PhytoSFDM version 1.0.0: Phytoplankton Size and Functional Diversity Model

Acevedo‐Trejos, Esteban; Brandt, Gunnar; Smith, S. Lan; Merico, Agostino

doi:10.5194/gmd-9-4071-2016

Cited by 14 publications

(23 citation statements)

References 54 publications

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“…where λ is a positive constant. Whether the power law or the lognormal distribution fits better to empirical data has been widely debated in the literature, and many results show that both can fit the data equally well (Allen et al, 2001;Mitzenmacher, 2004;Clauset et al, 2009). This is not surprising given that the two distributions are intrinsically connected (Mitzenmacher, 2004;Newman, 2005).…”

Section: Assumption Of Trait Distributionmentioning

confidence: 99%

CITRATE 1.0: Phytoplankton continuous trait-distribution model with one-dimensional physical transport applied to the North Pacific

Chen

Smith

2018

Geosci. Model Dev.

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Abstract. Diversity plays critical roles in ecosystem functioning, but it remains challenging to model phytoplankton diversity in order to better understand those roles and reproduce consistently observed diversity patterns in the ocean. In contrast to the typical approach of resolving distinct species or functional groups, we present a ContInuous TRAiT-basEd phytoplankton model (CITRATE) that focuses on macroscopic system properties such as total biomass, mean trait values, and trait variance. This phytoplankton component is embedded within a nitrogen–phytoplankton-zooplankton–detritus–iron model that itself is coupled with a simplified one-dimensional ocean model. Size is used as the master trait for phytoplankton. CITRATE also incorporates trait diffusion for sustaining diversity and simple representations of physiological acclimation, i.e., flexible chlorophyll-to-carbon and nitrogen-to-carbon ratios. We have implemented CITRATE at two contrasting stations in the North Pacific where several years of observational data are available. The model is driven by physical forcing including vertical eddy diffusivity imported from three-dimensional general ocean circulation models (GCMs). One common set of model parameters for the two stations is optimized using the Delayed-Rejection Adaptive Metropolis–Hasting Monte Carlo (DRAM) algorithm. The model faithfully reproduces most of the observed patterns and gives robust predictions on phytoplankton mean size and size diversity. CITRATE is suitable for applications in GCMs and constitutes a prototype upon which more sophisticated continuous trait-based models can be developed.

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Section: Assumption Of Trait Distributionmentioning

confidence: 99%

CITRATE 1.0: Phytoplankton continuous trait-distribution model with one-dimensional physical transport applied to the North Pacific

Chen

Smith

2018

Geosci. Model Dev.

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“…The optimized u value was much higher than in Acevedo-Trejos et al (2016). Reducing u to 0.05 led to worse fits to the size-fractionated chlorophyll since lower size variance failed to capture the observed size scatter.…”

Section: Parameter Optimization and Sensitivity Analysismentioning

confidence: 83%

“…Besides the improved computational efficiency (Acevedo-Trejos et al, 2016), the most important advantage of the continuous trait-based 'adaptive dynamics' approach is expressed well in the following quote from Bak (1996): "If, following traditional scientific methods, we concentrate on an accurate description of the details, we lose perspective." (p. 10) and, "It is a futile endeavour to try to explain most natural phenomena in detail by starting from particle physics and following the trajectories of all particles."…”

Section: Facilitating Understanding On Ecological Mechanismsmentioning

confidence: 99%

“…Continuous trait-based models have been developed to address the above questions (Wirtz and Eckhardt, 1996;Norberg et al, 2001;Bruggeman, 2009;Merico et al, 2009Merico et al, , 2014Terseleer et al, 2014;Acevedo-Trejos et al, 2016;Smith et al, 2016). Instead of modeling the dynamics of individual species, continuous trait-based models or so-called "adaptive dynamics" models focus on macroscopic or aggregate properties of a community such as total biomass, average trait, and trait variance by assuming that phytoplankton traits follow some distribution (usually Gaussian) (Smith et al, 2011).…”

Section: Introductionmentioning

confidence: 99%

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CITRATE 1.0: Phytoplankton continuous trait-distribution model with one-dimensional physical transport applied to the Northwest Pacific

Chen¹,

Smith²

2017

Preprint

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Abstract. Diversity plays critical roles in ecosystem functioning, but it remains unclear how best to model phytoplankton diversity in order to better understand those roles and reproduce consistently observed patterns in the ocean. In contrast to the typical approach of resolving distinct species or functional groups, we present a ContInuous TRAiT-basEd phytoplankton model (CITRATE) that focuses on macroscopic properties such as total biomass, mean trait values, and trait variance. This phytoplankton component is embedded within a Nitrogen-Phytoplankton-Zooplankton-Detritus-Iron model that itself is coupled with a simplified one-dimensional ocean model. Size is used as the master trait for phytoplankton. CITRATE also incorporates trait diffusion for sustaining diversity, as well as simple representations of physiological acclimation, i.e. flexible chlorophyll-to-carbon and nitrogen-to-carbon ratios. We implemented CITRATE 1.0 at two contrasting stations in the Northwest Pacific where several years of observational data are available. The model is driven by physics forcing including vertical eddy diffusivity imported from three-dimensional ocean circulation models. One common set of model parameters for the two stations was optimized using the Delayed Rejection Adaptive Metropolis-Hasting Monte Carlo (DRAM) algorithm. The model faithfully reproduced most of the observational patterns and gave robust predictions on phytoplankton mean size and size diversity. With proper physical forcing, CITRATE 1.0 can be applied to any oceanic station where either nitrogen or iron limits phytoplankton growth.

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“…In phytoplankton body size is usually estimated as cell size along the maximum linear dimension (abbreviated as MLD or GALD: greatest axial linear dimension). The use of cell size is common to both the explicit trait and morphospecies frameworks and lends itself well to ecosystem modeling (e.g., Acevedo-Trejos et al, 2016).…”

Section: "Master" Traitsmentioning

confidence: 99%

Measures and Approaches in Trait-Based Phytoplankton Community Ecology – From Freshwater to Marine Ecosystems

Weithoff

Beisner

2019

Front. Mar. Sci.

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Trait-based approaches to investigate (short-and long-term) phytoplankton dynamics and community assembly have become increasingly popular in freshwater and marine science. Although the nature of the pelagic habitat and the main phytoplankton taxa and ecology are relatively similar in both marine and freshwater systems, the lines of research have evolved, at least in part, separately. We compare and contrast the approaches adopted in marine and freshwater ecosystems with respect to phytoplankton functional traits. We note differences in study goals relating to functional trait use that assess community assembly and those that relate to ecosystem processes and biogeochemical cycling that affect the type of characteristics assigned as traits to phytoplankton taxa. Specific phytoplankton traits relevant for ecological function are examined in relation to herbivory, amplitude of environmental change and spatial and temporal scales of study. Major differences are identified, including the shorter time scale for regular environmental change in freshwater ecosystems compared to that in the open oceans as well as the type of sampling done by researchers based on site-accessibility. Overall, we encourage researchers to better motivate why they apply trait-based analyses to their studies and to make use of process-driven approaches, which are more common in marine studies. We further propose fully comparative trait studies conducted along the habitat gradient spanning freshwater to brackish to marine systems, or along geographic gradients. Such studies will benefit from the combined strength of both fields.

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PhytoSFDM version 1.0.0: Phytoplankton Size and Functional Diversity Model

Cited by 14 publications

References 54 publications

CITRATE 1.0: Phytoplankton continuous trait-distribution model with one-dimensional physical transport applied to the North Pacific

CITRATE 1.0: Phytoplankton continuous trait-distribution model with one-dimensional physical transport applied to the North Pacific

CITRATE 1.0: Phytoplankton continuous trait-distribution model with one-dimensional physical transport applied to the Northwest Pacific

Measures and Approaches in Trait-Based Phytoplankton Community Ecology – From Freshwater to Marine Ecosystems

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