Search

Your search keyword '"Arora, Vivek K."' showing total 509 results
Start Over Author "Arora, Vivek K."
509 results on '"Arora, Vivek K."'

2. The key role of forest disturbance in reconciling estimates of the northern carbon sink

Author

O’Sullivan, Michael, Sitch, Stephen, Friedlingstein, Pierre, Luijkx, Ingrid T., Peters, Wouter, Rosan, Thais M., Arneth, Almut, Arora, Vivek K., Chandra, Naveen, Chevallier, Frédéric, Ciais, Philippe, Falk, Stefanie, Feng, Liang, Gasser, Thomas, Houghton, Richard A., Jain, Atul K., Kato, Etsushi, Kennedy, Daniel, Knauer, Jürgen, McGrath, Matthew J., Niwa, Yosuke, Palmer, Paul I., Patra, Prabir K., Pongratz, Julia, Poulter, Benjamin, Rödenbeck, Christian, Schwingshackl, Clemens, Sun, Qing, Tian, Hanqin, Walker, Anthony P., Yang, Dongxu, Yuan, Wenping, Yue, Xu, and Zaehle, Sönke

Published
2024
Full Text
View/download PDF

4. Respiration driven CO2 pulses dominate Australia's flux variability

Author

Metz, Eva-Marie, Vardag, Sanam N., Basu, Sourish, Jung, Martin, Ahrens, Bernhard, El-Madany, Tarek, Sitch, Stephen, Arora, Vivek K., Briggs, Peter R., Friedlingstein, Pierre, Goll, Daniel S., Jain, Atul K., Kato, Etsushi, Lombardozzi, Danica, Nabel, Julia E. M. S., Poulter, Benjamin, Séférian, Roland, Tian, Hanqin, Wiltshire, Andrew, Yuan, Wenping, Yue, Xu, Zaehle, Sönke, Deutscher, Nicholas M., Griffith, David W. T., and Butz, André

Subjects
Physics - Atmospheric and Oceanic Physics
Abstract

The Australian continent contributes substantially to the year-to-year variability of the global terrestrial carbon dioxide (CO2) sink. However, the scarcity of in-situ observations in remote areas prevents deciphering the processes that force the CO2 flux variability. Here, examining atmospheric CO2 measurements from satellites in the period 2009-2018, we find recurrent end-of-dry-season CO2 pulses over the Australian continent. These pulses largely control the year-to-year variability of Australia's CO2 balance, due to 2-3 times higher seasonal variations compared to previous top-down inversions and bottom-up estimates. The CO2 pulses occur shortly after the onset of rainfall and are driven by enhanced soil respiration preceding photosynthetic uptake in Australia's semi-arid regions. The suggested continental-scale relevance of soil rewetting processes has large implications for our understanding and modelling of global climate-carbon cycle feedbacks., Comment: 28 pages (including supplementary materials), 3 main figures, 7 supplementary figures; v2 changes: Last name of first author changed

Published
2022
Full Text
View/download PDF

5. Multi-century dynamics of the climate and carbon cycle under both high and net negative emissions scenarios

Author

Koven, Charles D, Arora, Vivek K, Cadule, Patricia, Fisher, Rosie A, Jones, Chris D, Lawrence, David M, Lewis, Jared, Lindsay, Keith, Mathesius, Sabine, Meinshausen, Malte, Mills, Michael, Nicholls, Zebedee, Sanderson, Benjamin M, Séférian, Roland, Swart, Neil C, Wieder, William R, and Zickfeld, Kirsten

Subjects
Earth Sciences, Atmospheric Sciences, Climate Action, Oceanography, Physical Geography and Environmental Geoscience, Climate change science, Geoinformatics
Abstract

Future climate projections from Earth system models (ESMs) typically focus on the timescale of this century. We use a set of five ESMs and one Earth system model of intermediate complexity (EMIC) to explore the dynamics of the Earth's climate and carbon cycles under contrasting emissions trajectories beyond this century to the year 2300. The trajectories include a very-high-emissions, unmitigated fossil-fuel-driven scenario, as well as a mitigation scenario that diverges from the first scenario after 2040 and features an "overshoot", followed by a decrease in atmospheric CO2 concentrations by means of large net negative CO2 emissions. In both scenarios and for all models considered here, the terrestrial system switches from being a net sink to either a neutral state or a net source of carbon, though for different reasons and centered in different geographic regions, depending on both the model and the scenario. The ocean carbon system remains a sink, albeit weakened by carbon cycle feedbacks, in all models under the high-emissions scenario and switches from sink to source in the overshoot scenario. The global mean temperature anomaly is generally proportional to cumulative carbon emissions, with a deviation from proportionality in the overshoot scenario that is governed by the zero emissions commitment. Additionally, 23rd century warming continues after the cessation of carbon emissions in several models in the high-emissions scenario and in one model in the overshoot scenario. While ocean carbon cycle responses qualitatively agree in both globally integrated and zonal mean dynamics in both scenarios, the land models qualitatively disagree in zonal mean dynamics, in the relative roles of vegetation and soil in driving C fluxes, in the response of the sink to CO2, and in the timing of the sink-source transition, particularly in the high-emissions scenario. The lack of agreement among land models on the mechanisms and geographic patterns of carbon cycle feedbacks, alongside the potential for lagged physical climate dynamics to cause warming long after CO2 concentrations have stabilized, points to the possibility of surprises in the climate system beyond the 21st century time horizon, even under relatively mitigated global warming scenarios, which should be taken into consideration when setting global climate policy. Copyright:

Published
2022

6. Diagnosing destabilization risk in global land carbon sinks

Author

Fernández-Martínez, Marcos, Peñuelas, Josep, Chevallier, Frederic, Ciais, Philippe, Obersteiner, Michael, Rödenbeck, Christian, Sardans, Jordi, Vicca, Sara, Yang, Hui, Sitch, Stephen, Friedlingstein, Pierre, Arora, Vivek K., Goll, Daniel S., Jain, Atul K., Lombardozzi, Danica L., McGuire, Patrick C., and Janssens, Ivan A.

Published
2023
Full Text
View/download PDF

8. Carbon–concentration and carbon–climate feedbacks in CMIP6 models and their comparison to CMIP5 models

Author

Arora, Vivek K, Katavouta, Anna, Williams, Richard G, Jones, Chris D, Brovkin, Victor, Friedlingstein, Pierre, Schwinger, Jörg, Bopp, Laurent, Boucher, Olivier, Cadule, Patricia, Chamberlain, Matthew A, Christian, James R, Delire, Christine, Fisher, Rosie A, Hajima, Tomohiro, Ilyina, Tatiana, Joetzjer, Emilie, Kawamiya, Michio, Koven, Charles D, Krasting, John P, Law, Rachel M, Lawrence, David M, Lenton, Andrew, Lindsay, Keith, Pongratz, Julia, Raddatz, Thomas, Séférian, Roland, Tachiiri, Kaoru, Tjiputra, Jerry F, Wiltshire, Andy, Wu, Tongwen, and Ziehn, Tilo

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

Results from the fully and biogeochemically coupled simulations in which CO2 increases at a rate of 1%yr-1 (1pctCO2) from its preindustrial value are analyzed to quantify the magnitude of carbon-concentration and carbon-climate feedback parameters which measure the response of ocean and terrestrial carbon pools to changes in atmospheric CO2 concentration and the resulting change in global climate, respectively. The results are based on 11 comprehensive Earth system models from the most recent uncertain over land than over ocean as has been seen in existing studies. These values and their spread from 11 CMIP6 models have not changed significantly compared to CMIP5 models. The absolute values of feedback parameters are lower for land with models that include a representation of nitrogen cycle. The transient climate response to cumulative emissions (TCRE) from the 11 CMIP6 models considered here is 1.77±0.37 ° C EgC-1 and is similar to that found in CMIP5 models (1.63±0.48 °C EgC-1) but with somewhat reduced model spread. The expressions for feedback parameters based on the fully and biogeochemically coupled configurations of the 1pctCO2 simulation are simplified when the small temperature change in the biogeochemically coupled simulation is ignored. Decomposition of the terms of these simplified expressions for the feedback parameters is used to gain insight into the reasons for differing responses among ocean and land carbon cycle models.

Published
2020

9. The effect of climate change on the simulated streamflow of six Canadian rivers based on the CanRCM4 regional climate model.

Author

Arora, Vivek K., Lima, Aranildo, and Shrestha, Rajesh

Subjects
CLIMATE change models, GLOBAL warming, ATMOSPHERIC models, WATERSHEDS, STREAMFLOW
Abstract

The effect of climate change on the hydro-climatology, particularly the streamflow, of six major Canadian rivers (Mackenzie, Yukon, Columbia, Fraser, Nelson, and St. Lawrence) is investigated by analyzing results from the historical and future simulations (RCP 4.5 and 8.5 scenarios) performed with the Canadian regional climate model (CanRCM4). Streamflow is obtained by routing runoff using river networks at 0.5° resolution. Of these six rivers, the Nelson and St. Lawrence are the most regulated. As a result, the streamflow at the mouth of these rivers shows very little seasonality. Additionally, the Great Lakes significantly dampen the seasonality of streamflow for the St. Lawrence River. Mean annual precipitation (P), evaporation (E), runoff (R), and temperature increase for all six river basins in both future scenarios considered here, and the increases are higher for the more fossil-fuel-intensive RCP 8.5 scenario. The only exception is the Nelson River basin, for which the simulated runoff increases are extremely small. The hydrological response of these rivers to climate warming is characterized by their existing climate states. The northerly Mackenzie and Yukon River basins show a decrease in the evaporation ratio (E/P) and an increase in the runoff ratio (R/P) since the increase in precipitation is more than enough to offset the increase in evaporation associated with increasing temperature. For the southerly Fraser and Columbia River basins, the E/P ratio increases despite an increase in precipitation, and the R/P ratio decreases due to an already milder climate in the northwestern Pacific region. The seasonality of simulated monthly streamflow is also more affected for the southerly Fraser and Columbia rivers than for the northerly Mackenzie and Yukon rivers as snow amounts decrease and snowmelt occurs earlier. The streamflow seasonality for the Mackenzie and Yukon rivers is still dominated by snowmelt at the end of the century, even in the RCP 8.5 scenario. The simulated streamflow regime for the Fraser and Columbia rivers shifts from a snow-dominated to a hybrid or rainfall-dominated regime towards the end of this century in the RCP 8.5 scenario. While we expect the climate change signal from CanRCM4 to be higher than that from other climate models, owing to the higher-than-average climate sensitivity of its parent global climate model, the results presented here provide a consistent overview of hydrological changes across six major Canadian river basins in response to a warmer climate. [ABSTRACT FROM AUTHOR]

Published
2025
Full Text
View/download PDF

11. Impact of the 2015/2016 El Niño on the terrestrial carbon cycle constrained by bottom-up and top-down approaches

Author

Bastos, Ana, Friedlingstein, Pierre, Sitch, Stephen, Chen, Chi, Mialon, Arnaud, Wigneron, Jean-Pierre, Arora, Vivek K, Briggs, Peter R, Canadell, Josep G, Ciais, Philippe, Chevallier, Frédéric, Cheng, Lei, Delire, Christine, Haverd, Vanessa, Jain, Atul K, Joos, Fortunat, Kato, Etsushi, Lienert, Sebastian, Lombardozzi, Danica, Melton, Joe R, Myneni, Ranga, Nabel, Julia EMS, Pongratz, Julia, Poulter, Benjamin, Rödenbeck, Christian, Séférian, Roland, Tian, Hanqin, van Eck, Christel, Viovy, Nicolas, Vuichard, Nicolas, Walker, Anthony P, Wiltshire, Andy, Yang, Jia, Zaehle, Sönke, Zeng, Ning, and Zhu, Dan

Subjects
Climate Action, Atmosphere, Carbon Cycle, Carbon Sequestration, Ecosystem, El Nino-Southern Oscillation, Models, Theoretical, carbon cycle, El Nino/Southern Oscillation, land-surface models, atmospheric inversions, El Niño/Southern Oscillation, Biological Sciences, Medical and Health Sciences, Evolutionary Biology
Abstract

Evaluating the response of the land carbon sink to the anomalies in temperature and drought imposed by El Niño events provides insights into the present-day carbon cycle and its climate-driven variability. It is also a necessary step to build confidence in terrestrial ecosystems models' response to the warming and drying stresses expected in the future over many continents, and particularly in the tropics. Here we present an in-depth analysis of the response of the terrestrial carbon cycle to the 2015/2016 El Niño that imposed extreme warming and dry conditions in the tropics and other sensitive regions. First, we provide a synthesis of the spatio-temporal evolution of anomalies in net land-atmosphere CO2 fluxes estimated by two in situ measurements based on atmospheric inversions and 16 land-surface models (LSMs) from TRENDYv6. Simulated changes in ecosystem productivity, decomposition rates and fire emissions are also investigated. Inversions and LSMs generally agree on the decrease and subsequent recovery of the land sink in response to the onset, peak and demise of El Niño conditions and point to the decreased strength of the land carbon sink: by 0.4-0.7 PgC yr-1 (inversions) and by 1.0 PgC yr-1 (LSMs) during 2015/2016. LSM simulations indicate that a decrease in productivity, rather than increase in respiration, dominated the net biome productivity anomalies in response to ENSO throughout the tropics, mainly associated with prolonged drought conditions.This article is part of a discussion meeting issue 'The impact of the 2015/2016 El Niño on the terrestrial tropical carbon cycle: patterns, mechanisms and implications'.

Published
2018

12. Process-oriented analysis of dominant sources of uncertainty in the land carbon sink

Author

O’Sullivan, Michael, Friedlingstein, Pierre, Sitch, Stephen, Anthoni, Peter, Arneth, Almut, Arora, Vivek K., Bastrikov, Vladislav, Delire, Christine, Goll, Daniel S., Jain, Atul, Kato, Etsushi, Kennedy, Daniel, Knauer, Jürgen, Lienert, Sebastian, Lombardozzi, Danica, McGuire, Patrick C., Melton, Joe R., Nabel, Julia E. M. S., Pongratz, Julia, Poulter, Benjamin, Séférian, Roland, Tian, Hanqin, Vuichard, Nicolas, Walker, Anthony P., Yuan, Wenping, Yue, Xu, and Zaehle, Sönke

Published
2022
Full Text
View/download PDF

13. Global wetland contribution to 2000–2012 atmospheric methane growth rate dynamics

Author

Poulter, Benjamin, Bousquet, Philippe, Canadell, Josep G, Ciais, Philippe, Peregon, Anna, Saunois, Marielle, Arora, Vivek K, Beerling, David J, Brovkin, Victor, Jones, Chris D, Joos, Fortunat, Gedney, Nicola, Ito, Akihito, Kleinen, Thomas, Koven, Charles D, McDonald, Kyle, Melton, Joe R, Peng, Changhui, Peng, Shushi, Prigent, Catherine, Schroeder, Ronny, Riley, William J, Saito, Makoto, Spahni, Renato, Tian, Hanqin, Taylor, Lyla, Viovy, Nicolas, Wilton, David, Wiltshire, Andy, Xu, Xiyan, Zhang, Bowen, Zhang, Zhen, and Zhu, Qiuan

Subjects
Earth Sciences, Climate Change Impacts and Adaptation, Atmospheric Sciences, Environmental Sciences, Climate Action, methanogenesis, wetlands, methane, Meteorology & Atmospheric Sciences
Abstract

Increasing atmospheric methane (CH4) concentrations have contributed to approximately 20% of anthropogenic climate change. Despite the importance of CH4 as a greenhouse gas, its atmospheric growth rate and dynamics over the past two decades, which include a stabilization period (1999-2006), followed by renewed growth starting in 2007, remain poorly understood. We provide an updated estimate of CH4 emissions from wetlands, the largest natural global CH4 source, for 2000-2012 using an ensemble of biogeochemical models constrained with remote sensing surface inundation and inventory-based wetland area data. Between 2000-2012, boreal wetland CH4 emissions increased by 1.2 Tg yr-1 (-0.2-3.5 Tg yr-1), tropical emissions decreased by 0.9 Tg yr-1 (-3.2-1.1 Tg yr-1), yet globally, emissions remained unchanged at 184 22 Tg yr-1. Changing air temperature was responsible for increasing high-latitude emissions whereas declines in low-latitude wetland area decreased tropical emissions; both dynamics are consistent with features of predicted centennial-scale climate change impacts on wetland CH4 emissions. Despite uncertainties in wetland area mapping, our study shows that global wetland CH4 emissions have not contributed significantly to the period of renewed atmospheric CH4 growth, and is consistent with findings from studies that indicate some combination of increasing fossil fuel and agriculture-related CH4 emissions, and a decrease in the atmospheric oxidative sink.

Published
2017

14. Management of Muscle-Invasive Bladder Cancer During a Pandemic: Impact of Treatment Delay on Survival Outcomes for Patients Treated With Definitive Concurrent Chemoradiotherapy

Author

Fischer-Valuck, Benjamin W., Michalski, Jeff M., Harton, Joanna G., Birtle, Alison, Christodouleas, John P., Efstathiou, Jason A., Arora, Vivek K., Kim, Eric H., Knoche, Eric M., Pachynski, Russell K., Picus, Joel, Rao, Yuan James, Reimers, Melissa, Roth, Bruce J., Sargos, Paul, Smith, Zachary L., Zaghloul, Mohamed S., Gay, Hiram A., Patel, Sagar A., and Baumann, Brian C.

Published
2021
Full Text
View/download PDF

15. Advances in Land Surface Modelling

Author

Blyth, Eleanor M., Arora, Vivek K., Clark, Douglas B., Dadson, Simon J., De Kauwe, Martin G., Lawrence, David M., Melton, Joe R., Pongratz, Julia, Turton, Rachael H., Yoshimura, Kei, and Yuan, Hua

Published
2021
Full Text
View/download PDF

16. Estimation of Canada's methane emissions: inverse modelling analysis using the Environment and Climate Change Canada (ECCC) measurement network.

Author

Ishizawa, Misa, Chan, Douglas, Worthy, Doug, Chan, Elton, Vogel, Felix, Melton, Joe R., and Arora, Vivek K.

Subjects
GLOBAL warming, FOSSIL fuel industries, NATURAL gas production, CLIMATE change mitigation, ATMOSPHERIC temperature
Abstract

Canada has major sources of atmospheric methane (CH4), with the world's second-largest boreal wetland and the world's fourth-largest natural gas production. However, Canada's CH4 emissions remain uncertain among estimates. Better quantification and characterization of Canada's CH4 emissions are critical for climate mitigation strategies. To improve our understanding of Canada's CH4 emissions, we performed an ensemble regional inversion for 2007–2017 constrained with the Environment and Climate Change Canada (ECCC) surface measurement network. The decadal CH4 estimates show no significant trend, unlike some studies that reported long-term trends. The total CH4 estimate is 17.4 (15.3–19.5) TgCH4yr-1 , partitioned into natural and anthropogenic sources at 10.8 (7.5–13.2) and 6.6 (6.2–7.8) TgCH4yr-1 , respectively. The estimated anthropogenic emission is higher than inventories, mainly in western Canada (with the fossil fuel industry). Furthermore, the results reveal notable spatiotemporal characteristics. First, the modelled differences in atmospheric CH4 among the sites show improvement after inversion when compared to observations, implying the CH4 observation differences could help in verifying the inversion results. Second, the seasonal variations show slow onset and a late-summer maximum, indicating wetland CH4 flux has hysteretic dependence on air temperature. Third, the boreal winter natural CH4 emissions, usually treated as negligible, appear quantifiable (≥ 20 % of annual emissions). Understanding winter emission is important for climate prediction, as the winter in Canada is warming faster than the summer. Fourth, the inter-annual variability in estimated CH4 emissions is positively correlated with summer air temperature anomalies. This could enhance Canada's natural CH4 emission in the warming climate. [ABSTRACT FROM AUTHOR]

Published
2024
Full Text
View/download PDF

17. Variability and quasi-decadal changes in the methane budget over the period 2000–2012

Author

Saunois, Marielle, Bousquet, Philippe, Poulter, Ben, Peregon, Anna, Ciais, Philippe, Canadell, Josep G, Dlugokencky, Edward J, Etiope, Giuseppe, Bastviken, David, Houweling, Sander, Janssens-Maenhout, Greet, Tubiello, Francesco N, Castaldi, Simona, Jackson, Robert B, Alexe, Mihai, Arora, Vivek K, Beerling, David J, Bergamaschi, Peter, Blake, Donald R, Brailsford, Gordon, Bruhwiler, Lori, Crevoisier, Cyril, Crill, Patrick, Covey, Kristofer, Frankenberg, Christian, Gedney, Nicola, Höglund-Isaksson, Lena, Ishizawa, Misa, Ito, Akihiko, Joos, Fortunat, Kim, Heon-Sook, Kleinen, Thomas, Krummel, Paul, Lamarque, Jean-François, Langenfelds, Ray, Locatelli, Robin, Machida, Toshinobu, Maksyutov, Shamil, Melton, Joe R, Morino, Isamu, Naik, Vaishali, O'Doherty, Simon, Parmentier, Frans-Jan W, Patra, Prabir K, Peng, Changhui, Peng, Shushi, Peters, Glen P, Pison, Isabelle, Prinn, Ronald, Ramonet, Michel, Riley, William J, Saito, Makoto, Santini, Monia, Schroeder, Ronny, Simpson, Isobel J, Spahni, Renato, Takizawa, Atsushi, Thornton, Brett F, Tian, Hanqin, Tohjima, Yasunori, Viovy, Nicolas, Voulgarakis, Apostolos, Weiss, Ray, Wilton, David J, Wiltshire, Andy, Worthy, Doug, Wunch, Debra, Xu, Xiyan, Yoshida, Yukio, Zhang, Bowen, Zhang, Zhen, and Zhu, Qiuan

Subjects
Earth Sciences, Atmospheric Sciences, Climate Action, Astronomical and Space Sciences, Meteorology & Atmospheric Sciences, Atmospheric sciences, Climate change science
Abstract

Following the recent Global Carbon Project (GCP) synthesis of the decadal methane (CH4) budget over 2000-2012 (Saunois et al., 2016), we analyse here the same dataset with a focus on quasi-decadal and inter-annual variability in CH4 emissions. The GCP dataset integrates results from top-down studies (exploiting atmospheric observations within an atmospheric inverse-modelling framework) and bottom-up models (including process-based models for estimating land surface emissions and atmospheric chemistry), inventories of anthropogenic emissions, and data-driven approaches. The annual global methane emissions from top-down studies, which by construction match the observed methane growth rate within their uncertainties, all show an increase in total methane emissions over the period 2000-2012, but this increase is not linear over the 13 years. Despite differences between individual studies, the mean emission anomaly of the top-down ensemble shows no significant trend in total methane emissions over the period 2000-2006, during the plateau of atmospheric methane mole fractions, and also over the period 2008-2012, during the renewed atmospheric methane increase. However, the top-down ensemble mean produces an emission shift between 2006 and 2008, leading to 22 [16-32]Tg CH4yr-1 higher methane emissions over the period 2008-2012 compared to 2002-2006. This emission increase mostly originated from the tropics, with a smaller contribution from mid-latitudes and no significant change from boreal regions. The regional contributions remain uncertain in top-down studies. Tropical South America and South and East Asia seem to contribute the most to the emission increase in the tropics. However, these two regions have only limited atmospheric measurements and remain therefore poorly constrained. The sectorial partitioning of this emission increase between the periods 2002-2006 and 2008-2012 differs from one atmospheric inversion study to another. However, all top-down studies suggest smaller changes in fossil fuel emissions (from oil, gas, and coal industries) compared to the mean of the bottom-up inventories included in this study. This difference is partly driven by a smaller emission change in China from the top-down studies compared to the estimate in the Emission Database for Global Atmospheric Research (EDGARv4.2) inventory, which should be revised to smaller values in a near future. We apply isotopic signatures to the emission changes estimated for individual studies based on five emission sectors and find that for six individual top-down studies (out of eight) the average isotopic signature of the emission changes is not consistent with the observed change in atmospheric 13CH4. However, the partitioning in emission change derived from the ensemble mean is consistent with this isotopic constraint. At the global scale, the top-down ensemble mean suggests that the dominant contribution to the resumed atmospheric CH4 growth after 2006 comes from microbial sources (more from agriculture and waste sectors than from natural wetlands), with an uncertain but smaller contribution from fossil CH4 emissions. In addition, a decrease in biomass burning emissions (in agreement with the biomass burning emission databases) makes the balance of sources consistent with atmospheric 13CH4 observations. In most of the top-down studies included here, OH concentrations are considered constant over the years (seasonal variations but without any inter-annual variability). As a result, the methane loss (in particular through OH oxidation) varies mainly through the change in methane concentrations and not its oxidants. For these reasons, changes in the methane loss could not be properly investigated in this study, although it may play a significant role in the recent atmospheric methane changes as briefly discussed at the end of the paper.

Published
2017

18. The Global Methane Budget: 2000–2012

Author

Saunois, Marielle, Bousquet, Philippe, Poulter, Ben, Peregon, Anna, Ciais, Philippe, Canadell, Josep G, Dlugokencky, Edward J, Etiope, Giuseppe, Bastviken, David, Houweling, Sander, Janssens-Maenhout, Greet, Tubiello, Francesco N, Castaldi, Simona, Jackson, Robert B, Alexe, Mihai, Arora, Vivek K, Beerling, David J, Bergamaschi, Peter, Blake, Donald R, Brailsford, Gordon, Brovkin, Victor, Bruhwiler, Lori, Crevoisier, Cyril, Crill, Patrick, Curry, Charles, Frankenberg, Christian, Gedney, Nicola, Höglund-Isaksson, Lena, Ishizawa, Misa, Ito, Akihiko, Joos, Fortunat, Kim, Heon-Sook, Kleinen, Thomas, Krummel, Paul, Lamarque, Jean-François, Langenfelds, Ray, Locatelli, Robin, Machida, Toshinobu, Maksyutov, Shamil, McDonald, Kyle C, Marshall, Julia, Melton, Joe R, Morino, Isamu, O'Doherty, Simon, Parmentier, Frans-Jan W, Patra, Prabir K, Peng, Changhui, Peng, Shushi, Peters, Glen P, Pison, Isabelle, Prigent, Catherine, Prinn, Ronald, Ramonet, Michel, Riley, William J, Saito, Makoto, Schroeder, Ronny, Simpson, Isobel J, Spahni, Renato, Steele, Paul, Takizawa, Atsushi, Thornton, Brett F, Tian, Hanqin, Tohjima, Yasunori, Viovy, Nicolas, Voulgarakis, Apostolos, van Weele, Michiel, van der Werf, Guido, Weiss, Ray, Wiedinmyer, Christine, Wilton, David J, Wiltshire, Andy, Worthy, Doug, Wunch, Debra B, Xu, Xiyan, Yoshida, Yukio, Zhang, Bowen, Zhang, Zhen, and Zhu, Qiuan

Abstract

Abstract. The global methane (CH4) budget is becoming an increasingly important component for managing realistic pathways to mitigate climate change. This relevance, due to a shorter atmospheric lifetime and a stronger warming potential than carbon dioxide, is challenged by the still unexplained changes of atmospheric CH4 over the past decade. Emissions and concentrations of CH4 are continuing to increase making CH4 the second most important human-induced greenhouse gas after carbon dioxide. Two major difficulties in reducing uncertainties come from the large variety of diffusive CH4 sources that overlap geographically, and from the destruction of CH4 by the very short-lived hydroxyl radical (OH). To address these difficulties, we have established a consortium of multi-disciplinary scientists under the umbrella of the Global Carbon Project to synthesize and stimulate research on the methane cycle, and producing regular (~biennial) updates of the global methane budget. This consortium includes atmospheric physicists and chemists, biogeochemists of surface and marine emissions, and socio-economists who study anthropogenic emissions. Following Kirschke et al. (2013), we propose here the first version of a living review paper that integrates results of top-down studies (T-D, exploiting atmospheric observations within an atmospheric inverse-modelling framework) and bottom-up models, inventories, and data-driven approaches (B-U, including process-based models for estimating land surface emissions and atmospheric chemistry, and inventories for anthropogenic emissions, data-driven extrapolations). For the 2003–2012 decade, global methane emissions are estimated by T-D inversions at 558 Tg CH4 yr−1 (range [540–568]). About 60 % of global emissions are anthropogenic (range [50–65 %]). B-U approaches suggest larger global emissions (736 Tg CH4 yr−1 [596–884]) mostly because of larger natural emissions from individual sources such as inland waters, natural wetlands and geological sources. Considering the atmospheric constraints on the T-D budget, it is likely that some of the individual emissions reported by the B-U approaches are overestimated, leading to too large global emissions. Latitudinal data from T-D emissions indicate a predominance of tropical emissions (~64 % of the global budget,

Published
2016

19. Trends and Drivers of Terrestrial Sources and Sinks of Carbon Dioxide: An Overview of the TRENDY Project

Author

Sitch, Stephen, O’Sullivan, Michael, Robertson, Eddy, Friedlingstein, Pierre, Albergel, Clément, Anthoni, Peter, Arneth, Almut, Arora, Vivek K., Bastos, Ana, Bastrikov, Vladislav, Bellouin, Nicolas, Canadell, Josep G., Chini, Louise, Ciais, Philippe, Falk, Stefanie, Harris, Ian, Hurtt, George, Ito, Akihiko, Jain, Atul K., Jones, Matthew W., Joos, Fortunat, Kato, Etsushi, Kennedy, Daniel, Klein Goldewijk, Kees, Kluzek, Erik, Knauer, Jürgen, Lawrence, Peter J., Lombardozzi, Danica, Melton, Joe R., Nabel, Julia E.M.S., Pan, Naiqing, Peylin, Philippe, Pongratz, Julia, Poulter, Benjamin, Rosan, Thais M., Sun, Qing, Tian, Hanqin, Walker, Anthony P., Weber, Ulrich, Yuan, Wenping, Yue, Xu, Zaehle, Sönke, Sitch, Stephen, O’Sullivan, Michael, Robertson, Eddy, Friedlingstein, Pierre, Albergel, Clément, Anthoni, Peter, Arneth, Almut, Arora, Vivek K., Bastos, Ana, Bastrikov, Vladislav, Bellouin, Nicolas, Canadell, Josep G., Chini, Louise, Ciais, Philippe, Falk, Stefanie, Harris, Ian, Hurtt, George, Ito, Akihiko, Jain, Atul K., Jones, Matthew W., Joos, Fortunat, Kato, Etsushi, Kennedy, Daniel, Klein Goldewijk, Kees, Kluzek, Erik, Knauer, Jürgen, Lawrence, Peter J., Lombardozzi, Danica, Melton, Joe R., Nabel, Julia E.M.S., Pan, Naiqing, Peylin, Philippe, Pongratz, Julia, Poulter, Benjamin, Rosan, Thais M., Sun, Qing, Tian, Hanqin, Walker, Anthony P., Weber, Ulrich, Yuan, Wenping, Yue, Xu, and Zaehle, Sönke

Abstract

The terrestrial biosphere plays a major role in the global carbon cycle, and there is a recognized need for regularly updated estimates of land-atmosphere exchange at regional and global scales. An international ensemble of Dynamic Global Vegetation Models (DGVMs), known as the “Trends and drivers of the regional scale terrestrial sources and sinks of carbon dioxide” (TRENDY) project, quantifies land biophysical exchange processes and biogeochemistry cycles in support of the annual Global Carbon Budget assessments and the REgional Carbon Cycle Assessment and Processes, phase 2 project. DGVMs use a common protocol and set of driving data sets. A set of factorial simulations allows attribution of spatio-temporal changes in land surface processes to three primary global change drivers: changes in atmospheric CO2, climate change and variability, and Land Use and Land Cover Changes (LULCC). Here, we describe the TRENDY project, benchmark DGVM performance using remote-sensing and other observational data, and present results for the contemporary period. Simulation results show a large global carbon sink in natural vegetation over 2012–2021, attributed to the CO2 fertilization effect (3.8 ± 0.8 PgC/yr) and climate (−0.58 ± 0.54 PgC/yr). Forests and semi-arid ecosystems contribute approximately equally to the mean and trend in the natural land sink, and semi-arid ecosystems continue to dominate interannual variability. The natural sink is offset by net emissions from LULCC (−1.6 ± 0.5 PgC/yr), with a net land sink of 1.7 ± 0.6 PgC/yr. Despite the largest gross fluxes being in the tropics, the largest net land-atmosphere exchange is simulated in the extratropical regions.

Published
2024

20. Increased control of vegetation on global terrestrial energy fluxes

Author

Forzieri, Giovanni, Miralles, Diego G., Ciais, Philippe, Alkama, Ramdane, Ryu, Youngryel, Duveiller, Gregory, Zhang, Ke, Robertson, Eddy, Kautz, Markus, Martens, Brecht, Jiang, Chongya, Arneth, Almut, Georgievski, Goran, Li, Wei, Ceccherini, Guido, Anthoni, Peter, Lawrence, Peter, Wiltshire, Andy, Pongratz, Julia, Piao, Shilong, Sitch, Stephen, Goll, Daniel S., Arora, Vivek K., Lienert, Sebastian, Lombardozzi, Danica, Kato, Etsushi, Nabel, Julia E. M. S., Tian, Hanqin, Friedlingstein, Pierre, and Cescatti, Alessandro

Published
2020
Full Text
View/download PDF

23. The impacts of modelling prescribed vs. dynamic land cover in a high-CO2 future scenario – greening of the Arctic and Amazonian dieback.

Author

Kou-Giesbrecht, Sian, Arora, Vivek K., Seiler, Christian, and Wang, Libo

Abstract

Terrestrial biosphere models are a key tool in investigating the role played by land surface in the global climate system. However, few models simulate the geographic distribution of biomes dynamically, opting instead to prescribe them using remote sensing products. While prescribing land cover still allows for the simulation of the impacts of climate change on vegetation growth and the impacts of land use change, it prevents the simulation of climate-change-driven biome shifts, with implications for the projection of future terrestrial carbon sink. Here, we isolate the impacts of prescribed vs. dynamic land cover implementations in a terrestrial biosphere model. We first introduce a new framework for evaluating dynamic land cover (i.e., the spatial distribution of plant functional types across the land surface), which can be applied across terrestrial biosphere models alongside standard benchmarking of energy, water, and carbon cycle variables in model intercomparison projects. After validating simulated land cover, we then show that the simulated terrestrial carbon sink differs significantly between simulations with dynamic vs. prescribed land cover for a high-CO 2 future scenario. This is because of important range shifts that are only simulated when dynamic land cover is implemented: tree expansion into the Arctic and Amazonian transition from forest to grassland. In particular, the projected change in net land–atmosphere CO 2 flux at the end of the 21st century is twice as large in simulations with dynamic land cover than in simulations with prescribed land cover. Our results illustrate the importance of climate-change-driven biome shifts for projecting future terrestrial carbon sink. [ABSTRACT FROM AUTHOR]

Published
2024
Full Text
View/download PDF

26. Overcoming mutation-based resistance to antiandrogens with rational drug design.

Author

Balbas, Minna D, Evans, Michael J, Hosfield, David J, Wongvipat, John, Arora, Vivek K, Watson, Philip A, Chen, Yu, Greene, Geoffrey L, Shen, Yang, and Sawyers, Charles L

Subjects
Cell Line, Humans, Prostatic Neoplasms, Androgen Antagonists, Drug Design, Drug Resistance, Neoplasm, Mutation, Male, Molecular Dynamics Simulation, Human, Mouse, androgen receptor, drug resistance, prostate cancer, Drug Resistance, Neoplasm, Biochemistry and Cell Biology
Abstract

The second-generation antiandrogen enzalutamide was recently approved for patients with castration-resistant prostate cancer. Despite its success, the duration of response is often limited. For previous antiandrogens, one mechanism of resistance is mutation of the androgen receptor (AR). To prospectively identify AR mutations that might confer resistance to enzalutamide, we performed a reporter-based mutagenesis screen and identified a novel mutation, F876L, which converted enzalutamide into an AR agonist. Ectopic expression of AR F876L rescued the growth inhibition of enzalutamide treatment. Molecular dynamics simulations performed on antiandrogen-AR complexes suggested a mechanism by which the F876L substitution alleviates antagonism through repositioning of the coactivator recruiting helix 12. This model then provided the rationale for a focused chemical screen which, based on existing antiandrogen scaffolds, identified three novel compounds that effectively antagonized AR F876L (and AR WT) to suppress the growth of prostate cancer cells resistant to enzalutamide. DOI:http://dx.doi.org/10.7554/eLife.00499.001.

Published
2013

27. Correction: Urine tumor DNA detection of minimal residual disease in muscle-invasive bladder cancer treated with curative-intent radical cystectomy: A cohort study

Author

Chauhan, Pradeep S., Chen, Kevin, Babbra, Ramandeep K., Feng, Wenjia, Pejovic, Nadja, Nallicheri, Armaan, Harris, Peter K., Dienstbach, Katherine, Atkocius, Andrew, Maguire, Lenon, Qaium, Faridi, Szymanski, Jeffrey J., Baumann, Brian C., Ding, Li, Cao, Dengfeng, Reimers, Melissa A., Kim, Eric H., Smith, Zachary L., Arora, Vivek K., and Chaudhuri, Aadel A.

Abstract

Author(s): Pradeep S. Chauhan, Kevin Chen, Ramandeep K. Babbra, Wenjia Feng, Nadja Pejovic, Armaan Nallicheri, Peter K. Harris, Katherine Dienstbach, Andrew Atkocius, Lenon Maguire, Faridi Qaium, Jeffrey J. Szymanski, Brian [...]

Published
2021
Full Text
View/download PDF

30. Evaluating nitrogen cycling in terrestrial biosphere models: a disconnect between the carbon and nitrogen cycles

Author

Kou-Giesbrecht, Sian, primary, Arora, Vivek K., additional, Seiler, Christian, additional, Arneth, Almut, additional, Falk, Stefanie, additional, Jain, Atul K., additional, Joos, Fortunat, additional, Kennedy, Daniel, additional, Knauer, Jürgen, additional, Sitch, Stephen, additional, O'Sullivan, Michael, additional, Pan, Naiqing, additional, Sun, Qing, additional, Tian, Hanqin, additional, Vuichard, Nicolas, additional, and Zaehle, Sönke, additional

Published
2023
Full Text
View/download PDF

32. Mapping of ESA's Climate Change Initiative land cover data to plant functional types for use in the CLASSIC land model

Author

Wang, Libo, Arora, Vivek K., Bartlett, Paul, Chan, Ed, and Curasi, Salvatore R.

Abstract

Plant functional types (PFTs) are used to represent vegetation distribution in land surface models (LSMs). Previous studies have shown large differences in the geographical distribution of PFTs currently used in various LSMs, which may arise from the differences in the underlying land cover products but also the methods used to map or reclassify land cover data to the PFTs that a given LSM represents. There are large uncertainties associated with existing PFT mapping methods since they are largely based on expert judgement and therefore are subjective. In this study, we propose a new approach to inform the mapping or the cross-walking process using analyses from sub-pixel fractional error matrices, which allows for a quantitative assessment of the fractional composition of the land cover categories in a dataset. We use the Climate Change Initiative (CCI) land cover product produced by the European Space Agency (ESA). Previous work has shown that compared to fine-resolution maps over Canada, the ESA-CCI product provides an improved land cover distribution compared to that from the GLC2000 dataset currently used in the CLASSIC (Canadian Land Surface Scheme Including Biogeochemical Cycles) model. A tree cover fraction dataset and a fine-resolution land cover map over Canada are used to compute the sub-pixel fractional composition of the land cover classes in ESA-CCI, which is then used to create a cross-walking table for mapping the ESA-CCI land cover categories to nine PFTs represented in the CLASSIC model. There are large differences between the new PFT distributions and those currently used in the model. Offline simulations performed with the CLASSIC model using the ESA-CCI-based PFTs show improved winter albedo compared to that based on the GLC2000 dataset. This emphasizes the importance of accurate representation of vegetation distribution for realistic simulation of surface albedo in LSMs. Results in this study suggest that the sub-pixel fractional composition analyses are an effective way to reduce uncertainties in the PFT mapping process and therefore, to some extent, objectify the otherwise subjective process.

Published
2023

33. Urine tumor DNA detection of minimal residual disease in muscle-invasive bladder cancer treated with curative-intent radical cystectomy: A cohort study

Author

Chauhan, Pradeep S., Chen, Kevin, Babbra, Ramandeep K., Feng, Wenjia, Pejovic, Nadja, Nallicheri, Armaan, Harris, Peter K., Dienstbach, Katherine, Atkocius, Andrew, Maguire, Lenon, Qaium, Faridi, Szymanski, Jeffrey J., Baumann, Brian C., Ding, Li, Cao, Dengfeng, Reimers, Melissa A., Kim, Eric H., Smith, Zachary L., Arora, Vivek K., and Chaudhuri, Aadel A.

Subjects
Identification and classification, Care and treatment, Usage, Prognosis, Patient outcomes, Health aspects, Cystectomy -- Patient outcomes, Bladder cancer -- Care and treatment -- Prognosis -- Patient outcomes, DNA -- Identification and classification -- Health aspects, Urinalysis -- Usage, Urine -- Analysis
Abstract

Author(s): Pradeep S. Chauhan 1, Kevin Chen 1, Ramandeep K. Babbra 1, Wenjia Feng 1, Nadja Pejovic 1, Armaan Nallicheri 1, Peter K. Harris 1, Katherine Dienstbach 2,3, Andrew Atkocius [...], Background The standard of care treatment for muscle-invasive bladder cancer (MIBC) is radical cystectomy, which is typically preceded by neoadjuvant chemotherapy. However, the inability to assess minimal residual disease (MRD) noninvasively limits our ability to offer bladder-sparing treatment. Here, we sought to develop a liquid biopsy solution via urine tumor DNA (utDNA) analysis. Methods and findings We applied urine Cancer Personalized Profiling by Deep Sequencing (uCAPP-Seq), a targeted next-generation sequencing (NGS) method for detecting utDNA, to urine cell-free DNA (cfDNA) samples acquired between April 2019 and November 2020 on the day of curative-intent radical cystectomy from 42 patients with localized bladder cancer. The average age of patients was 69 years (range: 50 to 86), of whom 76% (32/42) were male, 64% (27/42) were smokers, and 76% (32/42) had a confirmed diagnosis of MIBC. Among MIBC patients, 59% (19/32) received neoadjuvant chemotherapy. utDNA variant calling was performed noninvasively without prior sequencing of tumor tissue. The overall utDNA level for each patient was represented by the non-silent mutation with the highest variant allele fraction after removing germline variants. Urine was similarly analyzed from 15 healthy adults. utDNA analysis revealed a median utDNA level of 0% in healthy adults and 2.4% in bladder cancer patients. When patients were classified as those who had residual disease detected in their surgical sample (n = 16) compared to those who achieved a pathologic complete response (pCR; n = 26), median utDNA levels were 4.3% vs. 0%, respectively (p = 0.002). Using an optimal utDNA threshold to define MRD detection, positive utDNA MRD detection was highly correlated with the absence of pCR (p < 0.001) with a sensitivity of 81% and specificity of 81%. Leave-one-out cross-validation applied to the prediction of pathologic response based on utDNA MRD detection in our cohort yielded a highly significant accuracy of 81% (p = 0.007). Moreover, utDNA MRD-positive patients exhibited significantly worse progression-free survival (PFS; HR = 7.4; 95% CI: 1.4-38.9; p = 0.02) compared to utDNA MRD-negative patients. Concordance between urine- and tumor-derived mutations, determined in 5 MIBC patients, was 85%. Tumor mutational burden (TMB) in utDNA MRD-positive patients was inferred from the number of non-silent mutations detected in urine cfDNA by applying a linear relationship derived from The Cancer Genome Atlas (TCGA) whole exome sequencing of 409 MIBC tumors. We suggest that about 58% of these patients with high inferred TMB might have been candidates for treatment with early immune checkpoint blockade. Study limitations included an analysis restricted only to single-nucleotide variants (SNVs), survival differences diminished by surgery, and a low number of DNA damage response (DRR) mutations detected after neoadjuvant chemotherapy at the MRD time point. Conclusions utDNA MRD detection prior to curative-intent radical cystectomy for bladder cancer correlated significantly with pathologic response, which may help select patients for bladder-sparing treatment. utDNA MRD detection also correlated significantly with PFS. Furthermore, utDNA can be used to noninvasively infer TMB, which could facilitate personalized immunotherapy for bladder cancer in the future.

Published
2021
Full Text
View/download PDF

35. National contributions to climate change due to historical emissions of carbon dioxide, methane and nitrous oxide

Author

Friedlingstein, Pierre, O'Sullivan, Michael, Jones, Matthew W., Andrew, Robbie M., Gregor, Luke, Hauck, Judith, Le Quéré, Corinne, Luijkx, Ingrid T., Olsen, Are, Peters, Glen P., Peters, Wouter, Pongratz, Julia, Schwingshackl, Clemens, Sitch, Stephen, Canadell, Josep G., Ciais, Philippe, Jackson, Robert B., Alin, Simone R., Alkama, Ramdane, Arneth, Almut, Arora, Vivek K., Bates, Nicholas R., Becker, Meike, Bellouin, Nicolas, Bittig, Henry C., Bopp, Laurent, Chevallier, Frédéric, Chini, Louise P., Cronin, Margot, Evans, Wiley, Falk, Stefanie, Feely, Richard A., Gasser, Thomas, Gehlen, Marion, Gkritzalis, Thanos, Gloege, Lucas, Grassi, Giacomo, Gruber, Nicolas, Gürses, Özgür, Harris, Ian, Hefner, Matthew, Houghton, Richard A., Hurtt, George C., Iida, Yosuke, Ilyina, Tatiana, Jain, Atul K., Jersild, Annika, Kadono, Koji, Kato, Etsushi, Kennedy, Daniel, Klein Goldewijk, Kees, Knauer, Jürgen, Korsbakken, Jan Ivar, Landschützer, Peter, Lefèvre, Nathalie, Lindsay, Keith, Liu, Junjie, Liu, Zhu, Marland, Gregg, Mayot, Nicolas, Mcgrath, Matthew J., Metzl, Nicolas, Monacci, Natalie M., Munro, David R., Nakaoka, Shin-Ichiro, Niwa, Yosuke, O'brien, Kevin, Ono, Tsuneo, Palmer, Paul I., Pan, Naiqing, Pierrot, Denis, Pocock, Katie, Poulter, Benjamin, Resplandy, Laure, Robertson, Eddy, Rödenbeck, Christian, Rodriguez, Carmen, Rosan, Thais M., Schwinger, Jörg, Séférian, Roland, Shutler, Jamie D., Skjelvan, Ingunn, Steinhoff, Tobias, Sun, Qing, Sutton, Adrienne J., Sweeney, Colm, Takao, Shintaro, Tanhua, Toste, Tans, Pieter P., Tian, Xiangjun, Tian, Hanqin, Tilbrook, Bronte, Tsujino, Hiroyuki, Tubiello, Francesco, Van Der Werf, Guido R., Walker, Anthony P., Wanninkhof, Rik, Whitehead, Chris, Willstrand Wranne, Anna, Wright, Rebecca, Yuan, Wenping, Yue, Chao, Yue, Xu, Zaehle, Sönke, Zeng, Jiye, Zheng, Bo, Friedlingstein, Pierre, O'Sullivan, Michael, Jones, Matthew W., Andrew, Robbie M., Gregor, Luke, Hauck, Judith, Le Quéré, Corinne, Luijkx, Ingrid T., Olsen, Are, Peters, Glen P., Peters, Wouter, Pongratz, Julia, Schwingshackl, Clemens, Sitch, Stephen, Canadell, Josep G., Ciais, Philippe, Jackson, Robert B., Alin, Simone R., Alkama, Ramdane, Arneth, Almut, Arora, Vivek K., Bates, Nicholas R., Becker, Meike, Bellouin, Nicolas, Bittig, Henry C., Bopp, Laurent, Chevallier, Frédéric, Chini, Louise P., Cronin, Margot, Evans, Wiley, Falk, Stefanie, Feely, Richard A., Gasser, Thomas, Gehlen, Marion, Gkritzalis, Thanos, Gloege, Lucas, Grassi, Giacomo, Gruber, Nicolas, Gürses, Özgür, Harris, Ian, Hefner, Matthew, Houghton, Richard A., Hurtt, George C., Iida, Yosuke, Ilyina, Tatiana, Jain, Atul K., Jersild, Annika, Kadono, Koji, Kato, Etsushi, Kennedy, Daniel, Klein Goldewijk, Kees, Knauer, Jürgen, Korsbakken, Jan Ivar, Landschützer, Peter, Lefèvre, Nathalie, Lindsay, Keith, Liu, Junjie, Liu, Zhu, Marland, Gregg, Mayot, Nicolas, Mcgrath, Matthew J., Metzl, Nicolas, Monacci, Natalie M., Munro, David R., Nakaoka, Shin-Ichiro, Niwa, Yosuke, O'brien, Kevin, Ono, Tsuneo, Palmer, Paul I., Pan, Naiqing, Pierrot, Denis, Pocock, Katie, Poulter, Benjamin, Resplandy, Laure, Robertson, Eddy, Rödenbeck, Christian, Rodriguez, Carmen, Rosan, Thais M., Schwinger, Jörg, Séférian, Roland, Shutler, Jamie D., Skjelvan, Ingunn, Steinhoff, Tobias, Sun, Qing, Sutton, Adrienne J., Sweeney, Colm, Takao, Shintaro, Tanhua, Toste, Tans, Pieter P., Tian, Xiangjun, Tian, Hanqin, Tilbrook, Bronte, Tsujino, Hiroyuki, Tubiello, Francesco, Van Der Werf, Guido R., Walker, Anthony P., Wanninkhof, Rik, Whitehead, Chris, Willstrand Wranne, Anna, Wright, Rebecca, Yuan, Wenping, Yue, Chao, Yue, Xu, Zaehle, Sönke, Zeng, Jiye, and Zheng, Bo

Abstract

A complete description of the dataset is given by Jones et al. (2023). Key information is provided below. A dataset describing the global warming response to national emissions CO2, CH4 and N2O from fossil and land use sources during 1851-2021. National CO2 emissions data are collated from the Global Carbon Project (Andrew and Peters, 2022; Friedlingstein et al., 2022). National CH4 and N2O emissions data are collated from PRIMAP-hist (HISTTP) (Gütschow et al., 2022). We construct a time series of cumulative CO2-equivalent emissions for each country, gas, and emissions source (fossil or land use). Emissions of CH4 and N2O emissions are related to cumulative CO2-equivalent emissions using the Global Warming Potential (GWP*) approach, with best-estimates of the coefficients taken from the IPCC AR6 (Forster et al., 2021). Warming in response to cumulative CO2-equivalent emissions is estimated using the transient climate response to cumulative carbon emissions (TCRE) approach, with best-estimate value of TCRE taken from the IPCC AR6 (Forster et al., 2021, Canadell et al., 2021). 'Warming' is specifically the change in global mean surface temperature (GMST). The data files provide emissions, cumulative emissions and the GMST response by country, gas (CO2, CH4, N2O or 3-GHG total) and source (fossil emissions, land use emissions or the total)., A complete description of the dataset is given by Jones et al. (2023). Key information is provided below. Background A dataset describing the global warming response to national emissions CO2, CH4 and N2O from fossil and land use sources during 1851-2021. National CO2 emissions data are collated from the Global Carbon Project (Andrew and Peters, 2022; Friedlingstein et al., 2022). National CH4 and N2O emissions data are collated from PRIMAP-hist (HISTTP) (Gütschow et al., 2022). We construct a time series of cumulative CO2-equivalent emissions for each country, gas, and emissions source (fossil or land use). Emissions of CH4 and N2O emissions are related to cumulative CO2-equivalent emissions using the Global Warming Potential (GWP*) approach, with best-estimates of the coefficients taken from the IPCC AR6 (Forster et al., 2021). Warming in response to cumulative CO2-equivalent emissions is estimated using the transient climate response to cumulative carbon emissions (TCRE) approach, with best-estimate value of TCRE taken from the IPCC AR6 (Forster et al., 2021, Canadell et al., 2021). 'Warming' is specifically the change in global mean surface temperature (GMST). The data files provide emissions, cumulative emissions and the GMST response by country, gas (CO2, CH4, N2O or 3-GHG total) and source (fossil emissions, land use emissions or the total). Data records: overview The data records include three comma separated values (.csv) files as described below. All files are in ‘long’ format with one value provided in the Data column for each combination of the categorical variables Year, Country Name, Country ISO3 code, Gas, and Component columns. Component specifies fossil emissions, LULUCF emissions or total emissions of the gas. Gas specifies CO2, CH4, N

Published
2023

36. The effect of climate change on the simulated streamflow of six Canadian rivers based on the CanRCM4 regional climate model.

Author

Arora, Vivek K., Lima, Aranildo, and Shrestha, Rajesh

Subjects
ATMOSPHERIC models, CLIMATE change models, GLOBAL warming, CLIMATE change, WATERSHEDS, STREAMFLOW, BASE flow (Hydrology)
Abstract

The effect of climate change is investigated on the hydro-climatology of six major Canadian rivers (Mackenzie, Yukon, Columbia, Fraser, Nelson, and St. Lawrence), in particular streamflow, by analyzing results from the historical and future simulations (RCP 4.5 and 8.5 scenarios) performed with the Canadian regional climate model (CanRCM4). Streamflow is obtained by routing runoff using river networks at 0.5° resolution. Of these six rivers, Nelson and St. Lawrence are the most regulated. As a result, the streamflow at the mouth of these rivers shows very little seasonality. Additionally, the Great Lakes significantly dampen the seasonality of streamflow for the St. Lawrence River. Mean annual precipitation (P), evaporation (E), runoff (R), and temperature increase for all six river basins considered and the increases are higher for the more fossil fuel-intensive RCP 8.5 scenario. The only exception is the Nelson River basin for which the simulated runoff increases are extremely small. The hydrological response of these rivers to climate warming is characterized by their existing climate states. The northerly Mackenzie and Yukon River basins show a decrease in evaporation ratio (E/P) and an increase in runoff ratio (R/P) since the increase in precipitation is more than enough to offset the increase in evaporation associated with increasing temperature. For the southerly Fraser and Columbia River basins, the E/P ratio increases, and the R/P ratio decreases due to an already milder climate in the Pacific north-western region. The seasonality of simulated monthly streamflow is also more affected for the southerly Fraser and Columbia Rivers than for the northerly Mackenzie and Yukon Rivers as snow amounts decrease and snowmelt occurs earlier. The streamflow seasonality for the Mackenzie and Yukon rivers is still dominated by snowmelt at the end of the century even in the RCP 8.5 scenario. The simulated streamflow regime for the Fraser and Columbia Rivers shifts from a snow-dominated to a hybrid/rainfall-dominated regime towards the end of this century in the RCP 8.5 scenario. While we expect the climate change signal from CanRCM4 to be higher than other climate models, owing to the higher-than-average climate sensitivity of its parent global climate model, the results presented here provide a consistent overview of hydrological changes across six major Canadian river basins in response to a warmer climate. [ABSTRACT FROM AUTHOR]

Published
2024
Full Text
View/download PDF

37. Estimation of Canada's methane emissions: inverse modelling analysis using the ECCC measurement network.

Author

Ishizawa, Misa, Chan, Douglas, Worthy, Doug, Chan, Elton, Vogel, Felix, Melton, Joe R., and Arora, Vivek K.

Abstract

Canada has major sources of atmospheric methane (CH4), with the world second-largest boreal wetland and the world fourth-largest natural gas production. However, Canada's CH4 emissions remain uncertain among estimates. Better quantification and characterization of Canada's CH4 emissions are critical for climate mitigation strategies. To improve our understanding of Canada's CH4 emissions, we performed an ensemble regional inversion (2007-2017) constrained with the Environment and Climate Change Canada (ECCC) surface measurement network. The decadal CH4 estimates show no significant trend, unlike some studies that reported long-term trends. The total CH4 estimate is 17.4 (15.3-19.5) Tg CH4 year-1, partitioned into natural and anthropogenic sources, 10.8 (7.5-13.2) and 6.6 (6.2-7.8) Tg CH4 year-1, respectively. The estimated anthropogenic emission is higher than inventories, mainly in western Canada (with the fossil fuel industry). Furthermore, the results reveal notable spatiotemporal characteristics. First, the modelled gradients of atmospheric CH4 show improvement after inversion when compared to observations, implying the CH4 gradients could help verify the inversion results. Second, the seasonal variations show slow onset and late summer maximum, indicating wetland CH4 flux has hysteretic dependence on air temperature. Third, the boreal winter natural CH4 emissions, usually treated as negligible, appear quantifiable (≥ 20 % of annual emissions). Understanding winter emission is important for climate prediction, as the winter in Canada is warming faster than the summer. Fourth, the inter-annual variability in estimated CH4 emissions is positively correlated with summer air temperature anomalies. This could enhance Canada's natural CH4 emission in the warming climate. [ABSTRACT FROM AUTHOR]

Published
2023
Full Text
View/download PDF

38. Data from Androgen Receptor Signaling Regulates DNA Repair in Prostate Cancers

Author

Polkinghorn, William R., primary, Parker, Joel S., primary, Lee, Man X., primary, Kass, Elizabeth M., primary, Spratt, Daniel E., primary, Iaquinta, Phillip J., primary, Arora, Vivek K., primary, Yen, Wei-Feng, primary, Cai, Ling, primary, Zheng, Deyou, primary, Carver, Brett S., primary, Chen, Yu, primary, Watson, Philip A., primary, Shah, Neel P., primary, Fujisawa, Sho, primary, Goglia, Alexander G., primary, Gopalan, Anuradha, primary, Hieronymus, Haley, primary, Wongvipat, John, primary, Scardino, Peter T., primary, Zelefsky, Michael J., primary, Jasin, Maria, primary, Chaudhuri, Jayanta, primary, Powell, Simon N., primary, and Sawyers, Charles L., primary

Published
2023
Full Text
View/download PDF

39. Supplementary Table S1 from Androgen Receptor Signaling Regulates DNA Repair in Prostate Cancers

Author

Polkinghorn, William R., primary, Parker, Joel S., primary, Lee, Man X., primary, Kass, Elizabeth M., primary, Spratt, Daniel E., primary, Iaquinta, Phillip J., primary, Arora, Vivek K., primary, Yen, Wei-Feng, primary, Cai, Ling, primary, Zheng, Deyou, primary, Carver, Brett S., primary, Chen, Yu, primary, Watson, Philip A., primary, Shah, Neel P., primary, Fujisawa, Sho, primary, Goglia, Alexander G., primary, Gopalan, Anuradha, primary, Hieronymus, Haley, primary, Wongvipat, John, primary, Scardino, Peter T., primary, Zelefsky, Michael J., primary, Jasin, Maria, primary, Chaudhuri, Jayanta, primary, Powell, Simon N., primary, and Sawyers, Charles L., primary

Published
2023
Full Text
View/download PDF

40. Supplementary Figure S3 from Androgen Receptor Signaling Regulates DNA Repair in Prostate Cancers

Author

Polkinghorn, William R., primary, Parker, Joel S., primary, Lee, Man X., primary, Kass, Elizabeth M., primary, Spratt, Daniel E., primary, Iaquinta, Phillip J., primary, Arora, Vivek K., primary, Yen, Wei-Feng, primary, Cai, Ling, primary, Zheng, Deyou, primary, Carver, Brett S., primary, Chen, Yu, primary, Watson, Philip A., primary, Shah, Neel P., primary, Fujisawa, Sho, primary, Goglia, Alexander G., primary, Gopalan, Anuradha, primary, Hieronymus, Haley, primary, Wongvipat, John, primary, Scardino, Peter T., primary, Zelefsky, Michael J., primary, Jasin, Maria, primary, Chaudhuri, Jayanta, primary, Powell, Simon N., primary, and Sawyers, Charles L., primary

Published
2023
Full Text
View/download PDF

41. Soil respiration–driven CO 2 pulses dominate Australia’s flux variability

Author

Metz, Eva-Marie, primary, Vardag, Sanam N., additional, Basu, Sourish, additional, Jung, Martin, additional, Ahrens, Bernhard, additional, El-Madany, Tarek, additional, Sitch, Stephen, additional, Arora, Vivek K., additional, Briggs, Peter R., additional, Friedlingstein, Pierre, additional, Goll, Daniel S., additional, Jain, Atul K., additional, Kato, Etsushi, additional, Lombardozzi, Danica, additional, Nabel, Julia E. M. S., additional, Poulter, Benjamin, additional, Séférian, Roland, additional, Tian, Hanqin, additional, Wiltshire, Andrew, additional, Yuan, Wenping, additional, Yue, Xu, additional, Zaehle, Sönke, additional, Deutscher, Nicholas M., additional, Griffith, David W. T., additional, and Butz, André, additional

Published
2023
Full Text
View/download PDF

42. Endothelial cells are a key target of IFN-g during response to combined PD-1/CTLA-4 ICB treatment in a mouse model of bladder cancer

Author

Freshour, Sharon L., primary, Chen, Timothy H.P., additional, Fisk, Bryan, additional, Shen, Haolin, additional, Mosior, Matthew, additional, Skidmore, Zachary L., additional, Fronick, Catrina, additional, Bolzenius, Jennifer K., additional, Griffith, Obi L., additional, Arora, Vivek K., additional, and Griffith, Malachi, additional

Published
2023
Full Text
View/download PDF

43. Is destabilisation risk increasing in land carbon sinks?

Author

Fernández-Martínez, Marcos, primary, Peñuelas, Josep, additional, Chevallier, Frederic, additional, Ciais, Philippe, additional, Obersteiner, Michael, additional, Rödenbeck, Christian, additional, Sardans, Jordi, additional, Vicca, Sara, additional, Yang, Hui, additional, Sitch, Stephen, additional, Friedlingstein, Pierre, additional, Arora, Vivek K., additional, Goll, Daniel, additional, Jain, Atul K., additional, Lombardozzi, Danica L., additional, and McGuire, Patrick C., additional

Published
2023
Full Text
View/download PDF

45. Organoid Cultures Derived from Patients with Advanced Prostate Cancer

Author

Gao, Dong, Vela, Ian, Sboner, Andrea, Iaquinta, Phillip J., Karthaus, Wouter R., Gopalan, Anuradha, Dowling, Catherine, Wanjala, Jackline N., Undvall, Eva A., Arora, Vivek K., Wongvipat, John, Kossai, Myriam, Ramazanoglu, Sinan, Barboza, Luendreo P., Di, Wei, Cao, Zhen, Zhang, Qi Fan, Sirota, Inna, Ran, Leili, MacDonald, Theresa Y., Beltran, Himisha, Mosquera, Juan-Miguel, Touijer, Karim A., Scardino, Peter T., Laudone, Vincent P., Curtis, Kristen R., Rathkopf, Dana E., Morris, Michael J., Danila, Daniel C., Slovin, Susan F., Solomon, Stephen B., Eastham, James A., Chi, Ping, Carver, Brett, Rubin, Mark A., Scher, Howard I., Clevers, Hans, Sawyers, Charles L., and Chen, Yu

Published
2014
Full Text
View/download PDF

46. The impacts of modelling prescribed vs. dynamic land cover in a high CO2 future scenario - greening of the Arctic and Amazonian dieback.

Author

Sian Kou-Giesbrecht, Arora, Vivek K., Seiler, Christian, and Libo Wang

Subjects
LAND cover, DIEBACK, CARBON cycle, BIOMES, PHYTOGEOGRAPHY, VEGETATION dynamics
Abstract

Terrestrial biosphere models are a key tool in investigating the role played by the land surface in the global climate system. However, few models simulate the geographic distribution of biomes dynamically, opting to prescribe them instead using remote sensing products. While prescribing land cover still allows for the simulation of the impacts of climate change on vegetation growth as well as the impacts of land use change, it prevents the simulation of climate change-driven biome shifts, with implications for projecting the future terrestrial carbon sink. Here, we isolate the impacts of prescribed vs. dynamic land cover implementations in a terrestrial biosphere model. We first introduce a framework for evaluating dynamic land cover (i.e., the spatial distribution of plant functional types across the land surface), which can be applied across terrestrial biosphere models alongside standard benchmarking of energy, water, and carbon cycle variables. After establishing confidence in simulated land cover, we then show that the simulated terrestrial carbon sink differs significantly between simulations with dynamic vs. prescribed land cover for a high CO2 future scenario. This is because of important range shifts that are only simulated when dynamic land cover is implemented: tree expansion into the Arctic and Amazonian transition from forest to grassland. In particular, the projected net land-atmosphere CO2 flux at the end of the 21st century is twice as large in simulations with dynamic land cover than in simulations with prescribed land cover. Our results illustrate the importance of climate change-driven biome shifts for projecting the future terrestrial carbon sink. [ABSTRACT FROM AUTHOR]

Published
2023
Full Text
View/download PDF

47. Enhanced India‐Africa Carbon Uptake and Asia‐Pacific Carbon Release Associated With the 2019 Extreme Positive Indian Ocean Dipole

Author

Wang, Jun, primary, Jiang, Fei, additional, Ju, Weimin, additional, Wang, Meirong, additional, Sitch, Stephen, additional, Arora, Vivek K., additional, Chen, Jing M., additional, Goll, Daniel S., additional, He, Wei, additional, Jain, Atul K., additional, Li, Xing, additional, Joiner, Joanna, additional, Poulter, Benjamin, additional, Séférian, Roland, additional, Wang, Hengmao, additional, Wu, Mousong, additional, Xiao, Jingfeng, additional, Yuan, Wenping, additional, Yue, Xu, additional, and Zaehle, Sönke, additional

Published
2022
Full Text
View/download PDF

48. Global Carbon Budget 2022

Author

Friedlingstein, Pierre, primary, O'Sullivan, Michael, additional, Jones, Matthew W., additional, Andrew, Robbie M., additional, Gregor, Luke, additional, Hauck, Judith, additional, Le Quéré, Corinne, additional, Luijkx, Ingrid T., additional, Olsen, Are, additional, Peters, Glen P., additional, Peters, Wouter, additional, Pongratz, Julia, additional, Schwingshackl, Clemens, additional, Sitch, Stephen, additional, Canadell, Josep G., additional, Ciais, Philippe, additional, Jackson, Robert B., additional, Alin, Simone R., additional, Alkama, Ramdane, additional, Arneth, Almut, additional, Arora, Vivek K., additional, Bates, Nicholas R., additional, Becker, Meike, additional, Bellouin, Nicolas, additional, Bittig, Henry C., additional, Bopp, Laurent, additional, Chevallier, Frédéric, additional, Chini, Louise P., additional, Cronin, Margot, additional, Evans, Wiley, additional, Falk, Stefanie, additional, Feely, Richard A., additional, Gasser, Thomas, additional, Gehlen, Marion, additional, Gkritzalis, Thanos, additional, Gloege, Lucas, additional, Grassi, Giacomo, additional, Gruber, Nicolas, additional, Gürses, Özgür, additional, Harris, Ian, additional, Hefner, Matthew, additional, Houghton, Richard A., additional, Hurtt, George C., additional, Iida, Yosuke, additional, Ilyina, Tatiana, additional, Jain, Atul K., additional, Jersild, Annika, additional, Kadono, Koji, additional, Kato, Etsushi, additional, Kennedy, Daniel, additional, Klein Goldewijk, Kees, additional, Knauer, Jürgen, additional, Korsbakken, Jan Ivar, additional, Landschützer, Peter, additional, Lefèvre, Nathalie, additional, Lindsay, Keith, additional, Liu, Junjie, additional, Liu, Zhu, additional, Marland, Gregg, additional, Mayot, Nicolas, additional, McGrath, Matthew J., additional, Metzl, Nicolas, additional, Monacci, Natalie M., additional, Munro, David R., additional, Nakaoka, Shin-Ichiro, additional, Niwa, Yosuke, additional, O'Brien, Kevin, additional, Ono, Tsuneo, additional, Palmer, Paul I., additional, Pan, Naiqing, additional, Pierrot, Denis, additional, Pocock, Katie, additional, Poulter, Benjamin, additional, Resplandy, Laure, additional, Robertson, Eddy, additional, Rödenbeck, Christian, additional, Rodriguez, Carmen, additional, Rosan, Thais M., additional, Schwinger, Jörg, additional, Séférian, Roland, additional, Shutler, Jamie D., additional, Skjelvan, Ingunn, additional, Steinhoff, Tobias, additional, Sun, Qing, additional, Sutton, Adrienne J., additional, Sweeney, Colm, additional, Takao, Shintaro, additional, Tanhua, Toste, additional, Tans, Pieter P., additional, Tian, Xiangjun, additional, Tian, Hanqin, additional, Tilbrook, Bronte, additional, Tsujino, Hiroyuki, additional, Tubiello, Francesco, additional, van der Werf, Guido R., additional, Walker, Anthony P., additional, Wanninkhof, Rik, additional, Whitehead, Chris, additional, Willstrand Wranne, Anna, additional, Wright, Rebecca, additional, Yuan, Wenping, additional, Yue, Chao, additional, Yue, Xu, additional, Zaehle, Sönke, additional, Zeng, Jiye, additional, and Zheng, Bo, additional

Published
2022
Full Text
View/download PDF

50. Supplementary material to "Global Carbon Budget 2022"

Author

Friedlingstein, Pierre, primary, O'Sullivan, Michael, additional, Jones, Matthew W., additional, Andrew, Robbie M., additional, Gregor, Luke, additional, Hauck, Judith, additional, Le Quéré, Corinne, additional, Luijkx, Ingrid T., additional, Olsen, Are, additional, Peters, Glen P., additional, Peters, Wouter, additional, Pongratz, Julia, additional, Schwingshackl, Clemens, additional, Sitch, Stephen, additional, Canadell, Josep G., additional, Ciais, Philippe, additional, Jackson, Robert B., additional, Alin, Simone R., additional, Alkama, Ramdane, additional, Arneth, Almut, additional, Arora, Vivek K., additional, Bates, Nicholas R., additional, Becker, Meike, additional, Bellouin, Nicolas, additional, Bittig, Henry C., additional, Bopp, Laurent, additional, Chevallier, Frédéric, additional, Chini, Louise P., additional, Cronin, Margot, additional, Evans, Wiley, additional, Falk, Stefanie, additional, Feely, Richard A., additional, Gasser, Thomas, additional, Gehlen, Marion, additional, Gkritzalis, Thanos, additional, Gloege, Lucas, additional, Grassi, Giacomo, additional, Gruber, Nicolas, additional, Gürses, Özgür, additional, Harris, Ian, additional, Hefner, Matthew, additional, Houghton, Richard A., additional, Hurtt, George C., additional, Iida, Yosuke, additional, Ilyina, Tatiana, additional, Jain, Atul K., additional, Jersild, Annika, additional, Kadono, Koji, additional, Kato, Etsushi, additional, Kennedy, Daniel, additional, Klein Goldewijk, Kees, additional, Knauer, Jürgen, additional, Korsbakken, Jan Ivar, additional, Landschützer, Peter, additional, Lefèvre, Nathalie, additional, Lindsay, Keith, additional, Liu, Junjie, additional, Liu, Zhu, additional, Marland, Gregg, additional, Mayot, Nicolas, additional, McGrath, Matthew J., additional, Metzl, Nicolas, additional, Monacci, Natalie M., additional, Munro, David R., additional, Nakaoka, Shin-Ichiro, additional, Niwa, Yosuke, additional, O'Brien, Kevin, additional, Ono, Tsuneo, additional, Palmer, Paul I., additional, Pan, Naiqing, additional, Pierrot, Denis, additional, Pocock, Katie, additional, Poulter, Benjamin, additional, Resplandy, Laure, additional, Robertson, Eddy, additional, Rödenbeck, Christian, additional, Rodriguez, Carmen, additional, Rosan, Thais M., additional, Schwinger, Jörg, additional, Séférian, Roland, additional, Shutler, Jamie D., additional, Skjelvan, Ingunn, additional, Steinhoff, Tobias, additional, Sun, Qing, additional, Sutton, Adrienne J., additional, Sweeney, Colm, additional, Takao, Shintaro, additional, Tanhua, Toste, additional, Tans, Pieter P., additional, Tian, Xiangjun, additional, Tian, Hanqin, additional, Tilbrook, Bronte, additional, Tsujino, Hiroyuki, additional, Tubiello, Francesco, additional, van der Werf, Guido, additional, Walker, Anthony P., additional, Wanninkhof, Rik, additional, Whitehead, Chris, additional, Willstrand Wranne, Anna, additional, Wright, Rebecca, additional, Yuan, Wenping, additional, Yue, Chao, additional, Yue, Xu, additional, Zaehle, Sönke, additional, Zeng, Jiye, additional, and Zheng, Bo, additional

Published
2022
Full Text
View/download PDF

Catalog

Books, media, physical & digital resources
See catalog results