Climate‐driven uncertainties in modeling terrestrial gross primary production: a site level to global‐scale analysis

Barman, Rahul; Jain, Atul K.; Liang, Miaoling

doi:10.1111/gcb.12474

Cited by 80 publications

(90 citation statements)

References 90 publications

(239 reference statements)

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“…The model calculates carbon, nitrogen, energy, and water fluxes at 0.5×0.5°spatial resolution and at multiple temporal resolutions ranging from half-hour to yearly time steps. The details about the model structure, parameterization, and performance have been introduced in previous studies [21][22][23][24][25]. In the following, we provide the details of the processes added to the model, which are specific for this study.…”

Section: Model Descriptionmentioning

confidence: 99%

“…While ISAM methodologies to model carbon assimilation, water and energy fluxes, and carbon and nitrogen dynamics for various plant functional types have been described elsewhere [21][22][23][24][25], this study extends ISAM model by accounting additional dynamic structural properties of vegetation, which are specific to the perennial bioenergy grasses. These include the following: (1) a specific phenology development scheme and its variation with latitude, which is controlled by thermal, photoperiod, and extreme meteorological conditions (e.g., frost and drought); (2) a dynamic carbon allocation process to allocate assimilated carbon among root, rhizome, leaf, and stem based on resource availability (e.g., light, water, and nutrient); (3) parameterization of N resorption rate; (4) parameterization of leaf area index (LAI) growth process, which is sensitive to photoperiod.…”

Section: Introductionmentioning

confidence: 99%

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Estimates of Biomass Yield for Perennial Bioenergy Grasses in the USA

et al. 2014

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Section: Model Descriptionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Estimates of Biomass Yield for Perennial Bioenergy Grasses in the USA

et al. 2014

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“…Gross primary production (GPP) from photosynthesis has been well understood at leaf and canopy levels; however, ecosystem level estimation of GPP has not yet been well investigated (Asaf et al, 2013;Barman, Jain, & Liang, 2014). Since the 1990s, the eddy covariance method has been used as an important tool to measure heat, water, and CO 2 exchanges as well as trace green-house gases (Baldocchi, 2014).…”

Section: Introductionmentioning

confidence: 99%

“…To better understand the global carbon-cycle feedback to climate change, it is critical to estimate GPP variability due to climate variation (e.g., drought), as it dominates the global GPP anomalies (Barman et al, 2014;Zscheischler et al, 2014). Previous studies have shown that EVI-based VPM, TG, GR, and VI models perform well in forest, grassland and cropland ecosystems under non-drought condition (Gitelson et al, 2006;Kalfas, Xiao, Vanegas, Verma, & Suyker, 2011;Sims et al, 2008;Wu, Gonsamo, Zhang, & Chen, 2014;Wu, Munger, Niu, & Kuang, 2010;Wu et al, 2011;Xiao et al, 2005).…”

Section: Introductionmentioning

confidence: 99%

Comparison of four EVI-based models for estimating gross primary production of maize and soybean croplands and tallgrass prairie under severe drought

Dong

Xiao

Wagle

et al. 2015

Remote Sensing of Environment

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Berrien III, "Comparison of four EVI-based models for estimating gross primary production of maize and soybean croplands and tallgrass prairie under severe drought" (2015). Accurate estimation of gross primary production (GPP) is critical for understanding ecosystem response to climate variability and change. Satellite-based diagnostic models, which use satellite images and/or climate data as input, are widely used to estimate GPP. Many models used the Normalized Difference Vegetation Index (NDVI) to estimate the fraction of absorbed photosynthetically active radiation (PAR) by vegetation canopy (FPAR canopy ) and GPP. Recently, the Enhanced Vegetation Index (EVI) has been increasingly used to estimate the fraction of PAR absorbed by chlorophyll (FPAR chl ) or green leaves (FPAR green ) and to provide more accurate estimates of GPP in such models as the Vegetation Photosynthesis Model (VPM), Temperature and Greenness (TG) model, Greenness and Radiation (GR) model, and Vegetation Index (VI) model. Although these EVI-based models perform well under non-drought conditions, their performances under severe droughts are unclear. In this study, we run the four EVI-based models at three AmeriFlux sites (rainfed soybean, irrigated maize, and grassland) during drought and non-drought years to examine their sensitivities to drought. As all the four models use EVI for FPAR estimate, our hypothesis is that their different sensitivities to drought are mainly attributed to the ways they handle light use efficiency (LUE), especially water stress. The predicted GPP from these four models had a good agreement with the GPP estimated from eddy flux tower in non-drought years with root mean squared errors (RMSEs) in the order of 2.17 (VPM), 2.47 (VI), 2.85 (GR) and 3.10 g C m −2 day −1 (TG). But their performances differed in drought years, the VPM model performed best, followed by the VI, GR and TG, with the RMSEs of 1.61, 2.32, 3.16 and 3.90 g C m −2 day −1 respectively. TG and GR models overestimated seasonal sum of GPP by 20% to 61% in rainfed sites in drought years and also overestimated or underestimated GPP in the irrigated site. This difference in model performance under severe drought is attributed to the fact that the VPM uses satellite-based Land Surface Water Index (LSWI) to address the effect of water stress (deficit) on LUE and GPP, while the other three models do not have such a mechanism. This study suggests that it is essential for these models to consider the effect of water stress on GPP, in addition to using EVI to estimate FPAR, if these models are applied to estimate GPP under drought conditions.

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“…ISAM has two main components: (1) a biogeophysical module representing sunlit-shaded photosynthesis schemes [7], energy, and soil/snow hydrology [8], [9], [7] and (2) a biogeochemical module, where assimilated carbon is allocated to vegetation, litter, and soil carbon pools [5], [7], [10]. The carbon cycle and nitrogen cycle are coupled together.…”

Section: Background a Isam: Integrated Science Assessment Modelmentioning

confidence: 99%

Scaling the ISAM Land Surface Model through Parallelization of Inter-component Data Transfer

Miller

Robson

Masri

et al. 2014

2014 43rd International Conference on Parallel Processing

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Abstract-We present the progression of developments necessary to scale the ISAM land surface model from single nodes and small clusters with unusually large per-node memory to much larger systems with more common configurations. These efforts include load balancing, conventional library-based output parallelization to reduce memory load, and parallel-in-time data input. On Hopper, a Cray XE6 machine, the result was strong scaling from 256 cores to 16k cores with an efficiency of 32.9%. On Edison, a Cray XC30 machine, the code strong scales from 256 cores to 16k cores with an efficiency of 51.4%. These largescale gains, and the associated performance increases at smaller scale, enable greater scientific productivity for the users of ISAM and open the possibilities of increased resolution in time and space and greater physical fidelity for the simulated processes while remaining computationally feasible.

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Climate‐driven uncertainties in modeling terrestrial gross primary production: a site level to global‐scale analysis

Cited by 80 publications

References 90 publications

Estimates of Biomass Yield for Perennial Bioenergy Grasses in the USA

Estimates of Biomass Yield for Perennial Bioenergy Grasses in the USA

Comparison of four EVI-based models for estimating gross primary production of maize and soybean croplands and tallgrass prairie under severe drought

Scaling the ISAM Land Surface Model through Parallelization of Inter-component Data Transfer

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