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286 results on '"Ricciuto, Daniel M."'

1. Nutrient Dynamics in a Coupled Terrestrial Biosphere and Land Model (ELM‐FATES‐CNP)

Author

Knox, Ryan G, Koven, Charles D, Riley, William J, Walker, Anthony P, Wright, S Joseph, Holm, Jennifer A, Wei, Xinyuan, Fisher, Rosie A, Zhu, Qing, Tang, Jinyun, Ricciuto, Daniel M, Shuman, Jacquelyn K, Yang, Xiaojuan, Kueppers, Lara M, and Chambers, Jeffrey Q

Subjects
Earth Sciences, Atmospheric Sciences, Geoinformatics, land model, biogeochemistry, terrestrial, ecosystem, vegetation, ESM, Atmospheric sciences
Abstract

We present a representation of nitrogen and phosphorus cycling in the Functionally Assembled Terrestrial Ecosystem Simulator, a demographic vegetation model within the Energy Exascale Earth System land model. This representation is modular, and designed to allow testing of multiple hypothetical approaches for carbon-nutrient coupling in plants. Novel model hypotheses introduced in this work include, (a) the controls on plant acquisition of aqueous mineralized nutrients in the soil and (b) fairly straight forward methods of allocating nutrients to specific plant organs and their losses through live plant turnover as well as litter fluxes generated through plant mortality. This combines the new with pre-existing hypotheses (such as nitrogen fixation and soil decomposition) into a system that can accommodate plant-soil dynamics for a large number of size- and functional-type-resolved plant cohorts within a time-since-disturbance-resolved ecosystem. Root uptake of nutrients is governed by fine root biomass, and plants vary in their fine root biomass allocation in order to balance carbon and nutrient limitations to growth. We test the sensitivity of the model to a wide range of parameter variations and structural representations, and in the context of observations at Barro Colorado Island, Panama. A key model prediction is that plants in the high-light-availability canopy positions allocate more carbon to fine roots than plants in low-light understory environments, given the widely different carbon versus nutrient constraints of these two niches within a given ecosystem. This model provides a basis for exploring carbon-nutrient coupling with vegetation demography within Earth system models.

Published
2024

2. Intensified Positive Arctic–Methane Feedback under IPCC Climate Scenarios in the 21st Century

Author

Wang, Yihui, He, Liyuan, Liu, Jianzhao, Arndt, Kyle A, Mazza Rodrigues, Jorge L, Zona, Donatella, Lipson, David A, Oechel, Walter C, Ricciuto, Daniel M, Wullschleger, Stan D, and Xu, Xiaofeng

Subjects
Climate Change Impacts and Adaptation, Ecological Applications, Environmental Sciences, Climate Action, Climate change impacts and adaptation, Ecological applications
Abstract

The positive Arctic–methane (CH 4 ) feedback forms when more CH 4 is released from the Arctic tundra to warm the climate, further stimulating the Arctic to emit CH 4 . This study utilized the CLM-Microbe model to project CH 4 emissions across five distinct Arctic tundra ecosystems on the Alaska North Slope, considering three Shared Socioeconomic Pathway (SSP) scenarios using climate data from three climate models from 2016 to 2100. Employing a hyper-resolution of 5 m × 5 m within 40,000 m 2 domains accounted for the Arctic tundra’s high spatial heterogeneity; three sites were near Utqiaġvik (US-Beo, US-Bes, and US-Brw), with one each in Atqasuk (US-Atq) and Ivotuk (US-Ivo). Simulated CH 4 emissions substantially increased by a factor of 5.3 to 7.5 under the SSP5–8.5 scenario compared to the SSP1–2.6 and SSP2–4.5 scenarios. The projected CH 4 emissions exhibited a stronger response to rising temperature under the SSP5–8.5 scenario than under the SSP1–2.6 and SSP2–4.5 scenarios, primarily due to strong temperature dependence and the enhanced precipitation-induced expansion of anoxic conditions that promoted methanogenesis. The CH 4 transport via ebullition and plant-mediated transport is projected to increase under all three SSP scenarios, and ebullition dominated CH 4 transport by 2100 across five sites. Projected CH 4 emissions varied in temperature sensitivity, with a Q 10 range of 2.7 to 60.9 under SSP1–2.6, 3.8 to 17.6 under SSP2–4.5, and 5.7 to 17.2 under SSP5–8.5. Compared with the other three sites, US-Atq and US-Ivo were estimated to have greater increases in CH 4 emissions due to warmer temperatures and higher precipitation. The fact that warmer sites and warmer climate scenarios had higher CH 4 emissions suggests an intensified positive Arctic–CH 4 feedback in the 21st century. Microbial physiology and substrate availability dominated the enhanced CH 4 production. The simulated intensified positive feedback underscores the urgent need for a more mechanistic understanding of CH 4 dynamics and the development of strategies to mitigate CH 4 across the Arctic.

Published
2024

4. Guidelines for Publicly Archiving Terrestrial Model Data to Enhance Usability, Intercomparison, and Synthesis

Author

Simmonds, Maegen B, Riley, William J, Agarwal, Deborah A, Chen, Xingyuan, Cholia, Shreyas, Crystal-Ornelas, Robert, Coon, Ethan T, Dwivedi, Dipankar, Hendrix, Valerie C, Huang, Maoyi, Jan, Ahmad, Kakalia, Zarine, Kumar, Jitendra, Koven, Charles D, Li, Li, Melara, Mario, Ramakrishnan, Lavanya, Ricciuto, Daniel M, Walker, Anthony P, Zhi, Wei, Zhu, Qing, and Varadharajan, Charuleka

Subjects
Information and Computing Sciences, Library and Information Studies, Data Science, Artificial Intelligence and Image Processing, Data Format, Computation Theory & Mathematics, Data management and data science
Abstract

Scientific communities are increasingly publishing data to evaluate, accredit, and build on published research. However, guidelines for curating data for publication are sparse for model-related research, limiting the usability of archived simulation data. In particular, there are no established guidelines for archiving data related to terrestrial models that simulate land processes and their coupled interactions with climate. Terrestrial modelers have a unique set of challenges when publishing data due to the diversity of scientific domains, research questions, and the types and scales of simulations. Researchers in the U.S. Department of Energy’s (DOE) projects use a variety of multiscale models to advance robust predictions of terrestrial and subsurface ecosystem processes. Here, we synthesize archiving needs for data associated with different DOE models, and provide guidelines for publishing terrestrial model data components following FAIR (Findable, Accessible, Interoperable, Reusable) principles. The guidelines recommend archiving model inputs and testing data used in final simulation runs along with associated codes, workflow scripts, and metadata in public repositories. Researchers should consider archiving model outputs if they are within the storage limits of the repository. We also provide considerations for how to bundle files into different data publications with citable digital object identifiers. Finally, we identify repository features and tools that would enable storage and reuse of model data. Given the diversity of DOE terrestrial models, these guidelines are transferable to other model types and will enable efficient reuse of simulation data for purposes such as model intercomparisons, initialization, benchmarking, synthesis, and comparisons with field observations.

Published
2022

5. Multi-hypothesis comparison of Farquhar and Collatz photosynthesis models reveals the unexpected influence of empirical assumptions at leaf and global scales.

Author

Walker, Anthony P, Johnson, Abbey L, Rogers, Alistair, Anderson, Jeremiah, Bridges, Robert A, Fisher, Rosie A, Lu, Dan, Ricciuto, Daniel M, Serbin, Shawn P, and Ye, Ming

Subjects
carbon assimilation, high-resolution A-Ci curve, multi-hypothesis modelling, photosynthesis, process sensitivity analysis, terrestrial biosphere model, Ecology, Environmental Sciences, Biological Sciences
Abstract

Mechanistic photosynthesis models are at the heart of terrestrial biosphere models (TBMs) simulating the daily, monthly, annual and decadal rhythms of carbon assimilation (A). These models are founded on robust mathematical hypotheses that describe how A responds to changes in light and atmospheric CO2 concentration. Two predominant photosynthesis models are in common usage: Farquhar (FvCB) and Collatz (CBGB). However, a detailed quantitative comparison of these two models has never been undertaken. In this study, we unify the FvCB and CBGB models to a common parameter set and use novel multi-hypothesis methods (that account for both hypothesis and parameter variability) for process-level sensitivity analysis. These models represent three key biological processes: carboxylation, electron transport, triose phosphate use (TPU) and an additional model process: limiting-rate selection. Each of the four processes comprises 1-3 alternative hypotheses giving 12 possible individual models with a total of 14 parameters. To broaden inference, TBM simulations were run and novel, high-resolution photosynthesis measurements were made. We show that parameters associated with carboxylation are the most influential parameters but also reveal the surprising and marked dominance of the limiting-rate selection process (accounting for 57% of the variation in A vs. 22% for carboxylation). The limiting-rate selection assumption proposed by CBGB smooths the transition between limiting rates and always reduces A below the minimum of all potentially limiting rates, by up to 25%, effectively imposing a fourth limitation on A. Evaluation of the CBGB smoothing function in three TBMs demonstrated a reduction in global A by 4%-10%, equivalent to 50%-160% of current annual fossil fuel emissions. This analysis reveals a surprising and previously unquantified influence of a process that has been integral to many TBMs for decades, highlighting the value of multi-hypothesis methods.

Published
2021

7. Mechanistic Modeling of Microtopographic Impacts on CO2 and CH4 Fluxes in an Alaskan Tundra Ecosystem Using the CLM‐Microbe Model

Author

Wang, Yihui, Yuan, Fengming, Yuan, Fenghui, Gu, Baohua, Hahn, Melanie S, Torn, Margaret S, Ricciuto, Daniel M, Kumar, Jitendra, He, Liyuan, Zona, Donatella, Lipson, David A, Wagner, Robert, Oechel, Walter C, Wullschleger, Stan D, Thornton, Peter E, and Xu, Xiaofeng

Subjects
Climate Action, Arctic tundra, CH4 flux, microtopographic, sensitivity analysis, net carbon exchange, Atmospheric Sciences
Abstract

Spatial heterogeneities in soil hydrology have been confirmed as a key control on CO2 and CH4 fluxes in the Arctic tundra ecosystem. In this study, we applied a mechanistic ecosystem model, CLM-Microbe, to examine the microtopographic impacts on CO2 and CH4 fluxes across seven landscape types in Utqiaġvik, Alaska: trough, low-centered polygon (LCP) center, LCP transition, LCP rim, high-centered polygon (HCP) center, HCP transition, and HCP rim. We first validated the CLM-Microbe model against static-chamber measured CO2 and CH4 fluxes in 2013 for three landscape types: trough, LCP center, and LCP rim. Model application showed that low-elevation and thus wetter landscape types (i.e., trough, transitions, and LCP center) had larger CH4 emissions rates with greater seasonal variations than high-elevation and drier landscape types (rims and HCP center). Sensitivity analysis indicated that substrate availability for methanogenesis (acetate, CO2 + H2) is the most important factor determining CH4 emission, and vegetation physiological properties largely affect the net ecosystem carbon exchange and ecosystem respiration in Arctic tundra ecosystems. Modeled CH4 emissions for different microtopographic features were upscaled to the eddy covariance (EC) domain with an area-weighted approach before validation against EC-measured CH4 fluxes. The model underestimated the EC-measured CH4 flux by 20% and 25% at daily and hourly time steps, suggesting the importance of the time step in reporting CH4 flux. The strong microtopographic impacts on CO2 and CH4 fluxes call for a model-data integration framework for better understanding and predicting carbon flux in the highly heterogeneous Arctic landscape.

Published
2019

8. The Community Land Model Version 5: Description of New Features, Benchmarking, and Impact of Forcing Uncertainty

Author

Lawrence, David M, Fisher, Rosie A, Koven, Charles D, Oleson, Keith W, Swenson, Sean C, Bonan, Gordon, Collier, Nathan, Ghimire, Bardan, van Kampenhout, Leo, Kennedy, Daniel, Kluzek, Erik, Lawrence, Peter J, Li, Fang, Li, Hongyi, Lombardozzi, Danica, Riley, William J, Sacks, William J, Shi, Mingjie, Vertenstein, Mariana, Wieder, William R, Xu, Chonggang, Ali, Ashehad A, Badger, Andrew M, Bisht, Gautam, van den Broeke, Michiel, Brunke, Michael A, Burns, Sean P, Buzan, Jonathan, Clark, Martyn, Craig, Anthony, Dahlin, Kyla, Drewniak, Beth, Fisher, Joshua B, Flanner, Mark, Fox, Andrew M, Gentine, Pierre, Hoffman, Forrest, Keppel‐Aleks, Gretchen, Knox, Ryan, Kumar, Sanjiv, Lenaerts, Jan, Leung, L Ruby, Lipscomb, William H, Lu, Yaqiong, Pandey, Ashutosh, Pelletier, Jon D, Perket, Justin, Randerson, James T, Ricciuto, Daniel M, Sanderson, Benjamin M, Slater, Andrew, Subin, Zachary M, Tang, Jinyun, Thomas, R Quinn, Martin, Maria Val, and Zeng, Xubin

Subjects
Earth Sciences, Atmospheric Sciences, Geoinformatics, Climate Action, global land model, Earth System Modeling, carbon and nitrogen cycling, hydrology, benchmarking, Atmospheric sciences
Abstract

The Community Land Model (CLM) is the land component of the Community Earth System Model (CESM) and is used in several global and regional modeling systems. In this paper, we introduce model developments included in CLM version 5 (CLM5), which is the default land component for CESM2. We assess an ensemble of simulations, including prescribed and prognostic vegetation state, multiple forcing data sets, and CLM4, CLM4.5, and CLM5, against a range of metrics including from the International Land Model Benchmarking (ILAMBv2) package. CLM5 includes new and updated processes and parameterizations: (1) dynamic land units, (2) updated parameterizations and structure for hydrology and snow (spatially explicit soil depth, dry surface layer, revised groundwater scheme, revised canopy interception and canopy snow processes, updated fresh snow density, simple firn model, and Model for Scale Adaptive River Transport), (3) plant hydraulics and hydraulic redistribution, (4) revised nitrogen cycling (flexible leaf stoichiometry, leaf N optimization for photosynthesis, and carbon costs for plant nitrogen uptake), (5) global crop model with six crop types and time-evolving irrigated areas and fertilization rates, (6) updated urban building energy, (7) carbon isotopes, and (8) updated stomatal physiology. New optional features include demographically structured dynamic vegetation model (Functionally Assembled Terrestrial Ecosystem Simulator), ozone damage to plants, and fire trace gas emissions coupling to the atmosphere. Conclusive establishment of improvement or degradation of individual variables or metrics is challenged by forcing uncertainty, parametric uncertainty, and model structural complexity, but the multivariate metrics presented here suggest a general broad improvement from CLM4 to CLM5.

Published
2019

10. Identification of key parameters controlling demographically structured vegetation dynamics in a land surface model: CLM4.5(FATES)

Author

Massoud, Elias C, Xu, Chonggang, Fisher, Rosie A, Knox, Ryan G, Walker, Anthony P, Serbin, Shawn P, Christoffersen, Bradley O, Holm, Jennifer A, Kueppers, Lara M, Ricciuto, Daniel M, Wei, Liang, Johnson, Daniel J, Chambers, Jeffrey Q, Koven, Charlie D, McDowell, Nate G, and Vrugt, Jasper A

Subjects
Earth Sciences, Earth sciences
Abstract

Vegetation plays an important role in regulating global carbon cycles and is a key component of the Earth system models (ESMs) that aim to project Earth's future climate. In the last decade, the vegetation component within ESMs has witnessed great progress from simple "big-leaf" approaches to demographically structured approaches, which have a better representation of plant size, canopy structure, and disturbances. These demographically structured vegetation models typically have a large number of input parameters, and sensitivity analysis is needed to quantify the impact of each parameter on the model outputs for a better understanding of model behavior. In this study, we conducted a comprehensive sensitivity analysis to diagnose the Community Land Model coupled to the Functionally Assembled Terrestrial Simulator, or CLM4.5(FATES). Specifically, we quantified the first- and second-order sensitivities of the model parameters to outputs that represent simulated growth and mortality as well as carbon fluxes and stocks for a tropical site with an extent of 1×1°. While the photosynthetic capacity parameter (Vc;max25) is found to be important for simulated carbon stocks and fluxes, we also show the importance of carbon storage and allometry parameters, which determine survival and growth strategies within the model. The parameter sensitivity changes with different sizes of trees and climate conditions. The results of this study highlight the importance of understanding the dynamics of the next generation of demographically enabled vegetation models within ESMs to improve model parameterization and structure for better model fidelity.

Published
2019

13. Thermal, water, and land cover factors led to contrasting urban and rural vegetation resilience to extreme hot months

Author

Wang, Yaoping, primary, Mao, Jiafu, additional, Brelsford, Christa M, additional, Ricciuto, Daniel M, additional, Yuan, Fengming, additional, Shi, Xiaoying, additional, Rastogi, Deeksha, additional, Mayes, Melanie M, additional, Kao, Shih-Chieh, additional, Warren, Jeffrey M, additional, Griffiths, Natalie A, additional, Cheng, Xinghua, additional, Weston, David J, additional, Zhou, Yuyu, additional, Gu, Lianhong, additional, and Thornton, Peter E, additional

Published
2024
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18. Response of Water Use Efficiency to Global Environmental Change Based on Output From Terrestrial Biosphere Models

Author

Zhou, Sha, Yu, Bofu, Schwalm, Christopher R, Ciais, Philippe, Zhang, Yao, Fisher, Joshua B, Michalak, Anna M, Wang, Weile, Poulter, Benjamin, Huntzinger, Deborah N, Niu, Shuli, Mao, Jiafu, Jain, Atul, Ricciuto, Daniel M, Shi, Xiaoying, Ito, Akihiko, Wei, Yaxing, Huang, Yuefei, and Wang, Guangqian

Subjects
Climate Action, atmospheric CO2, attribution, trend, interannual variability, physiology, structure, Atmospheric Sciences, Geochemistry, Oceanography, Meteorology & Atmospheric Sciences
Abstract

Water use efficiency (WUE), defined as the ratio of gross primary productivity and evapotranspiration at the ecosystem scale, is a critical variable linking the carbon and water cycles. Incorporating a dependency on vapor pressure deficit, apparent underlying WUE (uWUE) provides a better indicator of how terrestrial ecosystems respond to environmental changes than other WUE formulations. Here we used 20th century simulations from four terrestrial biosphere models to develop a novel variance decomposition method. With this method, we attributed variations in apparent uWUE to both the trend and interannual variation of environmental drivers. The secular increase in atmospheric CO2 explained a clear majority of total variation (66 ± 32%: mean ± one standard deviation), followed by positive trends in nitrogen deposition and climate, as well as a negative trend in land use change. In contrast, interannual variation was mostly driven by interannual climate variability. To analyze the mechanism of the CO2 effect, we partitioned the apparent uWUE into the transpiration ratio (transpiration over evapotranspiration) and potential uWUE. The relative increase in potential uWUE parallels that of CO2, but this direct CO2 effect was offset by 20 ± 4% by changes in ecosystem structure, that is, leaf area index for different vegetation types. However, the decrease in transpiration due to stomatal closure with rising CO2 was reduced by 84% by an increase in leaf area index, resulting in small changes in the transpiration ratio. CO2 concentration thus plays a dominant role in driving apparent uWUE variations over time, but its role differs for the two constituent components: potential uWUE and transpiration.

Published
2017

19. Evaluating the Community Land Model (CLM4.5) at a coniferous forest site in northwestern United States using flux and carbon-isotope measurements

Author

Duarte, Henrique F, Raczka, Brett M, Ricciuto, Daniel M, Lin, John C, Koven, Charles D, Thornton, Peter E, Bowling, David R, Lai, Chun-Ta, Bible, Kenneth J, and Ehleringer, James R

Subjects
Environmental Sciences, Biological Sciences, Ecology, Climate Action, Earth Sciences, Meteorology & Atmospheric Sciences, Physical geography and environmental geoscience, Environmental management
Abstract

Droughts in the western United States are expected to intensify with climate change. Thus, an adequate representation of ecosystem response to water stress in land models is critical for predicting carbon dynamics. The goal of this study was to evaluate the performance of the Community Land Model (CLM) version 4.5 against observations at an old-growth coniferous forest site in the Pacific Northwest region of the United States (Wind River AmeriFlux site), characterized by a Mediterranean climate that subjects trees to water stress each summer. CLM was driven by site-observed meteorology and calibrated primarily using parameter values observed at the site or at similar stands in the region. Key model adjustments included parameters controlling specific leaf area and stomatal conductance. Default values of these parameters led to significant underestimation of gross primary production, overestimation of evapotranspiration, and consequently overestimation of photosynthetic 13C discrimination, reflected in reduced 13°C 12°C ratios of carbon fluxes and pools. Adjustments in soil hydraulic parameters within CLM were also critical, preventing significant underestimation of soil water content and unrealistic soil moisture stress during summer. After calibration, CLM was able to simulate energy and carbon fluxes, leaf area index, biomass stocks, and carbon isotope ratios of carbon fluxes and pools in reasonable agreement with site observations. Overall, the calibrated CLM was able to simulate the observed response of canopy conductance to atmospheric vapor pressure deficit (VPD) and soil water content, reasonably capturing the impact of water stress on ecosystem functioning. Both simulations and observations indicate that stomatal response from water stress at Wind River was primarily driven by VPD and not soil moisture. The calibration of the Ball-Berry stomatal conductance slope (mbb) at Wind River aligned with findings from recent CLM experiments at sites characterized by the same plant functional type (needleleaf evergreen temperate forest), despite significant differences in stand composition and age and climatology, suggesting that CLM could benefit from a revised mbb value of 6, rather than the default value of 9, for this plant functional type. Conversely, Wind River required a unique calibration of the hydrology submodel to simulate soil moisture, suggesting that the default hydrology has a more limited applicability. This study demonstrates that carbon isotope data can be used to constrain stomatal conductance and intrinsic water use efficiency in CLM, as an alternative to eddy covariance flux measurements. It also demonstrates that carbon isotopes can expose structural weaknesses in the model and provide a key constraint that may guide future model development.

Published
2017

23. Quantifying wildfire drivers and predictability in boreal peatlands using a two-step error-correcting machine learning framework in TeFire v1.0.

Author

Tang, Rongyun, Jin, Mingzhou, Mao, Jiafu, Ricciuto, Daniel M., Chen, Anping, and Zhang, Yulong

Subjects
FOREST fires, MACHINE learning, WILDFIRE prevention, RECEIVER operating characteristic curves, CLIMATE extremes, PEATLANDS
Abstract

Wildfires are becoming an increasing challenge to the sustainability of boreal peatland (BP) ecosystems and can alter the stability of boreal carbon storage. However, predicting the occurrence of rare and extreme BP fires proves to be challenging, and gaining a quantitative understanding of the factors, both natural and anthropogenic, inducing BP fires remains elusive. Here, we quantified the predictability of BP fires and their primary controlling factors from 1997 to 2015 using a two-step correcting machine learning (ML) framework that combines multiple ML classifiers, regression models, and an error-correcting technique. We found that (1) the adopted oversampling algorithm effectively addressed the unbalanced data and improved the recall rate by 26.88 %–48.62 % when using multiple datasets, and the error-correcting technique tackled the overestimation of fire sizes during fire seasons; (2) nonparametric models outperformed parametric models in predicting fire occurrences, and the random forest machine learning model performed the best, with the area under the receiver operating characteristic curve ranging from 0.83 to 0.93 across multiple fire datasets; and (3) four sets of factor-control simulations consistently indicated the dominant role of temperature, air dryness, and climate extreme (i.e., frost) for boreal peatland fires, overriding the effects of precipitation, wind speed, and human activities. Our findings demonstrate the efficiency and accuracy of ML techniques in predicting rare and extreme fire events and disentangle the primary factors determining BP fires, which are critical for predicting future fire risks under climate change. [ABSTRACT FROM AUTHOR]

Published
2024
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25. Nutrient Dynamics in a Coupled Terrestrial Biosphere and Land Model (ELM-FATES)

Author

Knox, Ryan G, primary, Koven, Charles D., additional, Riley, William J., additional, Walker, Anthony P., additional, Wright, Stuart Joseph, additional, Holm, Jennifer A., additional, Wei, Xinyuan, additional, Fisher, Rosie A., additional, Zhu, Qing, additional, Tang, Jinyun, additional, Ricciuto, Daniel M., additional, Shuman, Jacquelyn, additional, Yang, Xiaojuan, additional, Kueppers, Lara M, additional, and Chambers, Jeffrey, additional

Published
2023
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26. Modeling Perennial Bioenergy Crops in the E3SM Land Model (ELMv2)

Author

Sinha, Eva, Calvin, Katherine V., Bond-Lamberty, Ben, Drewniak, Beth A., Ricciuto, Daniel M., Sargsyan, Khachik, Cheng, Yanyan, Bernacchi, Carl, Moore, Caitlin E., Sinha, Eva, Calvin, Katherine V., Bond-Lamberty, Ben, Drewniak, Beth A., Ricciuto, Daniel M., Sargsyan, Khachik, Cheng, Yanyan, Bernacchi, Carl, and Moore, Caitlin E.

Abstract

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.

Published
2023

35. Upscaling Methane Flux From Plot Level to Eddy Covariance Tower Domains in Five Alaskan Tundra Ecosystems

Author

Wang, Yihui, primary, Yuan, Fengming, additional, Arndt, Kyle A., additional, Liu, Jianzhao, additional, He, Liyuan, additional, Zuo, Yunjiang, additional, Zona, Donatella, additional, Lipson, David A., additional, Oechel, Walter C., additional, Ricciuto, Daniel M., additional, Wullschleger, Stan D., additional, Thornton, Peter E., additional, and Xu, Xiaofeng, additional

Published
2022
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38. Increasing Functional Diversity in a Global Land Surface Model Illustrates Uncertainties Related to Parameter Simplification

Author

Butler, Ethan E., Wythers, Kirk R., Flores-Moreno, Habacuc, Ricciuto, Daniel M., Datta, Abhirup, Banerjee, Arindam, Atkin, Owen K., Kattge, Jens, Thornton, Peter E., Anand, Madhur, Burrascano, Sabina, Byun, Chaeho, Cornelissen, J.H.C., Forey, Estelle, Jansen, Steven, Kramer, Koen, Minden, Vanessa, Reich, Peter B., Butler, Ethan E., Wythers, Kirk R., Flores-Moreno, Habacuc, Ricciuto, Daniel M., Datta, Abhirup, Banerjee, Arindam, Atkin, Owen K., Kattge, Jens, Thornton, Peter E., Anand, Madhur, Burrascano, Sabina, Byun, Chaeho, Cornelissen, J.H.C., Forey, Estelle, Jansen, Steven, Kramer, Koen, Minden, Vanessa, and Reich, Peter B.

Abstract

Simulations of the land surface carbon cycle typically compress functional diversity into a small set of plant functional types (PFT), with parameters defined by the average value of measurements of functional traits. In most earth system models, all wild plant life is represented by between five and 14 PFTs and a typical grid cell (≈100 × 100 km) may contain a single PFT. Model logic applied to this coarse representation of ecological functional diversity provides a reasonable proxy for the carbon cycle, but does not capture the non-linear influence of functional traits on productivity. Here we show through simulations using the Energy Exascale Land Surface Model in 15 diverse terrestrial landscapes, that better accounting for functional diversity markedly alters predicted total carbon uptake. The shift in carbon uptake is as great as 30% and 10% in boreal and tropical regions, respectively, when compared to a single PFT parameterized with the trait means. The traits that best predict gross primary production vary based on vegetation phenology, which broadly determines where traits fall within the global distribution. Carbon uptake is more closely associated with specific leaf area for evergreen PFTs and the leaf carbon to nitrogen ratio in deciduous PFTs.

Published
2022

39. Evaluating alternative ebullition models for predicting peatland methane emission and its pathways via data–model fusion

Author

Ma, Shuang; https://orcid.org/0000-0002-6494-724X, Jiang, Lifen, Wilson, Rachel M, Chanton, Jeff P, Bridgham, Scott, Niu, Shuli, Iversen, Colleen M, Malhotra, Avni; https://orcid.org/0000-0002-7850-6402, Jiang, Jiang, Lu, Xingjie; https://orcid.org/0000-0003-3732-1978, Huang, Yuanyuan; https://orcid.org/0000-0003-4202-8071, Keller, Jason, Xu, Xiaofeng; https://orcid.org/0000-0002-6553-6514, Ricciuto, Daniel M; https://orcid.org/0000-0002-3668-3021, Hanson, Paul J; https://orcid.org/0000-0001-7293-3561, Luo, Yiqi, Ma, Shuang; https://orcid.org/0000-0002-6494-724X, Jiang, Lifen, Wilson, Rachel M, Chanton, Jeff P, Bridgham, Scott, Niu, Shuli, Iversen, Colleen M, Malhotra, Avni; https://orcid.org/0000-0002-7850-6402, Jiang, Jiang, Lu, Xingjie; https://orcid.org/0000-0003-3732-1978, Huang, Yuanyuan; https://orcid.org/0000-0003-4202-8071, Keller, Jason, Xu, Xiaofeng; https://orcid.org/0000-0002-6553-6514, Ricciuto, Daniel M; https://orcid.org/0000-0002-3668-3021, Hanson, Paul J; https://orcid.org/0000-0001-7293-3561, and Luo, Yiqi

Abstract

Understanding the dynamics of peatland methane (CH4) emissions and quantifying sources of uncertainty in estimating peatland CH4 emissions are critical for mitigating climate change. The relative contributions of CH4 emission pathways through ebullition, plant-mediated transport, and diffusion, together with their different transport rates and vulnerability to oxidation, determine the quantity of CH4 to be oxidized before leaving the soil. Notwithstanding their importance, the relative contributions of the emission pathways are highly uncertain. In particular, the ebullition process is more uncertain and can lead to large uncertainties in modeled CH4 emissions. To improve model simulations of CH4 emission and its pathways, we evaluated two model structures: (1) the ebullition bubble growth volume threshold approach (EBG) and (2) the modified ebullition concentration threshold approach (ECT) using CH4 flux and concentration data collected in a peatland in northern Minnesota, USA. When model parameters were constrained using observed CH4 fluxes, the CH4 emissions simulated by the EBG approach (RMSE = 0.53) had a better agreement with observations than the ECT approach (RMSE = 0.61). Further, the EBG approach simulated a smaller contribution from ebullition but more frequent ebullition events than the ECT approach. The EBG approach yielded greatly improved simulations of pore water CH4 concentrations, especially in the deep soil layers, compared to the ECT approach. When constraining the EBG model with both CH4 flux and concentration data in model–data fusion, uncertainty of the modeled CH4 concentration profiles was reduced by 78 % to 86 % in comparison to constraints based on CH4 flux data alone. The improved model capability was attributed to the well-constrained parameters regulating the CH4 production and emission pathways. Our results suggest that the EBG modeling approach better characterizes CH4 emission and underlying mechanisms. Moreover, to achieve the best

Published
2022

40. Evaluating alternative ebullition models for predicting peatland methane emission and its pathways via data–model fusion

Author

Ma, Shuang, primary, Jiang, Lifen, additional, Wilson, Rachel M., additional, Chanton, Jeff P., additional, Bridgham, Scott, additional, Niu, Shuli, additional, Iversen, Colleen M., additional, Malhotra, Avni, additional, Jiang, Jiang, additional, Lu, Xingjie, additional, Huang, Yuanyuan, additional, Keller, Jason, additional, Xu, Xiaofeng, additional, Ricciuto, Daniel M., additional, Hanson, Paul J., additional, and Luo, Yiqi, additional

Published
2022
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41. Coupling of Tree Growth and Photosynthetic Carbon Uptake Across Six North American Forests

Author

Teets, Aaron, primary, Moore, David J. P., additional, Alexander, M. Ross, additional, Blanken, Peter D., additional, Bohrer, Gil, additional, Burns, Sean P., additional, Carbone, Mariah S., additional, Ducey, Mark J., additional, Fraver, Shawn, additional, Gough, Christopher M., additional, Hollinger, David Y., additional, Koch, George, additional, Kolb, Thomas, additional, Munger, J. William, additional, Novick, Kimberly A., additional, Ollinger, Scott V., additional, Ouimette, Andrew P., additional, Pederson, Neil, additional, Ricciuto, Daniel M., additional, Seyednasrollah, Bijan, additional, Vogel, Christoph S., additional, and Richardson, Andrew D., additional

Published
2022
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42. Increasing Functional Diversity in a Global Land Surface Model Illustrates Uncertainties Related to Parameter Simplification

Author

Butler, Ethan E., primary, Wythers, Kirk R., additional, Flores‐Moreno, Habacuc, additional, Ricciuto, Daniel M., additional, Datta, Abhirup, additional, Banerjee, Arindam, additional, Atkin, Owen K., additional, Kattge, Jens, additional, Thornton, Peter E., additional, Anand, Madhur, additional, Burrascano, Sabina, additional, Byun, Chaeho, additional, Cornelissen, J. H. C., additional, Forey, Estelle, additional, Jansen, Steven, additional, Kramer, Koen, additional, Minden, Vanessa, additional, and Reich, Peter B., additional

Published
2022
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43. Evaluating alternative ebullition models for predicting peatland methane emission and its pathways via data–model fusion

Author

Ma, Shuang, Jiang, Lifen, Wilson, Rachel M, Chanton, Jeff P, Bridgham, Scott, Niu, Shuli, Iversen, Colleen M, Malhotra, Avni, Jiang, Jiang, Lu, Xingjie, Huang, Yuanyuan, Keller, Jason, Xu, Xiaofeng, Ricciuto, Daniel M, Hanson, Paul J, Luo, Yiqi, University of Zurich, and Luo, Yiqi

Subjects
10122 Institute of Geography, 1105 Ecology, Evolution, Behavior and Systematics, Surface Processes, Ecology, Behavior and Systematics, Evolution, 1904 Earth-Surface Processes, wetland methane, data-model fusion, emission pathways, belowground CH4 concentration profile, CH4 emission, climate change, Earth, 910 Geography & travel, Ecology, Evolution, Behavior and Systematics, Earth-Surface Processes
Abstract

Understanding the dynamics of peatland methane (CH4) emissions and quantifying sources of uncertainty in estimating peatland CH4 emissions are critical for mitigating climate change. The relative contributions of CH4 emission pathways through ebullition, plant-mediated transport, and diffusion, together with their different transport rates and vulnerability to oxidation, determine the quantity of CH4 to be oxidized before leaving the soil. Notwithstanding their importance, the relative contributions of the emission pathways are highly uncertain. In particular, the ebullition process is more uncertain and can lead to large uncertainties in modeled CH4 emissions. To improve model simulations of CH4 emission and its pathways, we evaluated two model structures: (1) the ebullition bubble growth volume threshold approach (EBG) and (2) the modified ebullition concentration threshold approach (ECT) using CH4 flux and concentration data collected in a peatland in northern Minnesota, USA. When model parameters were constrained using observed CH4 fluxes, the CH4 emissions simulated by the EBG approach (RMSE = 0.53) had a better agreement with observations than the ECT approach (RMSE = 0.61). Further, the EBG approach simulated a smaller contribution from ebullition but more frequent ebullition events than the ECT approach. The EBG approach yielded greatly improved simulations of pore water CH4 concentrations, especially in the deep soil layers, compared to the ECT approach. When constraining the EBG model with both CH4 flux and concentration data in model–data fusion, uncertainty of the modeled CH4 concentration profiles was reduced by 78 % to 86 % in comparison to constraints based on CH4 flux data alone. The improved model capability was attributed to the well-constrained parameters regulating the CH4 production and emission pathways. Our results suggest that the EBG modeling approach better characterizes CH4 emission and underlying mechanisms. Moreover, to achieve the best model results both CH4 flux and concentration data are required to constrain model parameterization.

Published
2022
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44. Evaluating alternative ebullition models for predicting peatland methane emission and its pathways via data-model fusion

Author

Ma, Shuang, primary, Jiang, Lifen, additional, Wilson, Rachel M., additional, Chanton, Jeff P., additional, Bridgham, Scott, additional, Niu, Shuli, additional, Iversen, Colleen M., additional, Malhotra, Avni, additional, Jiang, Jiang, additional, Lu, Xingjie, additional, Huang, Yuanyuan, additional, Keller, Jason, additional, Xu, Xiaofeng, additional, Ricciuto, Daniel M., additional, Hanson, Paul J., additional, and Luo, Yiqi, additional

Published
2021
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45. Supplementary material to "Evaluating alternative ebullition models for predicting peatland methane emission and its pathways via data-model fusion"

Author

Ma, Shuang, primary, Jiang, Lifen, additional, Wilson, Rachel M., additional, Chanton, Jeff P., additional, Bridgham, Scott, additional, Niu, Shuli, additional, Iversen, Colleen M., additional, Malhotra, Avni, additional, Jiang, Jiang, additional, Lu, Xingjie, additional, Huang, Yuanyuan, additional, Keller, Jason, additional, Xu, Xiaofeng, additional, Ricciuto, Daniel M., additional, Hanson, Paul J., additional, and Luo, Yiqi, additional

Published
2021
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46. 2016 International Land Model Benchmarking (ILAMB) Workshop Report

Author

Hoffman, Forrest M, Koven, Charles D, Keppel-Aleks, Gretchen, Lawrence, David M, Riley, William J, Randerson, James T, Ahlstrom, Anders, Abramowitz, Gabriel, Baldocchi, Dennis D, Best, Martin J, Bond-Lamberty, Ben, De Kauwe, Martin G, Denning, A. Scott, Desai, Ankur, Eyring, Veronika, Fisher, Joshua B, Fisher, Rosie A, Gleckler, Peter J, Huang, Maoyi, Hugelius, Gustaf, Jain, Atul K, Kiang, Nancy Y, Kim, Hyungjun, Koster, Randal D, Kumar, Sujay V, Li, Hongyi, Luo, Yiqi, Mao, Jiafu, McDowell, Nathan G, Mishra, Umakant, Moorcroft, Paul R, Pau, George S. H, Ricciuto, Daniel M, Schaefer, Kevin, Schwalm, Christopher R, Serbin, Shawn P, Shevliakova, Elena, Slater, Andrew G, Tang, Jinyun, Williams, Mathew, Xia, Jianyang, Xu, Chonggang, Joseph, Renu, and Koch, Dorothy

Subjects
Meteorology And Climatology
Abstract

As earth system models (ESMs) become increasingly complex, there is a growing need for comprehensive and multi-faceted evaluation of model projections. To advance understanding of terrestrial biogeochemical processes and their interactions with hydrology and climate under conditions of increasing atmospheric carbon dioxide, new analysis methods are required that use observations to constrain model predictions, inform model development, and identify needed measurements and field experiments. Better representations of biogeochemistryclimate feedbacks and ecosystem processes in these models are essential for reducing the acknowledged substantial uncertainties in 21st century climate change projections.

Published
2016
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48. 2016 International Land Model Benchmarking (ILAMB) Workshop Report

Author

Hoffman, Forrest M., primary, Koven, Charles D., additional, Keppel-Aleks, Gretchen, additional, Lawrence, David M., additional, Riley, William J., additional, Randerson, James T., additional, Ahlström, Anders, additional, Abramowitz, Gabriel, additional, Baldocchi, Dennis D., additional, Best, Martin J., additional, Bond-Lamberty, Benjamin, additional, De Kauwe, Martin G., additional, Denning, A. Scott, additional, Desai, Ankur R., additional, Eyring, Veronika, additional, Fisher, Joshua B., additional, Fisher, Rosie A., additional, Gleckler, Peter J., additional, Huang, Maoyi, additional, Hugelius, Gustaf, additional, Jain, Atul K., additional, Kiang, Nancy Y., additional, Kim, Hyungjum, additional, Koster, Randal D., additional, Kumar, Sujay V., additional, Li, Hongyi, additional, Luo, Yiqi, additional, Mao, Jiafu, additional, McDowell, Nathan G., additional, Mishra, Umakant, additional, Moorcroft, Paul R., additional, Pau, George S.H., additional, Ricciuto, Daniel M., additional, Schaefer, Kevin, additional, Schwalm, Christopher R., additional, Serbin, Shawn P., additional, Shevliakova, Elena, additional, Slater, Andrew G., additional, Tang, Jinyun, additional, Williams, Mathew, additional, Xia, Jianyang, additional, Xu, Chonggang, additional, Joseph, Renu, additional, and Koch, Dorothy, additional

Published
2017
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