreau

Han Wang

Annikki Makela

Karin T Rebel

Ehud Meron

Stanislaus J Schymanski

Elena Rovenskaya

Benjamin D Stocker

Sonke Zaehle

Stefano Manzoni

Marcel Van Oijen

Ian J Wright

Philippe Ciais

Peter M van Bodegom

Josep Penuelas

Florian Hofhansl

Cesar Terrer

Nadejda A Soudzilovskaia

Guy Midgley

I Colin Prentice

Affiliations

Soon will be listed here.

Abstract

Plants and vegetation play a critical-but largely unpredictable-role in global environmental changes due to the multitude of contributing processes at widely different spatial and temporal scales. In this Perspective, we explore approaches to master this complexity and improve our ability to predict vegetation dynamics by explicitly taking account of principles that constrain plant and ecosystem behaviour: natural selection, self-organization and entropy maximization. These ideas are increasingly being used in vegetation models, but we argue that their full potential has yet to be realized. We demonstrate the power of natural selection-based optimality principles to predict photosynthetic and carbon allocation responses to multiple environmental drivers, as well as how individual plasticity leads to the predictable self-organization of forest canopies. We show how models of natural selection acting on a few key traits can generate realistic plant communities and how entropy maximization can identify the most probable outcomes of community dynamics in space- and time-varying environments. Finally, we present a roadmap indicating how these principles could be combined in a new generation of models with stronger theoretical foundations and an improved capacity to predict complex vegetation responses to environmental change.

Citing Articles

The Response of Carbon Uptake to Soil Moisture Stress: Adaptation to Climatic Aridity.

Mengoli G, Harrison S, Prentice I Glob Chang Biol. 2025; 31(3):e70098.

PMID: 40062550 PMC: 11892089. DOI: 10.1111/gcb.70098.

Scaling of shoot and root respiration of woody and herbaceous plants.

Kurosawa Y, Mori S, Ferrio J, Nishizono T, Masyagina O, Yamaji K Proc Biol Sci. 2025; 292(2039):20241910.

PMID: 39876728 PMC: 11775627. DOI: 10.1098/rspb.2024.1910.

Generalized Stomatal Optimization of Evolutionary Fitness Proxies for Predicting Plant Gas Exchange Under Drought, Heatwaves, and Elevated CO.

Potkay A, Cabon A, Peters R, Fonti P, Sapes G, Sala A Glob Chang Biol. 2025; 31(1):e70049.

PMID: 39873117 PMC: 11774141. DOI: 10.1111/gcb.70049.

Why models underestimate West African tropical forest primary productivity.

Zhang-Zheng H, Deng X, Aguirre-Gutierrez J, Stocker B, Thomson E, Ding R Nat Commun. 2024; 15(1):9574.

PMID: 39505869 PMC: 11541734. DOI: 10.1038/s41467-024-53949-0.

Empirical evidence and theoretical understanding of ecosystem carbon and nitrogen cycle interactions.

Stocker B, Dong N, Perkowski E, Schneider P, Xu H, de Boer H New Phytol. 2024; 245(1):49-68.

PMID: 39444238 PMC: 11617667. DOI: 10.1111/nph.20178.

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