4.7 Review

Uniting the scales of microbial biogeochemistry with trait-based modelling

Journal

FUNCTIONAL ECOLOGY
Volume 36, Issue 6, Pages 1457-1472

Publisher

WILEY
DOI: 10.1111/1365-2435.14035

Keywords

carbon cycle; community ecology; earth system modelling; ecosystem ecology; mathematical modelling; soil microbes; traits

Categories

Ask authors/readers for more resources

Below-ground microbial communities play a significant role in earth's biogeochemical fluxes. This review discusses recent advances in trait-based soil carbon modeling and highlights the challenges and methods in integrating different scales of microbial biogeochemical modeling.
Below-ground microbial communities drive some of Earth's largest biogeochemical fluxes, yet they represent a major source of uncertainty in global biogeochemical models. This review synthesizes recent advances in trait-based soil carbon modelling in order to identify how empirical observations of microbial traits can inform the next generation of soil carbon models. We identify four key perspectives from which trait-based models have investigated the role of microbes in soil carbon fluxes, ranging from the largest to the smallest scales of biological organization: (i) Earth system models, which have recently begun to incorporate microbial traits at a global scale; (ii) ecosystem models, which relate microbial carbon cycling to other trophic levels and element cycles; (iii) models from community ecology, which link theories of species diversity to ecosystem cycles; and (iv) models of fine-scale physiology, which mechanistically represent traits at the individual level. Highlighting the contributions of diverse trait-based modelling approaches, we caution that this diversity makes it challenging to link perspectives at different scales. The meaning of a trait depends both on the structure of the model in which it occurs and on the scale treated by the model. Thus, reapplying a fine-scale trait at a broader scale may make incorrect predictions, an issue we illustrate quantitatively using model simulations. With these challenges in mind, we highlight several ways to synthesize the scales of microbial biogeochemical modelling: (i) quantitatively, using mathematical scaling techniques, (ii) empirically, by applying experiments to test relationships between scales and (iii) conceptually, by identifying key traits and processes across scales. Taking full advantage of trait-based modelling, ecologists will thus be able to incorporate multiple perspectives to better predict carbon cycling in a changing world.

Authors

I am an author on this paper
Click your name to claim this paper and add it to your profile.

Reviews

Primary Rating

4.7
Not enough ratings

Secondary Ratings

Novelty
-
Significance
-
Scientific rigor
-
Rate this paper

Recommended

No Data Available
No Data Available