Katherine Calvin’s research while affiliated with Pacific Northwest National Laboratory and other places

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Publications (172)


Figure 1: New framework of utilizing FAOSTAT data in GCAM and similar large-scale models through gcamfaostat. Modules with identifier "xfaostat" only exist in gcamfaostat. The AgLU-related modules ("aglu") that rely on outputs from gcamfaostat can run in both packages. Other gcamdata modules that process data in such areas as energy, emissions, water, and socioeconomics only exist in gcamdata.
Figure 2: Data processing architecture in gcamfaostat.
gcamfaostat: An R package to prepare, process, and synthesize FAOSTAT data for global agroeconomic and multisector dynamic modeling
  • Article
  • Full-text available

April 2024

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66 Reads

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6 Citations

The Journal of Open Source Software

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Pralit Patel

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Panel (a) Regional wind and solar energy in the top 5% of scenarios across all GCAM regions in 2020 and 2050. Panel (b) Total solar (left) and wind (right) electricity generation from 2020 to 2050 in the top eight regions, averaged across the top 5% of scenarios in our ensemble.
Drivers of wind and solar electricity generation across each region across all scenarios. Left panel is the fraction of wind and solar electricity in each region out of the global total. Middle panel is the corresponding maximum fraction of renewable energy in each region across all scenarios. Right panel shows the relative importance of each input to the fraction of combined solar and wind electricity generation in each region, quantified by regression variable importance scores from Classification and Regression Trees (CART).
Paths to high combined wind and solar energy, defined as the top 5% of wind and solar electricity generation. Each path is named by the input parameter or parameters that differentiate it from the three others. The fractions along each path correspond to the total number of scenarios that fall into the top 5% of wind and solar electricity generation over the total number of scenarios from the full ensemble that solved with this particular combination of parameters.
Regional synergies (blue) and tradeoffs (red) of different paths to high combinations of wind and solar electricity generation in Global Change Analysis Model. A set of eight example regions were selected to illustrate regional variability, two from each of four levels of gross national income (GNI) per capita (Figure S4 in Supporting Information S1). The outline type on each bar corresponds to statistical significance, where a dashed line is not a statistically significant result.
Sectoral breakdown of differences between the four key pathways in a select few regions. Individual bars give the difference between the value in the given path and the mean across all others. Panel (a) shows water consumption changes between paths in Brazil, Japan, and the United States as examples. Panel (b) shows carbon monoxide emissions across Africa Western, Brazil, and China. Note that the y‐axis scales differ for visibility.
Scenario Discovery Analysis of Drivers of Solar and Wind Energy Transitions Through 2050

August 2023

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206 Reads

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5 Citations

Deep human‐Earth system uncertainties and strong multi‐sector dynamics make it difficult to anticipate which conditions are most likely to lead to higher or lower adoption of renewable energy, and models project a broad range of future solar and wind energy shares across future scenarios. To elucidate these dynamics, we explore a large data set of scenarios simulated from the Global Change Analysis Model (GCAM), and use scenario discovery to identify the most significant factors affecting solar and wind adoption by mid‐century. We generated a data set of over 4,000 scenarios from GCAM by varying 12 different socioeconomic factors at high and low levels, including assumptions about future energy demand, resource costs, and fossil fuel emissions paths, as well as specific technology assumptions including wind and solar backup requirements and storage costs. Using scenario discovery, we assess the most important factors globally and regionally in creating high fractions of solar and wind energy and explore interconnected effects on other systems including water and non‐CO2 emissions. Globally and regionally, we found that solar and wind‐related technology costs were the primary drivers of high wind and solar energy adoption, though a few regions depend heavily on other parameters like carbon capture and storage costs, population and gross domestic product trajectories, and fossil fuel costs. We also identify four key paths to high solar and wind energy by mid‐century and discuss their tradeoffs in terms of other outcomes.


Present and Future Changes in Land‐Atmosphere Coupling of Water and Energy Over Extratropical Forest Regions

April 2023

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83 Reads

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1 Citation

Couplings between land and the near surface atmosphere are modulated by interactions between soil conditions, vegetation dynamics, turbulent fluxes, and atmospheric properties. How the land‐atmosphere coupling responds to warming and elevated CO2 are important for understanding the land surface carbon, energy, and water cycles. In this work, we documented this coupled land‐atmosphere network based on observations and the Energy Exascale Earth System Model (E3SM) simulations over extratropical forest ecosystems. We employed a transfer entropy approach and novel network metrics to reveal patterns and strength of the land‐atmosphere coupling under historical conditions and a future high emission scenario (SSP585). We found that, in observations, the present‐day extratropical forest coupling network has high network connectivity (72%–88% of the targeted processes are coupled). E3SM reasonably captured the extratropical forest coupling network (modeled network connectivity was 81%–96%) and predicted that the coupling strength would significantly increase by 28% (±3%) under warming and elevated CO2 conditions. Furthermore, E3SM factorial coupled experiments suggested that warming enhanced soil nitrogen mineralization favoring plant nitrogen uptake and vegetation growth were responsible for the strengthening future land‐atmosphere coupling. This work provides new metrics to analyze and document complex couplings for coupled earth system processes and highlights the important roles soil nutrient availability and biogeochemistry have on land‐atmosphere coupling.


Contrasting the Biophysical and Radiative Effects of Rising CO2 Concentrations on Ozone Dry Deposition Fluxes

March 2023

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66 Reads

The dry deposition of ozone from the atmosphere to ecosystems is an important coupling mechanism between atmospheric chemistry and terrestrial biogeochemical processes. In most Earth system models, dry deposition is simulated using a resistor‐in‐series approach that aims to parameterize the governing biological, chemical, and physical processes through a series of functional approximations. Here, we evaluate the influence of carbon cycle‐climate responses on this parameterization using the results of the Energy Exascale Earth System Model v1.1 Biogeochemistry simulation campaign. This simulation campaign was designed in part to explore the biophysical and radiative effects of rising historical CO2 concentrations on the Earth system. We find that while the global annual ozone dry deposition is relatively insensitive to these effects, regionally the influence can be up to 10%. The strongest regional sensitivities in ozone dry deposition are predominantly in higher latitudes over land in the northern hemisphere and are dominated by the radiative effect of CO2, with little net influence of biophysical responses. Of all the impacts of the radiative effect of CO2, we point to the potential importance of accurately representing ozone deposition to snow in Earth System Models and provide recommendations for future simulation campaigns.


The Impact of Crop Rotation and Spatially Varying Crop Parameters in the E3SM Land Model (ELMv2)

March 2023

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136 Reads

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5 Citations

Earth System Models (ESMs) are increasingly representing agriculture due to its impact on biogeochemical cycles, local and regional climate, and fundamental importance for human society. Realistic large scale simulations may require spatially varying crop parameters that capture crop growth at various scales and among different cultivars, as well as common crop management practices, but their importance is uncertain, and they are often not represented in ESMs. In this study, we examine the impact of using constant versus spatially varying crop parameters using a novel, realistic crop rotation scenario in the Energy Exascale Earth System Model (E3SM) Land Model version 2 (ELMv2). We implemented crop rotation by using ELMv2's dynamic land unit capability, and then calibrated and validated the model against observations collected at three AmeriFlux sites in the US Midwest with corn soybean rotation. The calibrated model closely captured the magnitude and observed seasonality of carbon and energy fluxes across crops and sites. We performed regional simulations for the US Midwest using the calibrated model and found that spatially varying only a few crop parameters across the region, as opposed to using constant parameters, had a large impact, with the carbon fluxes and energy fluxes both varying by up to 40%. These results imply that large scale ESM simulations using spatially invariant crop parameters may result in biased energy and carbon fluxes estimation from agricultural land, and underline the importance of improving human‐earth systems interactions in ESMs.



Modeling perennial bioenergy crops in the E3SM land model (ELMv2)

January 2023

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151 Reads

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5 Citations

Perennial bioenergy crops are increasingly important for the production of ethanol and other renewable fuels, and as part of an agricultural system that alters the climate through its impact on biogeophysical and biogeochemical properties of the terrestrial ecosystem. Few Earth System Models (ESMs) represent such crops, however. In this study, we expand the Energy Exascale Earth System Land Model to include perennial bioenergy crops with a high potential for mitigating climate change. We focus on high‐productivity miscanthus and switchgrass, estimating various parameters associated with their different growth stages and performing a global sensitivity analysis to identify and optimize these parameters. The sensitivity analysis identifies five parameters associated with phenology, carbon/nitrogen allocation, stomatal conductance, and maintenance respiration as the most sensitive parameters for carbon and energy fluxes. We calibrated and validated the model against observations and found that the model closely captures the observed seasonality and the magnitude of carbon fluxes. The validated model represents the latent heat flux fairly well, but sensible heat flux for miscanthus is not well captured. Finally, we validated the model against observed leaf area index (LAI) and harvest amount and found modeled LAI captured observed seasonality, although the model underestimates LAI and harvest amount. This work provides a foundation for future ESM analyses of the interactions between perennial bioenergy crops and carbon, water, and energy dynamics in the larger Earth system, and sets the stage for studying the impact of future biofuel expansion on climate and terrestrial systems.


Doubling protected land area may be inefficient at preserving the extent of undeveloped land and could cause substantial regional shifts in land use

December 2022

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197 Reads

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5 Citations

Projection of land use and land‐cover change is highly uncertain yet drives critical estimates of carbon emissions, climate change, and food and bioenergy production. We use new, spatially explicit land availability data in conjunction with a model sensitivity analysis to estimate the effects of additional land protection on land use and land cover. The land availability data include protected land and agricultural suitability and is incorporated into the Moirai land data system for initializing the Global Change Analysis Model. Overall, decreasing land availability is relatively inefficient at preserving undeveloped land while having considerable regional land‐use impacts. Current amounts of protected area have little effect on land and crop production estimates, but including the spatial distribution of unsuitable (i.e., unavailable) land dramatically shifts bioenergy production from high northern latitudes to the rest of the world, compared with uniform availability. This highlights the importance of spatial heterogeneity in understanding and managing land change. Approximately doubling the current protected area to emulate a 30% protected area target may avoid land conversion by 2050 of less than half the newly protected extent while reducing bioenergy feedstock land by 10.4% and cropland and grazed pasture by over 3%. Regional bioenergy land may be reduced (increased) by up to 46% (36%), cropland reduced by up to 61%, pasture reduced by up to 100%, and harvested forest reduced by up to 35%. Only a few regions show notable gains in some undeveloped land types of up to 36%. Half of the regions can reach the target using only unsuitable land, which would minimize impacts on agriculture but may not meet conservation goals. Rather than focusing on an area target, a more robust approach may be to carefully select newly protected land to meet well‐defined conservation goals while minimizing impacts to agriculture.


Figure 1: Schematic of the gdess code structure.
Figure 2: Global map showing surface observing station locations (red circles) and their three-letter site codes, as recorded in Obspack and used in gdess.
Figure 3: Example output of the surface_trends recipe, showing (a) individual time series and (b) differences between simulated and observed concentrations of surface-level atmospheric CO 2 at the Mauna Loa Observatory, Hawaii (MLO).
Figure 4: Example output of the seasonal_cycle recipe, comparing annual climatologies of surface atmospheric CO 2 concentrations at the American Samoa Observatory, Tutuila Island (SMO).
Figure 5: Example output of the meridional recipe, comparing the seasonal cycle across latitudes, at locations of user-specified surface stations.
gdess: A framework for evaluating simulated atmospheric CO2 in Earth System Models

August 2022

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143 Reads

The Journal of Open Source Software

Atmospheric carbon dioxide (CO2) plays a key role in the global carbon cycle and global warming. Climate-carbon feedbacks are often studied and estimated using Earth System Models (ESMs), which couple together multiple model components—including the atmosphere, ocean, terrestrial biosphere, and cryosphere—to jointly simulate mass and energy exchanges within and between these components. Despite tremendous advances, model intercomparisons and benchmarking are aspects of ESMs that warrant further improvement (Fer et al., 2021; Smith et al., 2014). Such benchmarking is critical because comparing the value of state variables in these simulations against observed values provides evidence for appropriately refining model components; moreover, researchers can learn much about Earth system dynamics in the process (Randall et al., 2019). We introduce gdess (a.k.a., Greenhouse gas Diagnostics for Earth System Simulations), which parses observational datasets and ESM simulation output, combines them to be in a consistent structure, computes statistical metrics, and generates diagnostic visualizations. In its current incarnation, gdess facilitates evaluating a model’s ability to reproduce observed temporal and spatial variations of atmospheric CO2. The diagnostics implemented modularly in gdess support more rapid assessment and improvement of model-simulated global CO2 sources and sinks associated with land and ocean ecosystem processes. We intend for this set of automated diagnostics to form an extensible, open source framework for future comparisons of simulated and observed concentrations of various greenhouse gases across Earth system models.


Citations (84)


... In other words, the per capita food calorie consumption is responsive to price & income and substitution is allowed between staple and nonstaple food calories, as implied by the parameters specified. Food calories, or dietary energy available, were derived based on food demand (in tonnes) and the conversion factors were compiled based on FAOSTAT data using the R package gcamfaostat (Zhao et al., 2024a). ...

Reference:

Core Model Proposal #393: Update AgLU parameters for land-based mitigation measures
gcamfaostat: An R package to prepare, process, and synthesize FAOSTAT data for global agroeconomic and multisector dynamic modeling

The Journal of Open Source Software

... Water resources are increasingly receiving widespread attention, with research by Graham et al. (2023) and Scanlon et al. (2023) indicating that water scarcity poses a serious global challenge. Given the projected significant reduction in terrestrial water storage (Pokhrel et al., 2021) and the current reality that which the agricultural sector consumes 70 % of the global water usage (Kang et al., 2017), the severity of water scarcity in agriculture is expected to worsen. ...

Agricultural market integration preserves future global water resources
  • Citing Article
  • September 2023

One Earth

... This understanding of sensitivity and drivers can facilitate identification of pros and cons of different pathways to outcomes of interest (e.g., to minimize water scarcity [5]). The ensembles are often designed to incorporate a range of data sources, expert opinion, and discrete parameterizations in a factorial combination [18]. However, even with access to modern computing clusters, computational cost hinders a comprehensive exploration of these inputs. ...

Scenario Discovery Analysis of Drivers of Solar and Wind Energy Transitions Through 2050

... Average temperatures have already increased and are on a rapidly increasing trajectory making the limitation of warming to 1.5 • C or even 2 • C beyond reach [1,2]. One of the major concerns associated with climate change is not only the increase in average temperatures but also the increasing frequency of prolonged periods of extreme temperatures, referred to as heatwaves [3,4]. ...

Climate Change 2023: Synthesis Report. Contribution of Working Groups I, II and III to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change

... Their findings demonstrated that 91% of the fluctuation in GPP may be linked to changes in VPD. A study by Zhu et al. (2023) utilized a transfer entropy (TE) method and new network parameters to uncover the trends and strengths of the interaction between land and atmosphere. They examined both historical conditions and a future scenario with high emissions. ...

Present and Future Changes in Land‐Atmosphere Coupling of Water and Energy Over Extratropical Forest Regions

... The parameters associated with the prognostic S&H schemes and several commonly sensitive parameters related to crop growth (Table 1), as identified by previous research (Arsenault et al., 2018;Huo et al., 2019;Li et al., 2020;Sinha et al., 2023;Yang et al., 2021;Yu et al., 2022;Zhang et al., 2020), were calibrated to ensure the accurate simulation of maize and soybean dynamic growth. Firstly, as found by Chen et al. (2018), the minimum temperature threshold (T min p ) for sowing is easily attained; therefore, the value of T p determines the sowing date. ...

The Impact of Crop Rotation and Spatially Varying Crop Parameters in the E3SM Land Model (ELMv2)

... Assuming our representation of modeled and observed fine-root biomass can be rectified, these observations would form a key component of future calibration exercises. Such an exercise would also require more sophisticated toolsets to explore the parameter optimization space (such as Offline Land Model Testbed (Lu et al., 2018;Sinha et al., 2023), the Predictive ECosystem ANalyzer (LeBauer et al., 2013), LAVENDAR (Pinnington et al., 2020), etc.) ...

Modeling perennial bioenergy crops in the E3SM land model (ELMv2)

... The results provide evidence on the speed and viability of long-term forests-based mitigation, with the ultimate objective to support GHG abatement policies and future NDCs. used for studying climate change mitigation from agriculture and land use (Zhao et al 2021, Di Vittorio et al 2023. The land and water systems are subdivided into 235 water basins and 32 geopolitical regions structure the economic and energy systems, resulting in a total of 384 distinct land-water regions (called land use units, LUTs). ...

Doubling protected land area may be inefficient at preserving the extent of undeveloped land and could cause substantial regional shifts in land use

... Across the United States, biomass production is projected to increase, despite general uncertainties around midlatitude changes. Studies are consistent with respect to the CO 2 fertilization effect increasing biomass production, but not necessarily for all crops, especially when accounting for other processes such as the nitrogen cycle and water quality [14,[68][69][70]73,75]. Additionally, these increases in production could come at the cost of increased deforestation, higher water stress, and nutrient leaching [75]. ...

Future bioenergy expansion could alter carbon sequestration potential and exacerbate water stress in the United States
  • Citing Article
  • May 2022

Science Advances

... In each of these simulations, changes in the land and atmosphere interact dynamically. For example, changes in physiological impact simulations can include both the changes in vegetation associated with ecosystem responses to CO 2 and the resulting changes to the atmosphere through biosphere-atmosphere coupling (e.g., changes to transpiration and heat fluxes via changing LAI) (Harrop et al., 2022). Due to an issue with data storage, only results through 2006 were stored for scenario 3. ...

Diurnal Rainfall Response to the Physiological and Radiative Effects of CO2 in Tropical Forests in the Energy Exascale Earth System Model v1