Your search keyword '"Villalobos, Yohanna"' showing total 13 results

1. RECCAP2 Future Component: Consistency and Potential for Regional Assessment to Constrain Global Projections

Author

Jones, Chris D., primary, Ziehn, Tilo, additional, Anand, Jatin, additional, Bastos, Ana, additional, Burke, Eleanor, additional, Canadell, Josep G., additional, Cardoso, Manoel, additional, Ernst, Yolandi, additional, Jain, Atul K., additional, Jeong, Sujong, additional, Keller, Elizabeth D., additional, Kondo, Masayuki, additional, Lauerwald, Ronny, additional, Lin, Tzu‐Shun, additional, Murray‐Tortarolo, Guillermo, additional, Nabuurs, Gert‐Jan, additional, O’Sullivan, Mike, additional, Poulter, Ben, additional, Qin, Xiaoyu, additional, von Randow, Celso, additional, Sanches, Marcos, additional, Schepaschenko, Dmitry, additional, Shvidenko, Anatoly, additional, Smallman, T. Luke, additional, Tian, Hanqin, additional, Villalobos, Yohanna, additional, Wang, Xuhui, additional, and Yun, Jeongmin, additional

Published

2023

2. A comprehensive assessment of anthropogenic and natural sources and sinks of Australasia's carbon budget

Author

Villalobos, Yohanna, Canadell, Josep G., Keller, Elizabeth D., Briggs, Peter R., Bukosa, Beata, Giltrap, Donna L., Harman, Ian, Hilton, Timothy W., Kirschbaum, Miko U. F., Lauerwald, Ronny, Liang, Liyin L., Maavara, Taylor, Mikaloff-Fletcher, Sara E., Rayner, Peter J., Resplandy, Laure, Rosentreter, Judith, Metz, Eva M., Serrano, Oscar, Smith, Benjamin, Villalobos, Yohanna, Canadell, Josep G., Keller, Elizabeth D., Briggs, Peter R., Bukosa, Beata, Giltrap, Donna L., Harman, Ian, Hilton, Timothy W., Kirschbaum, Miko U. F., Lauerwald, Ronny, Liang, Liyin L., Maavara, Taylor, Mikaloff-Fletcher, Sara E., Rayner, Peter J., Resplandy, Laure, Rosentreter, Judith, Metz, Eva M., Serrano, Oscar, and Smith, Benjamin

Abstract

Regional carbon budget assessments attribute and track changes in carbon sources and sinks and support the development and monitoring the efficacy of climate policies. We present a comprehensive assessment of the natural and anthropogenic carbon (C-CO2) fluxes for Australasia as a whole, as well as for Australia and New Zealand individually, for the period from 2010 to 2019, using two approaches: bottom-up methods that integrate flux estimates from land-surface models, data-driven models, and inventory estimates; and top-down atmospheric inversions based on satellite and in situ measurements. Our bottom-up decadal assessment suggests that Australasia's net carbon balance was close to carbon neutral (−0.4 ± 77.0 TgC yr−1). However, substantial uncertainties remain in this estimate, primarily driven by the large spread between our regional terrestrial biosphere simulations and predictions from global ecosystem models. Within Australasia, Australia was a net source of 38.2 ± 75.8 TgC yr−1, and New Zealand was a net CO2 sink of −38.6 ± 13.4 TgC yr−1. The top-down approach using atmospheric CO2 inversions indicates that fluxes derived from the latest satellite retrievals are consistent within the range of uncertainties with Australia's bottom-up budget. For New Zealand, the best agreement was found with a national scale flux inversion estimate based on in situ measurements, which provide better constrained of fluxes than satellite flux inversions. This study marks an important step toward a more comprehensive understanding of the net CO2 balance in both countries, facilitating the improvement of carbon accounting approaches and strategies to reduce emissions.

Published

2023

3. RECCAP2 Future Component : Consistency and Potential for Regional Assessment to Constrain Global Projections

Author

Jones, Chris D., Ziehn, Tilo, Anand, Jatin, Bastos, Ana, Burke, Eleanor, Canadell, Josep G., Cardoso, Manoel, Ernst, Yolandi, Jain, Atul K., Jeong, Sujong, Keller, Elizabeth D., Kondo, Masayuki, Lauerwald, Ronny, Lin, Tzu Shun, Murray-Tortarolo, Guillermo, Nabuurs, Gert Jan, O’Sullivan, Mike, Poulter, Ben, Qin, Xiaoyu, von Randow, Celso, Sanches, Marcos, Schepaschenko, Dmitry, Shvidenko, Anatoly, Smallman, Luke, Tian, Hanqin, Villalobos, Yohanna, Wang, Xuhui, Yun, Jeongmin, Jones, Chris D., Ziehn, Tilo, Anand, Jatin, Bastos, Ana, Burke, Eleanor, Canadell, Josep G., Cardoso, Manoel, Ernst, Yolandi, Jain, Atul K., Jeong, Sujong, Keller, Elizabeth D., Kondo, Masayuki, Lauerwald, Ronny, Lin, Tzu Shun, Murray-Tortarolo, Guillermo, Nabuurs, Gert Jan, O’Sullivan, Mike, Poulter, Ben, Qin, Xiaoyu, von Randow, Celso, Sanches, Marcos, Schepaschenko, Dmitry, Shvidenko, Anatoly, Smallman, Luke, Tian, Hanqin, Villalobos, Yohanna, Wang, Xuhui, and Yun, Jeongmin

Abstract

Projections of future carbon sinks and stocks are important because they show how the world's ecosystems will respond to elevated CO2 and changes in climate. Moreover, they are crucial to inform policy decisions around emissions reductions to stay within the global warming levels identified by the Paris Agreement. However, Earth System Models from the 6th Coupled Model Intercomparison Project (CMIP6) show substantial spread in future projections—especially of the terrestrial carbon cycle, leading to a large uncertainty in our knowledge of any remaining carbon budget (RCB). Here we evaluate the global terrestrial carbon cycle projections on a region-by-region basis and compare the global models with regional assessments made by the REgional Carbon Cycle Assessment and Processes, Phase 2 activity. Results show that for each region, the CMIP6 multi-model mean is generally consistent with the regional assessment, but substantial cross-model spread exists. Nonetheless, all models perform well in some regions and no region is without some well performing models. This gives confidence that the CMIP6 models can be used to look at future changes in carbon stocks on a regional basis with appropriate model assessment and benchmarking. We find that most regions of the world remain cumulative net sources of CO2 between now and 2100 when considering the balance of fossil-fuels and natural sinks, even under aggressive mitigation scenarios. This paper identifies strengths and weaknesses for each model in terms of its performance over a particular region including how process representation might impact those results and sets the agenda for applying stricter constraints at regional scales to reduce the uncertainty in global projections.

Published

2023

4. Interannual variability in the Australian carbon cycle over 2015–2019, based on assimilation of Orbiting Carbon Observatory-2 (OCO-2) satellite data

Author

Villalobos, Yohanna, primary, Rayner, Peter J., additional, Silver, Jeremy D., additional, Thomas, Steven, additional, Haverd, Vanessa, additional, Knauer, Jürgen, additional, Loh, Zoë M., additional, Deutscher, Nicholas M., additional, Griffith, David W. T., additional, and Pollard, David F., additional

Published

2022

5. Was Australia a sink or source of CO2 in 2015? Data assimilation using OCO-2 satellite measurements

Author

Villalobos, Yohanna, primary, Rayner, Peter J., additional, Silver, Jeremy D., additional, Thomas, Steven, additional, Haverd, Vanessa, additional, Knauer, Jürgen, additional, Loh, Zoë M., additional, Deutscher, Nicholas M., additional, Griffith, David W. T., additional, and Pollard, David F., additional

Published

2021

6. Was Australia a sink or source of CO2 in 2015? Data assimilation using OCO-2 satellite measurements

Author

Villalobos, Yohanna, Rayner, Peter J., Silver, Jeremy D., Thomas, Steven, Haverd, Vanessa, Knauer, Jürgen, Loh, Zoë M., Deutscher, Nicholas M., Griffith, David W. T., and Pollard, David F.

Abstract

In this study, we present the assimilation of data from the Orbiting Carbon Observatory-2 (OCO-2) (land nadir and glint data, version 9) to estimate the Australian carbon surface fluxes for the year 2015. To perform this estimation, we used both a regional-scale atmospheric transport–dispersion model and a four-dimensional variational assimilation scheme. Our results suggest that Australia was a carbon sink of −0.41 ± 0.08 PgC yr−1 compared to the prior estimate 0.09 ± 0.20 PgC yr−1 (excluding fossil fuel emissions). Most of the carbon uptake occurred in northern Australia over the savanna ecotype and in the western region over areas with sparse vegetation. Analysis of the enhanced vegetation index (EVI) suggests that the majority of the carbon uptake over the savanna ecosystem was due to an increase of vegetation productivity (positive EVI anomalies) amplified by an anomalous increase of rainfall in summer. Further from this, a slight increase of carbon uptake in Western Australia over areas with sparse vegetation (the largest ecosystem in Australia) was noted due to increased land productivity in the area caused by positive rainfall anomalies. The stronger carbon uptake estimate in this ecosystem was partially due to the land surface model (CABLE-BIOS3) underestimating the gross primary productivity of the ecosystem. To evaluate the accuracy of our carbon flux estimates from OCO-2 retrievals, we compare our posterior concentration fields against the column-averaged carbon retrievals from the Total Carbon Column Observing Network (TCCON) and ground-based in situ monitoring sites located around our domain. The validation analysis against TCCON shows that our system is able to reduce bias mainly in the summer season. Comparison with surface in situ observations was less successful, particularly over oceanic monitoring sites that are strongly affected by oceanic fluxes and subject to less freedom by the inversion. For stations located far from the coast, the comparison with in situ data was more variable, suggesting difficulties matching the column-integrated and surface data by the inversion, most likely linked to model vertical transport. Comparison of our fluxes against the OCO-2 model intercomparison (MIP) was encouraging. The annual carbon uptake estimated by our inversion falls within the ensemble of the OCO-2 MIP global inversions and presents a similar seasonal pattern.

Published

2021

7. The potential of Orbiting Carbon Observatory-2 data to reduce the uncertainties in CO2 surface fluxes over Australia using a variational assimilation scheme

Author

Villalobos, Yohanna, Rayner, Peter, Thomas, Steven, and Silver, Jeremy

Abstract

This paper addresses the question of how much uncertainties in CO2 fluxes over Australia can be reduced by assimilation of total-column carbon dioxide retrievals from the Orbiting Carbon Observatory-2 (OCO-2) satellite instrument. We apply a four-dimensional variational data assimilation system, based around the Community Multiscale Air Quality (CMAQ) transport-dispersion model. We ran a series of observing system simulation experiments to estimate posterior error statistics of optimized monthly-mean CO2 fluxes in Australia. Our assimilations were run with a horizontal grid resolution of 81 km using OCO-2 data for 2015. Based on four representative months, we find that the integrated flux uncertainty for Australia is reduced from 0.52 to 0.13 Pg C yr−1. Uncertainty reductions of up to 90 % were found at grid-point resolution over productive ecosystems. Our sensitivity experiments show that the choice of the correlation structure in the prior error covariance plays a large role in distributing information from the observations. We also found that biases in the observations would significantly impact the inverted fluxes and could contaminate the final results of the inversion. Biases in prior fluxes are generally removed by the inversion system. Biases in the boundary conditions have a significant impact on retrieved fluxes, but this can be mitigated by including boundary conditions in our retrieved parameters. In general, results from our idealized experiments suggest that flux inversions at this unusually fine scale will yield useful information on the carbon cycle at continental and finer scales.

Published

2020

8. The potential of OCO-2 data to reduce the uncertainties in CO2 surface fluxes over Australia using a variational assimilation scheme

Author

Villalobos, Yohanna, Rayner, Peter, Thomas, Steven, and Silver, Jeremy

Abstract

This paper addresses the question of how much uncertainties in CO2 fluxes over Australia can be reduced by assimilation of total-column carbon dioxide retrievals from the Orbiting Carbon Observatory-2 (OCO-2) satellite instrument. We apply a four-dimensional variational data assimilation system, based around the Community Multiscale Air Quality (CMAQ) transport-dispersion model. We ran a series of observing system simulation experiments to estimate posterior error statistics of optimized monthly mean CO2 fluxes in Australia. Our assimilations were run with a horizontal grid resolution of 81 km using OCO-2 data for 2015. We found that on average, the total Australia flux uncertainty was reduced by up to 40 % using only OCO-2 nadir measurements. Using both nadir and glint satellite measurements produces uncertainty reductions up to 80 %, which represents 0.55 PgC y−1 for the whole continent. Uncertainty reductions were found to be greatest in the more productive regions of Australia. The choice of the correlation structure in the prior error covariance was found to play a large role in distributing information from the observations. Overall the results suggest that flux inversions at this unusually fine scale will yield useful information on the Australian carbon cycle.

Published

2019

9. The potential of Orbiting Carbon Observatory-2 data to reduce the uncertainties in CO2 surface fluxes over Australia using a variational assimilation scheme

Author

Villalobos, Yohanna, primary, Rayner, Peter, additional, Thomas, Steven, additional, and Silver, Jeremy, additional

Published

2020

10. Interannual variability in the Australian carbon cycle over 2015-2019, based on assimilation of OCO-2 satellite data.

Author

Villalobos, Yohanna, Rayner, Peter J., Silver, Jeremy D., Thomas, Steven, Haverd, Vanessa, Knauer, Jürgen, Loh, Zoë M., Deutscher, Nicholas M., Griffith, David W.T., and Pollard, David F.

Abstract

In this study, we employ a regional inverse modelling approach to estimate monthly carbon fluxes over the Australian continent for 2015-2019 using the assimilation of the total column-averaged mole fractions of carbon dioxide from the Orbiting Carbon Observatory-2 (OCO-2, version 9). Subsequently, we study the carbon cycle variations and relate their fluctuations to anomalies in vegetation productivity and climate drivers. Our five-year regional carbon flux inversion suggests that Australia was a carbon sink averaging -0.46 ± 0.08 PgC yr-1 (excluding fossil fuel emissions), largely influenced by a strong carbon uptake (-1.04 PgC yr-1) recorded in 2016. Australia semi-arid ecosystems, such as sparsely vegetated regions (in central Australia) and savanna (in northern Australia), were the main contributors to the carbon uptake in 2016. These regions showed relatively high vegetation productivity, high rainfall and low temperature in 2016. In contrast to the large carbon sink found in 2016, the large carbon outgassing recorded in 2019 coincides with an unprecedented deficit of rainfall and higher than average temperature across Australia. Comparison of the posterior column average CO2 concentration against the Total Carbon Column Observing Networks (TCCON) and in situ measurements offers limited insight into the fluxes assimilated with OCO-2. However, the lack of these monitoring stations across Australia, mainly over ecosystems such as the savanna and areas with sparse vegetation, impedes us from providing strong conclusions. Comparison of our flux inversion to the ensemble mean carbon flux of the OCO-2 Multi-model Intercomparison Project (MIP) (2015-2018) agrees with our findings, and their results also suggest that Australia was a strong carbon sink in 2016 (-0.73 ± 0.41 PgC yr-1). The analysis of the variability of the nine models that participate in the OCO-2 MIP also aligns with our findings, and it gives us the confidence to say that changes in rainfall and temperature drive most of the carbon flux variability across Australia. [ABSTRACT FROM AUTHOR]

Published

2022

11. Was Australia a sink or source of CO2 in 2015? Data assimilation using OCO-2 satellite measurements.

Author

Villalobos, Yohanna, Rayner, Peter J., Silver, Jeremy D., Thomas, Steven, Haverd, Vanessa, Knauer, Jürgen, Loh, Zoë M., Deutscher, Nicholas M., Griffith, David W.T., and Pollard, David F.

Abstract

In this study, we present the assimilation of data from the Orbiting Carbon Observatory-2 (OCO-2) to estimate the Australian CO2 surface fluxes for the year 2015. We used a regional-scale atmospheric transport-dispersion model and a four-dimensional variational assimilation scheme. Our results suggest that Australia was a carbon sink of -0.3 ± 0.09 PgC y-1 compared to the prior estimate 0.09 ± 0.17 PgC y-1 (excluding fossil fuel emissions). Most of the uptake occurred over northern savannas, the Mediterranean ecotype in southern Australia and the sparsely vegetated ecotype in central Australia. Our results suggest that the majority of the carbon uptake over Mediterranean was associated with positive EVI anomalies (relative to 2000-2014). However, the stronger posterior carbon uptake estimated over savanna and sparsely vegetated ecosystem was due primarily to underestimation of the gross primary productivity by the land surface model (CABLE-BIOS3 model). To evaluate the accuracy of our posterior flux estimates, we compare our posterior CO2 concentration simulations against the column-averaged carbon retrievals from the Total Carbon Column Observing Network (TCCON) and ground-based in-situ monitoring sites located around our Australia domain. In general, the performance of our posterior concentration compared well with TCCON observations, except when TCCON concentrations were dominated by ocean fluxes which were tightly constrained to their prior values. Comparisons with in-situ measurements also show encouraging results though with similar difficulties for coastal stations. For stations located far from the coast, the comparison with in situ data was more variable, suggesting difficulties to match the column-integrated and surface data by the inversion, most likely linked to model vertical transport. [ABSTRACT FROM AUTHOR]

Published

2021

12. The potential of Orbiting Carbon Observatory-2 data to reduce the uncertainties in CO2 surface fluxes over Australia using a variational assimilation scheme.

Author

Villalobos, Yohanna, Rayner, Peter, Thomas, Steven, and Silver, Jeremy

Abstract

This paper addresses the question of how much uncertainties in CO2 fluxes over Australia can be reduced by assimilation of total-column carbon dioxide retrievals from the Orbiting Carbon Observatory-2 (OCO-2) satellite instrument. We apply a four-dimensional variational data assimilation system, based around the Community Multiscale Air Quality (CMAQ) transport-dispersion model. We ran a series of observing system simulation experiments to estimate posterior error statistics of optimized monthly-mean CO2 fluxes in Australia. Our assimilations were run with a horizontal grid resolution of 81 km using OCO-2 data for 2015. Based on four representative months, we find that the integrated flux uncertainty for Australia is reduced from 0.52 to 0.13 Pg C yr−1. Uncertainty reductions of up to 90 % were found at grid-point resolution over productive ecosystems. Our sensitivity experiments show that the choice of the correlation structure in the prior error covariance plays a large role in distributing information from the observations. We also found that biases in the observations would significantly impact the inverted fluxes and could contaminate the final results of the inversion. Biases in prior fluxes are generally removed by the inversion system. Biases in the boundary conditions have a significant impact on retrieved fluxes, but this can be mitigated by including boundary conditions in our retrieved parameters. In general, results from our idealized experiments suggest that flux inversions at this unusually fine scale will yield useful information on the carbon cycle at continental and finer scales. [ABSTRACT FROM AUTHOR]

Published

2020

13. The potential of OCO-2 data to reduce the uncertainties in CO2 surface fluxes over Australia using a variational assimilation scheme.

Author

Villalobos, Yohanna, Rayner, Peter, Thomas, Steven, and Silver, Jeremy

Abstract

This paper addresses the question of how much uncertainties in CO2 fluxes over Australia can be reduced by assimilation of total-column carbon dioxide retrievals from the Orbiting Carbon Observatory-2 (OCO-2) satellite instrument. We apply a four-dimensional variational data assimilation system, based around the Community Multiscale Air Quality (CMAQ) transport-dispersion model. We ran a series of observing system simulation experiments to estimate posterior error statistics of optimized monthly mean CO2 fluxes in Australia. Our assimilations were run with a horizontal grid resolution of 81 km using OCO-2 data for 2015. We found that on average, the total Australia flux uncertainty was reduced by up to 40 % using only OCO-2 nadir measurements. Using both nadir and glint satellite measurements produces uncertainty reductions up to 80 %, which represents 0.55 PgC y−1 for the whole continent. Uncertainty reductions were found to be greatest in the more productive regions of Australia. The choice of the correlation structure in the prior error covariance was found to play a large role in distributing information from the observations. Overall the results suggest that flux inversions at this unusually fine scale will yield useful information on the Australian carbon cycle. [ABSTRACT FROM AUTHOR]

Published

2019