BioEarth: Envisioning and developing a new regional earth system model to inform natural and agricultural resource management

Adam, J. C.; Stephens, Jennie C.; Chung, S. H.; Brady, Michael P.; Evans, R. D.; Kruger, Chad E.; Lamb, Brian; Liu, Mingliang; Stöckle, Claudio O.; Vaughan, J. K.; Rajagopalan, K.; Harrison, John; Tague, Christina; Kalyanaraman, Ananth; Chen, Yong; Guenther, Alex; Leung, F. T.; Leung, L. Ruby; Perleberg, Andrew B.; Yoder, Jonathan; Allen, Elizabeth; Anderson, Sarah M.; Chandrasekharan, B.; Malek, Keyvan; Mullis, Tristan; Miller, C.; Nergui, Tsengel; Poinsatte, Justin; Reyes, Julian; Jian, Zhu; Choate, J.; Jiang, Xiaoyan; Nelson, Roger; Yoon, Jin‐Ho; Yorgey, Georgine; Johnson, Kristen; Chinnayakanahalli, K.; Hamlet, Alan F.; Nijssen, Bart; Walden, Von P.

doi:10.1007/s10584-014-1115-2

Cited by 30 publications

(28 citation statements)

References 46 publications

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“…Currently, many existing and new ESMs are being developed to resolve coupled human and natural systems, including representation of resource management activities [Pokhrel et al, 2012;Adam et al, 2014;Kraucunas et al, 2014]. CLM has been developed to represent maize, soybean, and spring wheat including management practices such as fertilizer application, residue management, and harvest [Drewniak et al, 2013]; irrigation from surface water [Sacks et al, 2009;Leng et al, 2013] and from groundwater [Leng et al, 2014].…”

Section: Human Impacts On the Terrestrial Water Cyclementioning

confidence: 99%

Improving the representation of hydrologic processes in Earth System Models

Clark

Fan

Lawrence

et al. 2015

Water Resources Research

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415

401

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Many of the scientific and societal challenges in understanding and preparing for global environmental change rest upon our ability to understand and predict the water cycle change at large river basin, continent, and global scales. However, current large-scale land models (as a component of Earth System Models, or ESMs) do not yet reflect the best hydrologic process understanding or utilize the large amount of hydrologic observations for model testing. This paper discusses the opportunities and key challenges to improve hydrologic process representations and benchmarking in ESM land models, suggesting that (1) land model development can benefit from recent advances in hydrology, both through incorporating key processes (e.g., groundwater-surface water interactions) and new approaches to describe multiscale spatial variability and hydrologic connectivity; (2) accelerating model advances requires comprehensive hydrologic benchmarking in order to systematically evaluate competing alternatives, understand model weaknesses, and prioritize model development needs, and (3) stronger collaboration is needed between the hydrology and ESM modeling communities, both through greater engagement of hydrologists in ESM land model development, and through rigorous evaluation of ESM hydrology performance in research watersheds or Critical Zone Observatories. Such coordinated efforts in advancing hydrology in ESMs have the potential to substantially impact energy, carbon, and nutrient cycle prediction capabilities through the fundamental role hydrologic processes play in regulating these cycles.

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Section: Human Impacts On the Terrestrial Water Cyclementioning

confidence: 99%

Improving the representation of hydrologic processes in Earth System Models

Clark

Fan

Lawrence

et al. 2015

Water Resources Research

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415

401

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“…Improved transparency in the forcing generation process: While VIC's core function is as a hydrologic model, specific modeling decisions were made when MT-CLIM was chosen as VIC's meteorological preprocessor and those decisions were abstracted deep within the model source code. As a result, the implications of forcing VIC with only minimum 5 and maximum temperature and precipitation were abstracted away from and mostly invisible to the user. Removing the preprocessor from VIC enhances the transparency of the model by forcing users to make specific choices about the source of the model forcings.…”

Section: Identical Treatment Of Forcings Between Driversmentioning

confidence: 99%

“…In RASM, VIC-5 is directly coupled to CESM's flux coupler (CPL7; Craig et al, 2012) via the Model Coupling Toolkit interface (MCT; Larson et al, 2005). As implemented within RASM, this interface allows VIC to be coupled to the Weather Research and Forecasting (WRF) atmospheric model (Skamarock,5 2008) and the RVIC streamflow routing model (Hamman et al, 2017) components, while maintaining the legacy and standalone model infrastructure, which have a large existing user base. The successful coupling of VIC-5 within RASM is a key demonstration of the benefits of the source code refactor.…”

mentioning

confidence: 99%

“…Previous versions of VIC have added extended functionality to the model such as streamflow routing (Lohmann et al, 1996;Hamman et al, 2017), reservoirs, irrigation (Haddeland et al, 2006), glaciers and ice sheets, and dynamic vegetation and crops (Adam et al, 2015). These extensions were added either as stand-alone post-processing options or via highly customized interfaces.…”

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confidence: 99%

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The Variable Infiltration Capacity Model, Version 5 (VIC-5): Infrastructure improvements for new applications and reproducibility

Hamman¹,

Nijssen²,

Bohn³

et al. 2018

Preprint

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Abstract. The Variable Infiltration Capacity (VIC) model is a macro-scale semi-distributed hydrologic model. VIC development began in the early 1990s and the model has since been used extensively for basin-to global-scale applications that include hydrologic data set construction, trend analysis of hydrologic fluxes and states, data evaluation and assimilation, forecasting, coupled climate modeling, and climate change impact assessment. Ongoing operational applications of the VIC model include the University of Washington's drought monitoring and forecasting systems and NASA's Land Data Assimilation System. This 5 paper documents the development of VIC version 5 (VIC-5), which includes a major reconfiguration of the legacy VIC source code to support a wider range of modern hydrologic modeling applications. The VIC source code has been moved to a public GitHub repository to encourage participation by the broader user and developer communities. The reconfiguration has separated the core physics of the model from the driver source code, where the latter is responsible for memory allocation, preand post-processing and input/output (I/O). VIC-5 includes four drivers that use the same core physics modules, but which 10 allow for different methods for accessing this core to enable different model applications. Finally, VIC-5 is distributed with robust test infrastructure, components of which routinely run during development using cloud-hosted continuous integration.The work described here provides an example to the model development community for extending the life of a legacy model that is being used extensively. The development and release of VIC-5 represents a significant step forward for the VIC user community in terms of support for existing and new model applications, reproducibility, and scientific robustness.

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“…The accuracy of emission reductions for the iPNW could also be improved through development of regional emission factors (Tier II or Tier III) and might be achieved through field measurements or employing existing biophysical models, such as CropSyst (Stockle et al, 2012), and assessment frameworks, such as BioEarth (Adam et al, 2014). However, lower input models (e.g., COMET-Farm) rather than high input process-based models (e.g., CropSyst, DNDC) would likely reduce transaction costs associated with project development and verification (Li, 2000;Stockle et al, 2012).…”

Section: Impact Of Quantification Approaches On Offsets Generatedmentioning

confidence: 99%

Comparison of Greenhouse Gas Offset Quantification Protocols for Nitrogen Management in Dryland Wheat Cropping Systems of the Pacific Northwest

Brown

Lee

Kruger

et al. 2017

Front. Environ. Sci.

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In the carbon market, greenhouse gas (GHG) offset protocols need to ensure that emission reductions are of high quality, quantifiable, and real. Lack of consistency across protocols for quantifying emission reductions compromise the credibility of offsets generated. Thus, protocol quantification methodologies need to be periodically reviewed to ensure emission offsets are credited accurately and updated to support practical climate policy solutions. Current GHG emission offset credits generated by agricultural nitrogen (N) management activities are based on reducing the annual N fertilizer application rate for a given crop without reducing yield. We performed a "road test" of agricultural N management protocols to evaluate differences among protocol components and quantify nitrous oxide (N 2 O) emission reductions under sample projects relevant to N management in dryland, wheat-based cropping systems of the inland Pacific Northwest (iPNW). We evaluated five agricultural N management offset protocols applicable to North America: two methodologies of American Carbon Registry (ACR1 and ACR2), Verified Carbon Standard (VCS), Climate Action Reserve (CAR), and Alberta Offset Credit System (Alberta). We found that only two protocols, ACR2 and VCS, were suitable for this study, in which four sample projects were developed representing feasible N fertilizer rate reduction activities. The ACR2 and VCS protocols had identical baseline and project emission quantification methodologies resulting in identical emission reduction values. Reducing N fertilizer application rate by switching to variable rate N (sample projects 1-3) or split N application (sample project 4) management resulted in a N 2 O emission reduction ranging from 0.07 to 0.16, and 0.26 Mg CO 2 e ha −1 , respectively. Across the range of C prices considered ($5, $10, and $50 per metric ton of CO 2 equivalent), we concluded that the N 2 O emission offset payment alone ($0.35-$13.0 ha −1 ) was unlikely to encourage a change in fertilizer N management; however, the fertilizer cost savings from adopting variable or split N management would incentivize Brown et al.Nitrogen Management for GHG Offsets adopting these practices. Therefore, the monetary incentive of adopting agricultural N management BMPs for reducing N 2 O emission should be tied to other co-benefits and existing conservation programs to encourage N rate reductions that do not limit yield, crop quality, or economic stability.

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BioEarth: Envisioning and developing a new regional earth system model to inform natural and agricultural resource management

Cited by 30 publications

References 46 publications

Improving the representation of hydrologic processes in Earth System Models

Improving the representation of hydrologic processes in Earth System Models

The Variable Infiltration Capacity Model, Version 5 (VIC-5): Infrastructure improvements for new applications and reproducibility

Comparison of Greenhouse Gas Offset Quantification Protocols for Nitrogen Management in Dryland Wheat Cropping Systems of the Pacific Northwest

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