Global Evaluation of the Ecosystem Demography Model (ED v3.0)

Ma, Lei; Hurtt, George C.; Ott, Lesley; Sahajpal, Ritvik; Fisk, J.; Lamb, Rachel L.; Tang, Hao; Flanagan, S.; Chini, L. P.; Chatterjee, Abhishek; Sullivan, Joseph

doi:10.5194/gmd-2021-292

Cited by 3 publications

(4 citation statements)

References 72 publications

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“…Code and data availability. All model simulation and source scripts can be found in https://doi.org/10.5281/zenodo.5236771 (Ma et al, 2021a). All benchmarking datasets are cited and publicly available.…”

Section: Discussionmentioning

confidence: 99%

Global evaluation of the Ecosystem Demography model (ED v3.0)

Hurtt

Ott

et al. 2022

Geosci. Model Dev.

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Abstract. Terrestrial ecosystems play a critical role in the global carbon cycle but have highly uncertain future dynamics. Ecosystem modeling that includes the scaling up of underlying mechanistic ecological processes has the potential to improve the accuracy of future projections while retaining key process-level detail. Over the past two decades, multiple modeling advances have been made to meet this challenge, such as the Ecosystem Demography (ED) model and its derivatives, including ED2 and FATES. Here, we present the global evaluation of the Ecosystem Demography model (ED v3.0), which, like its predecessors, features the formal scaling of physiological processes for individual-based vegetation dynamics to ecosystem scales, together with integrated submodules of soil biogeochemistry and soil hydrology, while retaining explicit tracking of vegetation 3-D structure. This new model version builds on previous versions and provides the first global calibration and evaluation, global tracking of the effects of climate and land-use change on vegetation 3-D structure, spin-up process and input datasets, as well as numerous other advances. Model evaluation was performed with respect to a set of important benchmarking datasets, and model estimates were within observational constraints for multiple key variables, including (i) global patterns of dominant plant functional types (broadleaf vs. evergreen), (ii) the spatial distribution, seasonal cycle, and interannual trends for global gross primary production (GPP), (iii) the global interannual variability of net biome production (NBP) and (iv) global patterns of vertical structure, including leaf area and canopy height. With this global model version, it is now possible to simulate vegetation dynamics from local to global scales and from seconds to centuries with a consistent mechanistic modeling framework amendable to data from multiple traditional and new remote sensing sources, including lidar.

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Section: Discussionmentioning

confidence: 99%

Global evaluation of the Ecosystem Demography model (ED v3.0)

Hurtt

Ott

et al. 2022

Geosci. Model Dev.

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“…The ideas above are meant to be applied to individual microbes and plants (which can be representative of a population), forming the foundation to model population and community dynamics (e.g., population demography, community and ecosystem assembly). These individual-based formulations, when combined in "ecosystem demography" models (Koven et al, 2020;Ma et al, 2022;Medvigy et al, 2019), will contribute to better modeling of biogeochemistry-climate feedbacks regulated by plant and microbial physiology (a knowledge gap in existing models).…”

Section: Feasibility Of Physical Rules-based Approachesmentioning

confidence: 99%

Feasibility of Formulating Ecosystem Biogeochemical Models From Established Physical Rules

Tang,

Riley,

Manzoni

et al. 2024

JGR Biogeosciences

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To improve the predictive capability of ecosystem biogeochemical models (EBMs), we discuss the feasibility of formulating biogeochemical processes using physical rules that have underpinned the many successes in computational physics and chemistry. We argue that the currently popular empirically based approaches, such as multiplicative empirical response functions and the law of the minimum, will not lead to EBM formulations that can be continuously refined to incorporate improved mechanistic understanding and empirical observations of biogeochemical processes. Instead, we propose that EBM parameterizations, as a lossy data compression problem, can be better formulated using established physical rules widely used in computational physics and chemistry, and different biogeochemical processes can be more robustly integrated within a reactive‐transport framework. Through several examples, we demonstrate how mathematical representations derived from physical rules can improve understanding of relevant biogeochemical processes and enable more effective communication between modelers, observationalists, and experimentalists regarding essential questions, such as what measurements are needed to meaningfully inform models and how can models generate new process‐level hypotheses to test in empirical studies. Finally, while empirical models with more parameters are often less robust, physical rules‐based models can be more robust and show lower predictive equifinality, stemming from their enhanced consistency in representations of processes, interactions and spatial scaling.

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“…XGBoost has been successfully applied in a variety of fields within Earth and Environmental Sciences, such as urban temperature emulation (Zheng et al, 2021b), wildfire burned area (Wang et al, 2021), and emissions prediction (Wang et al, 2022), flash flood risk assessment (Ma et al, 2021), and aerosol property estimation (Zheng et al, 2021a, c).…”

Section: Xgboost and Shapmentioning

confidence: 99%

“…However, explicit simulations of individual plants with stochastic processes suffer a substantial computational penalty and limit applicability over large or global scales (Fisher et al, 2018). To capture sufficient ecosystem dynamics and maintain relatively high computational efficiency, "cohort-based" models have been proposed (Haverd et al, 2013;Medvigy et al, 2009;Ma et al, 2021;Moorcroft et al, 2001;Longo et al, 2019). In a cohort-based approach, individual plants are grouped together as "cohorts" based on their similar properties, including size, age, and PFT (Fisher et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

A machine learning approach targeting parameter estimation for plant functional type coexistence modeling using ELM-FATES (v2.0)

Fang

Zheng

et al. 2023

Preprint

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Abstract. Tropical forest dynamics play crucial roles in the global carbon, water, and energy cycles. Dynamic global vegetation models are the primary tools to simulate terrestrial ecosystem dynamics and their response to climate change. However, realistically simulating the dynamics of competition and coexistence of differing plant functional traits within tropical forests remains a significant challenge. This study aims to improve modeling of plant functional type (PFT) coexistence in the Functionally Assembled Terrestrial Ecosystem Simulator (FATES), a vegetation demography model implemented in the Energy Exascale Earth System Model (E3SM) land model (ELM), ELM-FATES. Specifically, we explore: (1) whether plant trait relationships established from field measurements can constrain ELM-FATES simulations; and (2) whether machine learning based surrogate models can emulate the complex ELM-FATES model and optimize parameter selections to improve PFT coexistence modeling. We conducted ELM-FATES experiments for a tropical forest site near Manaus, Brazil. We first conducted two ensembles of ELM-FATES experiments, without (Exp-1) and with (Exp-2) consideration of observed trait relationships, respectively. Considering the observed trait relationships (Exp-2) slightly improves ELM-FATES simulations of water, energy, and carbon fluxes, but degrades the simulation of PFT coexistence. Using eXtreme Gradient Boosting (XGBoost) based surrogate models trained on Exp-1, we optimize the trait-related parameters in ELM-FATES to enable PFT coexistence and reduce model errors relative to the field observations. We used parameters selected by the surrogate model to conduct another ensemble of ELM-FATES experiments (Exp-3). The probability of experiments yielding PFT coexistence greatly increases from 21 % in Exp-1 to 73 % in Exp-3. Further filtering those experiments that allow for PFT coexistence to agree within 15 % of the observations, Exp-3 still has 33 % of experiments left, much higher than the 1.4 % in Exp-1. Exp-3 also better reproduces the annual means and seasonal variations of water, energy and carbon fluxes, and the field inventory of above ground biomass. Our study demonstrates the benefits of using machine learning models to improve PFT coexistence modeling in ELM-FATES, with important implications for modeling the response and feedback of ecosystem dynamics to climate change. Our results also suggest that new mechanisms are required for robust simulation of coexisting plants in FATES.

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Global Evaluation of the Ecosystem Demography Model (ED v3.0)

Cited by 3 publications

References 72 publications

Global evaluation of the Ecosystem Demography model (ED v3.0)

Global evaluation of the Ecosystem Demography model (ED v3.0)

Feasibility of Formulating Ecosystem Biogeochemical Models From Established Physical Rules

A machine learning approach targeting parameter estimation for plant functional type coexistence modeling using ELM-FATES (v2.0)

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