Search

Your search keyword '"Pongratz, Julia"' showing total 233 results
Start Over Author "Pongratz, Julia" Publication Year Range Last 3 years
233 results on '"Pongratz, Julia"'

1. 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. Synthesis of the land carbon fluxes of the Amazon region between 2010 and 2020

Author

Rosan, Thais M., Sitch, Stephen, O’Sullivan, Michael, Basso, Luana S., Wilson, Chris, Silva, Camila, Gloor, Emanuel, Fawcett, Dominic, Heinrich, Viola, Souza, Jefferson G., Bezerra, Francisco Gilney Silva, von Randow, Celso, Mercado, Lina M., Gatti, Luciana, Wiltshire, Andy, Friedlingstein, Pierre, Pongratz, Julia, Schwingshackl, Clemens, Williams, Mathew, Smallman, Luke, Knauer, Jürgen, Arora, Vivek, Kennedy, Daniel, Tian, Hanqin, Yuan, Wenping, Jain, Atul K., Falk, Stefanie, Poulter, Benjamin, Arneth, Almut, Sun, Qing, Zaehle, Sönke, Walker, Anthony P., Kato, Etsushi, Yue, Xu, Bastos, Ana, Ciais, Philippe, Wigneron, Jean-Pierre, Albergel, Clement, and Aragão, Luiz E. O. C.

Published
2024
Full Text
View/download PDF

6. Ten New Insights in Climate Science 2023/2024

Author

Bustamante, Mercedes, Roy, Joyashree, Ospina, Daniel, Achakulwisut, Ploy, Aggarwal, Anubha, Bastos, Ana, Broadgate, Wendy, Canadell, Josep G, Carr, Edward R, Chen, Deliang, Cleugh, Helen A, Ebi, Kristie L, Edwards, Clea, Farbotko, Carol, Fernández-Martínez, Marcos, Frölicher, Thomas L, Fuss, Sabine, Geden, Oliver, Gruber, Nicolas, Harrington, Luke J, Hauck, Judith, Hausfather, Zeke, Hebden, Sophie, Hebinck, Aniek, Huq, Saleemul, Huss, Matthias, Jamero, M Laurice P, Juhola, Sirkku, Kumarasinghe, Nilushi, Lwasa, Shuaib, Mallick, Bishawjit, Martin, Maria, McGreevy, Steven, Mirazo, Paula, Mukherji, Aditi, Muttitt, Greg, Nemet, Gregory F, Obura, David, Okereke, Chukwumerije, Oliver, Tom, Orlove, Ben, Ouedraogo, Nadia S, Patra, Prabir K, Pelling, Mark, Pereira, Laura M, Persson, Åsa, Pongratz, Julia, Prakash, Anjal, Rammig, Anja, Raymond, Colin, Redman, Aaron, Reveco, Cristobal, Rockström, Johan, Rodrigues, Regina, Rounce, David R, Schipper, E Lisa F, Schlosser, Peter, Selomane, Odirilwe, Semieniuk, Gregor, Shin, Yunne-Jai, Siddiqui, Tasneem A, Singh, Vartika, Sioen, Giles B, Sokona, Youba, Stammer, Detlef, Steinert, Norman J, Suk, Sunhee, Sutton, Rowan, Thalheimer, Lisa, Thompson, Vikki, Trencher, Gregory, van der Geest, Kees, Werners, Saskia E, Wübbelmann, Thea, Wunderling, Nico, Yin, Jiabo, Zickfeld, Kirsten, and Zscheischler, Jakob

Subjects
Development Studies, Climate Change Impacts and Adaptation, Environmental Sciences, Human Society, Climate change impacts and adaptation, Development studies
Abstract

Non-technical summary: We identify a set of essential recent advances in climate change research with high policy relevance, across natural and social sciences: (1) looming inevitability and implications of overshooting the 1.5°C warming limit, (2) urgent need for a rapid and managed fossil fuel phase-out, (3) challenges for scaling carbon dioxide removal, (4) uncertainties regarding the future contribution of natural carbon sinks, (5) intertwinedness of the crises of biodiversity loss and climate change, (6) compound events, (7) mountain glacier loss, (8) human immobility in the face of climate risks, (9) adaptation justice, and (10) just transitions in food systems. Technical summary The IPCC Assessment Reports offer the scientific foundation for international climate negotiations and constitute an unmatched resource for climate change researchers. However, the assessment cycles take multiple years. As a contribution to cross- and interdisciplinary understanding across diverse climate change research communities, we have streamlined an annual process to identify and synthesise essential research advances. We collected input from experts on different fields using an online questionnaire and prioritised a set of ten key research insights with high policy relevance. This year we focus on: (1) looming overshoot of the 1.5°C warming limit, (2) urgency of phasing-out fossil fuels, (3) challenges for scaling carbon dioxide removal, (4) uncertainties regarding the future of natural carbon sinks, (5) need for join governance of biodiversity loss and climate change, (6) advances in the science of compound events, (7) mountain glacier loss, (8) human immobility in the face of climate risks, (9) adaptation justice, and (10) just transitions in food systems. We first present a succinct account of these Insights, reflect on their policy implications, and offer an integrated set of policy relevant messages. This science synthesis and science communication effort is also the basis for a report targeted to policymakers as a contribution to elevate climate science every year, in time for the UNFCCC COP. Social media summary We highlight recent and policy-relevant advances in climate change research - with input from more than 200 experts 1.

Published
2023

7. Using the atmospheric CO2 growth rate to constrain the CO2 flux from land use and land cover change since 1900

Author

Dohner, Julia L, Birner, Benjamin, Schwartzman, Armin, Pongratz, Julia, and Keeling, Ralph F

Subjects
Earth Sciences, Atmospheric Sciences, Biological Sciences, Life on Land, Carbon Dioxide, Ecosystem, Carbon Cycle, Carbon, Uncertainty, atmospheric CO2, CO2 growth rate, global carbon budget, global CO2 fluxes, land use change, terrestrial CO2 sink, Environmental Sciences, Ecology, Biological sciences, Earth sciences, Environmental sciences
Abstract

We explore the ability of the atmospheric CO2 record since 1900 to constrain the source of CO2 from land use and land cover change (hereafter "land use"), taking account of uncertainties in other terms in the global carbon budget. We find that the atmospheric constraint favors land use CO2 flux estimates with lower decadal variability and can identify potentially erroneous features, such as emission peaks around 1960 and after 2000, in some published estimates. Furthermore, we resolve an offset in the global carbon budget that is most plausibly attributed to the land use flux. This correction shifts the mean land use flux since 1900 across 20 published estimates down by 0.35 PgC year-1 to 1.04 ± 0.57 PgC year-1 , which is within the range but at the low end of these estimates. We show that the atmospheric CO2 record can provide insights into the time history of the land use flux that may reduce uncertainty in this term and improve current understanding and projections of the global carbon cycle.

Published
2022

9. Corrigendum: A review of trends and drivers of greenhouse gas emissions by sector from 1990 to 2018 (2021 Environ. Res. Lett. 16 073005)

Author

Lamb, William F, Wiedmann, Thomas, Pongratz, Julia, Andrew, Robbie, Crippa, Monica, Olivier, Jos GJ, Wiedenhofer, Dominik, Mattioli, Giulio, Al Khourdajie, Alaa, House, Jo, Pachauri, Shonali, Figueroa, Maria, Saheb, Yamina, Slade, Raphael, Hubacek, Klaus, Sun, Laixiang, Ribeiro, Suzana Kahn, Khennas, Smail, du Can, Stephane de la Rue, Chapungu, Lazarus, Davis, Steven J, Bashmakov, Igor, Dai, Hancheng, Dhakal, Shobhakar, Tan, Xianchun, Geng, Yong, Gu, Baihe, and Minx, Jan

Subjects
Environmental and Resources Law, Law and Legal Studies, Climate Action, Meteorology & Atmospheric Sciences
Abstract

This corrigendum resolves an error in figure 17 and clarifies the scope of the cement sector in figure 2. Figure 17 in the original published manuscript depicts a Kaya identity for the agriculture, forestry and other land uses (AFOLU) sector. We unintentionally excluded land-use CO2 emissions from total greenhouse gas (GHG) emissions in this identity, and depicted only agricultural GHG emissions.

Published
2022

10. Are Land‐Use Change Emissions in Southeast Asia Decreasing or Increasing?

Author

Kondo, Masayuki, Sitch, Stephen, Ciais, Philippe, Achard, Frédéric, Kato, Etsushi, Pongratz, Julia, Houghton, Richard A, Canadell, Josep G, Patra, Prabir K, Friedlingstein, Pierre, Li, Wei, Anthoni, Peter, Arneth, Almut, Chevallier, Frédéric, Ganzenmüller, Raphael, Harper, Anna, Jain, Atul K, Koven, Charles, Lienert, Sebastian, Lombardozzi, Danica, Maki, Takashi, Nabel, Julia EMS, Nakamura, Takashi, Niwa, Yosuke, Peylin, Philippe, Poulter, Benjamin, Pugh, Thomas AM, Rödenbeck, Christian, Saeki, Tazu, Stocker, Benjamin, Viovy, Nicolas, Wiltshire, Andy, and Zaehle, Sönke

Subjects
Earth Sciences, Atmospheric Sciences, Life on Land, Southeast Asia, land-use changes, Dynamic Global Vegetation Models, book-keeping models, forest area, atmospheric inversions, Geochemistry, Oceanography, Meteorology & Atmospheric Sciences, Geoinformatics, Climate change impacts and adaptation
Abstract

Southeast Asia is a region known for active land-use changes (LUC) over the past 60 years; yet, how trends in net CO2 uptake and release resulting from LUC activities (net LUC flux) have changed through past decades remains uncertain. The level of uncertainty in net LUC flux from process-based models is so high that it cannot be concluded that newer estimates are necessarily more reliable than older ones. Here, we examined net LUC flux estimates of Southeast Asia for the 1980s−2010s from older and newer sets of Dynamic Global Vegetation Model simulations (TRENDY v2 and v7, respectively), and forcing data used for running those simulations, along with two book-keeping estimates (H&N and BLUE). These estimates yielded two contrasting historical LUC transitions, such that TRENDY v2 and H&N showed a transition from increased emissions from the 1980s to 1990s to declining emissions in the 2000s, while TRENDY v7 and BLUE showed the opposite transition. We found that these contrasting transitions originated in the update of LUC forcing data, which reduced the loss of forest area during the 1990s. Further evaluation of remote sensing studies, atmospheric inversions, and the history of forestry and environmental policies in Southeast Asia supported the occurrence of peak emissions in the 1990s and declining thereafter. However, whether LUC emissions continue to decline in Southeast Asia remains uncertain as key processes in recent years, such as conversion of peat forest to oil-palm plantation, are yet to be represented in the forcing data, suggesting a need for further revision.

Published
2022

11. Emissionsreduktionen durch ökosystembasierte Ansätze

Author

Hansjürgens, Bernd, Bolte, Andreas, Flessa, Heinz, Heidecke, Claudia, Nordt, Anke, Osterburg, Bernhard, Pongratz, Julia, Rock, Joachim, Schäfer, Achim, Stümer, Wolfgang, Wichmann, Sabine, Brasseur, Guy P., editor, Jacob, Daniela, editor, and Schuck-Zöller, Susanne, editor

Published
2023
Full Text
View/download PDF

14. How to measure the efficiency of bioenergy crops compared to forestation.

Author

Egerer, Sabine, Falk, Stefanie, Mayer, Dorothea, Nützel, Tobias, Obermeier, Wolfgang A., and Pongratz, Julia

Abstract

The climate mitigation potential of terrestrial carbon dioxide removal (tCDR) methods depends critically on the timing and magnitude of their implementation. In our study, we introduce different measures of efficiency to evaluate the carbon removal potential of afforestation and reforestation (AR) and bioenergy with carbon capture and storage (BECCS) under the low-emission scenario SSP1-2.6 and in the same area. We define efficiency as the potential to sequester carbon in the biosphere in a specific area or store carbon in geological reservoirs or woody products within a certain time. In addition to carbon capture and storage (CCS), we consider the effects of fossil fuel substitution (FFS) through the usage of bioenergy for energy production, which increases the efficiency through avoided CO2 emissions. These efficiency measures reflect perspectives regarding climate mitigation, carbon sequestration, land availability, spatiotemporal dynamics, and the technological progress in FFS and CCS. We use the land component JSBACH3.2 of the Max Planck Institute Earth System Model (MPI-ESM) to calculate the carbon sequestration potential in the biosphere using an updated representation of second-generation bioenergy plants such as Miscanthus. Our spatially explicit modeling results reveal that, depending on FFS and CCS levels, BECCS sequesters 24–158 GtC by 2100, whereas AR methods sequester around 53 GtC on a global scale, with BECCS having an advantage in the long term. For our specific setup, BECCS has a higher potential in the South American grasslands and southeast Africa, whereas AR methods are more suitable in southeast China. Our results reveal that the efficiency of BECCS to sequester carbon compared to "nature-based solutions" like AR will depend critically on the upscaling of CCS facilities, replacing fossil fuels with bioenergy in the future, the time frame, and the location of tCDR deployment. [ABSTRACT FROM AUTHOR]

Published
2024
Full Text
View/download PDF

15. Global Carbon Budget 2024.

Author

Friedlingstein, Pierre, O'Sullivan, Michael, Jones, Matthew W., Andrew, Robbie M., Hauck, Judith, Landschützer, Peter, Quéré, Corinne Le, Li, Hongmei, 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., and Arneth, Almut

Subjects
ATMOSPHERIC oxygen, CEMENT industries, CARBON dioxide, GOVERNMENT policy on climate change, CLIMATE change, CARBON cycle
Abstract

Accurate assessment of anthropogenic carbon dioxide (CO2) emissions and their redistribution among the atmosphere, ocean, and terrestrial biosphere in a changing climate is critical to better understand the global carbon cycle, support the development of climate policies, and project future climate change. Here we describe and synthesise datasets and methodologies to quantify the five major components of the global carbon budget and their uncertainties. Fossil CO2 emissions (EFOS) are based on energy statistics and cement production data, while emissions from land-use change (ELUC) are based on land-use and land-use change data and bookkeeping models. Atmospheric CO2 concentration is measured directly, and its growth rate (GATM) is computed from the annual changes in concentration. The ocean CO2 sink (SOCEAN) is estimated with global ocean biogeochemistry models and observation-based f CO2-products. The terrestrial CO2 sink (SLAND) is estimated with dynamic global vegetation models. Additional lines of evidence on land and ocean sinks are provided by atmospheric inversions, atmospheric oxygen measurements and Earth System Models. The sum of all sources and sinks results in the carbon budget imbalance (BIM), a measure of imperfect data and incomplete understanding of the contemporary carbon cycle. All uncertainties are reported as ±1σ. For the year 2023, EFOS increased by 1.3 % relative to 2022, with fossil emissions at 10.1 ± 0.5 GtC yr-1 (10.3 ± 0.5 GtC yr-1 when the cement carbonation sink is not included), ELUC was 1.0 ± 0.7 GtC yr-1, for a total anthropogenic CO2 emission (including the cement carbonation sink) of 11.1 ± 0.9 GtC yr-1 (40.6 ± 3.2 GtCO2 yr-1). Also, for 2023, GATM was 5.9 ± 0.2 GtC yr-1 (2.79 ± 0.1 ppm yr-1), SOCEAN was 2.9 ± 0.4 GtC yr-1 and SLAND was 2.3 ± 1.0 GtC yr-1, with a near zero BIM (-0.02 GtC yr-1). The global atmospheric CO2 concentration averaged over 2023 reached 419.3 ± 0.1 ppm. Preliminary data for 2024, suggest an increase in EFOS relative to 2023 of +0.8 % (-0.3 % to 1.9 %) globally, and atmospheric CO2 concentration increased by 2.8 ppm reaching 422.5 ppm, 52 % above pre-industrial level (around 278 ppm in 1750). Overall, the mean and trend in the components of the global carbon budget are consistently estimated over the period 1959–2023, with a near-zero overall budget imbalance, although discrepancies of up to around 1 GtC yr-1 persist for the representation of annual to semi-decadal variability in CO2 fluxes. Comparison of estimates from multiple approaches and observations shows: (1) a persistent large uncertainty in the estimate of land-use changes emissions, (2) a low agreement between the different methods on the magnitude of the land CO2 flux in the northern extra-tropics, and (3) a discrepancy between the different methods on the mean ocean sink. This living data update documents changes in methods and datasets applied to this most-recent global carbon budget as well as evolving community understanding of the global carbon cycle. The data presented in this work are available at https://doi.org/10.18160/GCP-2024 (Friedlingstein et al., 2024). [ABSTRACT FROM AUTHOR]

Published
2024
Full Text
View/download PDF

17. On the use of Earth Observation to support estimates of national greenhouse gas emissions and sinks for the Global stocktake process: lessons learned from ESA-CCI RECCAP2

Author

Bastos, Ana, Ciais, Philippe, Sitch, Stephen, Aragão, Luiz E. O. C., Chevallier, Frédéric, Fawcett, Dominic, Rosan, Thais M., Saunois, Marielle, Günther, Dirk, Perugini, Lucia, Robert, Colas, Deng, Zhu, Pongratz, Julia, Ganzenmüller, Raphael, Fuchs, Richard, Winkler, Karina, Zaehle, Sönke, and Albergel, Clément

Published
2022
Full Text
View/download PDF

18. 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

20. Indicators of Global Climate Change 2023: annual update of key indicators of the state of the climate system and human influence

Author

Forster, Piers M., primary, Smith, Chris, additional, Walsh, Tristram, additional, Lamb, William F., additional, Lamboll, Robin, additional, Hall, Bradley, additional, Hauser, Mathias, additional, Ribes, Aurélien, additional, Rosen, Debbie, additional, Gillett, Nathan P., additional, Palmer, Matthew D., additional, Rogelj, Joeri, additional, von Schuckmann, Karina, additional, Trewin, Blair, additional, Allen, Myles, additional, Andrew, Robbie, additional, Betts, Richard A., additional, Borger, Alex, additional, Boyer, Tim, additional, Broersma, Jiddu A., additional, Buontempo, Carlo, additional, Burgess, Samantha, additional, Cagnazzo, Chiara, additional, Cheng, Lijing, additional, Friedlingstein, Pierre, additional, Gettelman, Andrew, additional, Gütschow, Johannes, additional, Ishii, Masayoshi, additional, Jenkins, Stuart, additional, Lan, Xin, additional, Morice, Colin, additional, Mühle, Jens, additional, Kadow, Christopher, additional, Kennedy, John, additional, Killick, Rachel E., additional, Krummel, Paul B., additional, Minx, Jan C., additional, Myhre, Gunnar, additional, Naik, Vaishali, additional, Peters, Glen P., additional, Pirani, Anna, additional, Pongratz, Julia, additional, Schleussner, Carl-Friedrich, additional, Seneviratne, Sonia I., additional, Szopa, Sophie, additional, Thorne, Peter, additional, Kovilakam, Mahesh V. M., additional, Majamäki, Elisa, additional, Jalkanen, Jukka-Pekka, additional, van Marle, Margreet, additional, Hoesly, Rachel M., additional, Rohde, Robert, additional, Schumacher, Dominik, additional, van der Werf, Guido, additional, Vose, Russell, additional, Zickfeld, Kirsten, additional, Zhang, Xuebin, additional, Masson-Delmotte, Valérie, additional, and Zhai, Panmao, additional

Published
2024
Full Text
View/download PDF

21. Exploring site-specific carbon dioxide removal options with storage or sequestration in the marine environment - The 10 Mt CO2 yr-1 removal challenge for Germany

Author

Yao, Wanxuan, primary, Morganti, Teresa, additional, Wu, Jiajun, additional, Borchers, Malgorzata, additional, Anschütz, Anna-Adriana, additional, Bednarz, Lena-Katharina, additional, Bhaumik, Amrita, additional, Boettcher, Miranda, additional, Burkhard, Kremena, additional, Cabus, Tony, additional, Chua, Allison Sueyi, additional, Diercks, Isabel, additional, Mario, Esposito, additional, Fink, Michael, additional, Fouqueray, Mondane, additional, Gasanzade, Firdovsi, additional, Geilert, Sonja, additional, Hauck, Judith, additional, Havermann, Felix, additional, Hellige, Inga, additional, Hoog, Sven, additional, Jürchott, Malte, additional, Kalapurakkal, Habeeb Thanveer, additional, Kemper, Jost, additional, Kremin, Isabel, additional, Lange, Isabel, additional, Lencina-Avila, Jannine Marquez, additional, Liadova, Margarita, additional, Liu, Feifei, additional, Mathesius, Sabine, additional, Mehendale, Neha, additional, Nagwekar, Tanvi, additional, Philippi, Miriam, additional, Luz, Gustavo Leite Neves da, additional, Ramasamy, Murugan, additional, Stahl, Florian, additional, Tank, Lukas, additional, Vorrath, Maria-Elena, additional, Westmark, Lennart, additional, Wey, Hao-Wei, additional, Wollnik, Ronja, additional, Wölfelschneider, Mirco, additional, Bach, Wolfgang, additional, Bischof, Kai, additional, boersma, maarten, additional, Daewel, Ute, additional, Fernández-Méndez, Mar, additional, Geuer, Jana, additional, Keller, David Peter, additional, Kopf, Achim J., additional, Merk, Christine, additional, Moosdorf, Nils, additional, Oppelt, Natascha Maria, additional, Oschlies, Andreas, additional, Pongratz, Julia, additional, Proelss, Alexander, additional, Rehder, Gregor, additional, Rüpke, Lars Helmuth, additional, Szarka, Nora, additional, Thrän, Daniela, additional, Wallmann, Klaus, additional, and Mengis, Nadine, additional

Published
2024
Full Text
View/download PDF

23. Carbon and greenhouse gas budgets of Europe: trends, interannual and spatial variability, and their drivers

Author

Lauerwald, Ronny, primary, Bastos, Ana, additional, McGrath, Matthew J, additional, Petrescu, Ana-Maria-Roxana, additional, Ritter, François, additional, Andrew, Robbie M, additional, Berchet, Antoine, additional, Broquet, Grégoire, additional, Brunner, Dominik, additional, Chevallier, Frederic, additional, Cescatti, Alessandro, additional, Filipek, Sara, additional, Fortems-Cheiney, Audrey, additional, Forzieri, Giovanni, additional, Friedlingstein, Pierre, additional, Fuchs, Richard, additional, Gerbig, Christoph, additional, Houweling, Sander, additional, Ke, Piyu, additional, Lerink, Bas J.W., additional, Li, Wei, additional, Li, Xiaojun, additional, Luijkx, Ingrid Theodora, additional, Monteil, Guillaume, additional, Munassar, Saqr, additional, Nabuurs, Gert-Jan, additional, Patra, Prabir K., additional, Peylin, Philippe, additional, Pongratz, Julia, additional, Regnier, Pierre, additional, SAUNOIS, Marielle, additional, Schelhaas, Mart-Jan, additional, Scholze, Marko, additional, Sitch, Stephen, additional, Thompson, Rona L., additional, Tian, Hanqin, additional, Tsuruta, Aki, additional, Wilson, Chris, additional, Wigneron, Jean-Pierre, additional, YAO, YITONG, additional, Zaehle, Sönke, additional, Ciais, Philippe, additional, and Li, Wanjing, additional

Published
2024
Full Text
View/download PDF

25. Contributors

Author

Ahlström, Anders, primary, Almeida, Mariana, additional, Andrew, Robbie, additional, Archibeque, Shawn, additional, Basso, Luana, additional, Bastos, Ana, additional, Bezerra, Francisco Gilney, additional, Birdsey, Richard, additional, Bowman, Kevin, additional, Bruhwiler, Lori M., additional, Brunner, Dominik, additional, Bun, Rostyslav, additional, Butman, David E., additional, Campbell, Donovan, additional, Canadell, Josep G., additional, Cardoso, Manoel, additional, Chatterjee, Abhishek, additional, Chevallier, Frédéric, additional, Ciais, Philippe, additional, Commane, Róisín, additional, Crippa, Monica, additional, Cunha-Zeri, Gisleine, additional, Domke, Grant M., additional, Euskirchen, Eugénie S., additional, Fisher, Joshua B., additional, Gilfillan, Dennis, additional, Hayes, Daniel J., additional, Holmquist, James R., additional, Houghton, Richard A., additional, Huntzinger, Deborah, additional, Ilyina, Tatiana, additional, Janardanan, Rajesh, additional, Janssens-Maenhout, Greet, additional, Jones, Matthew W., additional, Keppler, Lydia, additional, Kondo, Masayuki, additional, Kroeger, Kevin D., additional, Kurz, Werner, additional, Landschützer, Peter, additional, Lauerwald, Ronny, additional, Luyssaert, Sebastiaan, additional, MacBean, Natasha, additional, Maksyutov, Shamil, additional, Marland, Eric, additional, Marland, Gregg, additional, Miranda, Marcela, additional, Naipal, Victoria, additional, Naudts, Kim, additional, Neigh, Christopher S.R., additional, Neto, Eráclito Souza, additional, Nevison, Cynthia, additional, Niu, Shuli, additional, Oda, Tomohiro, additional, Ogle, Stephen M., additional, Ometto, Jean Pierre, additional, Ott, Lesley, additional, Pacheco, Felipe S., additional, Parmentier, Frans-Jan W., additional, Patra, Prabir K., additional, Petrescu, A.M. Roxana, additional, Pongratz, Julia, additional, Poulter, Benjamin, additional, Pugh, Thomas A.M., additional, Ramaswami, Anu, additional, Raymond, Peter A., additional, Rezende, Luiz Felipe, additional, Ribeiro, Kelly, additional, Roten, Dustin, additional, Schädel, Christina, additional, Schuur, Edward A.G., additional, Sitch, Stephen, additional, Smith, Pete, additional, Smith, William Kolby, additional, Taboada, Miguel, additional, Thompson, Rona L., additional, Tong, Kangkang, additional, Troxler, Tiffany G., additional, Tubiello, Francesco N., additional, Turner, Alexander J., additional, Villalobos, Yohanna, additional, von Randow, Celso, additional, Watts, Jennifer, additional, Welp, Lisa R., additional, Windham-Myers, Lisamarie, additional, and Zavala-Araiza, Daniel, additional

Published
2022
Full Text
View/download PDF

26. Bottom-up approaches for estimating terrestrial GHG budgets: Bookkeeping, process-based modeling, and data-driven methods

Author

Poulter, Benjamin, primary, Bastos, Ana, additional, Canadell, Josep G., additional, Ciais, Philippe, additional, Huntzinger, Deborah, additional, Houghton, Richard A., additional, Kurz, Werner, additional, Petrescu, A.M. Roxana, additional, Pongratz, Julia, additional, Sitch, Stephen, additional, and Luyssaert, Sebastiaan, additional

Published
2022
Full Text
View/download PDF

27. 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

28. Indicators of Global Climate Change 2023 : annual update of key indicators of the state of the climate system and human influence

Author

Forster, Piers M., Smith, Chris, Walsh, Tristram, Lamb, William F., Lamboll, Robin, Hall, Bradley, Hauser, Mathias, Ribes, Aurélien, Rosen, Debbie, Gillett, Nathan P., Palmer, Matthew D., Rogelj, Joeri, Von Schuckmann, Karina, Trewin, Blair, Allen, Myles, Andrew, Robbie, Betts, Richard A., Borger, Alex, Boyer, Tim, Broersma, Jiddu A., Buontempo, Carlo, Burgess, Samantha, Cagnazzo, Chiara, Cheng, Lijing, Friedlingstein, Pierre, Gettelman, Andrew, Gütschow, Johannes, Ishii, Masayoshi, Jenkins, Stuart, Lan, Xin, Morice, Colin, Mühle, Jens, Kadow, Christopher, Kennedy, John, Killick, Rachel E., Krummel, Paul B., Minx, Jan C., Myhre, Gunnar, Naik, Vaishali, Peters, Glen P., Pirani, Anna, Pongratz, Julia, Schleussner, Carl Friedrich, Seneviratne, Sonia I., Szopa, Sophie, Thorne, Peter, Kovilakam, Mahesh V.M., Majamäki, Elisa, Jalkanen, Jukka Pekka, Van Marle, Margreet, Hoesly, Rachel M., Rohde, Robert, Schumacher, Dominik, Van Der Werf, Guido, Vose, Russell, Zickfeld, Kirsten, Zhang, Xuebin, Masson-Delmotte, Valérie, Zhai, Panmao, Forster, Piers M., Smith, Chris, Walsh, Tristram, Lamb, William F., Lamboll, Robin, Hall, Bradley, Hauser, Mathias, Ribes, Aurélien, Rosen, Debbie, Gillett, Nathan P., Palmer, Matthew D., Rogelj, Joeri, Von Schuckmann, Karina, Trewin, Blair, Allen, Myles, Andrew, Robbie, Betts, Richard A., Borger, Alex, Boyer, Tim, Broersma, Jiddu A., Buontempo, Carlo, Burgess, Samantha, Cagnazzo, Chiara, Cheng, Lijing, Friedlingstein, Pierre, Gettelman, Andrew, Gütschow, Johannes, Ishii, Masayoshi, Jenkins, Stuart, Lan, Xin, Morice, Colin, Mühle, Jens, Kadow, Christopher, Kennedy, John, Killick, Rachel E., Krummel, Paul B., Minx, Jan C., Myhre, Gunnar, Naik, Vaishali, Peters, Glen P., Pirani, Anna, Pongratz, Julia, Schleussner, Carl Friedrich, Seneviratne, Sonia I., Szopa, Sophie, Thorne, Peter, Kovilakam, Mahesh V.M., Majamäki, Elisa, Jalkanen, Jukka Pekka, Van Marle, Margreet, Hoesly, Rachel M., Rohde, Robert, Schumacher, Dominik, Van Der Werf, Guido, Vose, Russell, Zickfeld, Kirsten, Zhang, Xuebin, Masson-Delmotte, Valérie, and Zhai, Panmao

Abstract

Intergovernmental Panel on Climate Change (IPCC) assessments are the trusted source of scientific evidence for climate negotiations taking place under the United Nations Framework Convention on Climate Change (UNFCCC). Evidence-based decision-making needs to be informed by up-to-date and timely information on key indicators of the state of the climate system and of the human influence on the global climate system. However, successive IPCC reports are published at intervals of 5-10 years, creating potential for an information gap between report cycles. We follow methods as close as possible to those used in the IPCC Sixth Assessment Report (AR6) Working Group One (WGI) report. We compile monitoring datasets to produce estimates for key climate indicators related to forcing of the climate system: emissions of greenhouse gases and short-lived climate forcers, greenhouse gas concentrations, radiative forcing, the Earth's energy imbalance, surface temperature changes, warming attributed to human activities, the remaining carbon budget, and estimates of global temperature extremes. The purpose of this effort, grounded in an open-data, open-science approach, is to make annually updated reliable global climate indicators available in the public domain (https://doi.org/10.5281/zenodo.11388387, Smith et al., 2024a). As they are traceable to IPCC report methods, they can be trusted by all parties involved in UNFCCC negotiations and help convey wider understanding of the latest knowledge of the climate system and its direction of travel. The indicators show that, for the 2014-2023 decade average, observed warming was 1.19 [1.06 to 1.30] °C, of which 1.19 [1.0 to 1.4] °C was human-induced. For the single-year average, human-induced warming reached 1.31 [1.1 to 1.7] °C in 2023 relative to 1850-1900. The best estimate is below the 2023-observed warming record of 1.43 [1.32 to 1.53] °C, indicating a substantial contribution of internal variability in the 2023 record. Humaninduced w

Published
2024

29. World Ocean Review: The Ocean – A Climate Champion? How to Boost Marine Carbon Dioxide Uptake

Author

Amann, Thorben, Baatz, Christian, Böttcher, Miranda, Geden, Oliver, Keller, David P., Kopf, Achim, Merk, Christine, Milinski, Sebastian, Mintenbeck, Katja, Oschlies, Andreas, Pongratz, Julia, Proelß, Alexander, Rehder, Gregor, Rickels, Wilfried, Riebesell, Ulf, Sswat, Michael, Tank, Lukas, Wallmann, Klaus, Westmark, Lennart, Wölfelschneider, Mirco, Zimmer, Martin, Amann, Thorben, Baatz, Christian, Böttcher, Miranda, Geden, Oliver, Keller, David P., Kopf, Achim, Merk, Christine, Milinski, Sebastian, Mintenbeck, Katja, Oschlies, Andreas, Pongratz, Julia, Proelß, Alexander, Rehder, Gregor, Rickels, Wilfried, Riebesell, Ulf, Sswat, Michael, Tank, Lukas, Wallmann, Klaus, Westmark, Lennart, Wölfelschneider, Mirco, and Zimmer, Martin

Abstract

What action should we take for the effective mitigation of climate change? Measures to avoid greenhouse gas emissions are surely the main priority – but the truth is that in the coming decades, we will also have to remove large quantities of carbon dioxide from the atmosphere and store it securely. Can – indeed, should – the ocean aid us in this task? The new World Ocean Review (WOR 8) explores this issue with reference to the oceans' role in the Earth's carbon cycle and looks at the benefits, risks and knowledge gaps around the main marine carbon dioxide removal techniques.

Published
2024

32. Timescale dependence of airborne fraction and underlying climate–carbon-cycle feedbacks for weak perturbations in CMIP5 models.

Author

Torres Mendonça, Guilherme L., Pongratz, Julia, and Reick, Christian H.

Subjects
CARBON cycle, CLIMATE change, CLIMATE research, PREDICTION theory, CLIMATE feedbacks, CARBON dioxide
Abstract

The response of the global climate–carbon-cycle system to anthropogenic perturbations happens differently at different timescales. The unravelling of the memory structure underlying this timescale dependence is a major challenge in climate research. Recently the widely applied α – β – γ framework proposed by to quantify climate–carbon-cycle feedbacks has been generalized to account also for such internal memory. By means of this generalized framework, we investigate the timescale dependence of the airborne fraction for a set of Earth system models that participated in CMIP5 (Coupled Model Intercomparison Project Phase 5). The analysis is based on published simulation data from C 4 MIP-type (Coupled Climate–Carbon Cycle Model Intercomparison) experiments with these models. Independently of the considered scenario, the proposed generalization describes at global scale the reaction of the climate–carbon system to sufficiently weak perturbations. One prediction from this theory is how the timescale-resolved airborne fraction depends on the underlying feedbacks between climate and the carbon cycle. These feedbacks are expressed as timescale-resolved functions depending solely on analogues of the α , β , and γ sensitivities, introduced in the generalized framework as linear response functions. In this way a feedback-dependent quantity (airborne fraction) is predicted from feedback-independent quantities (the sensitivities). This is the key relation underlying our study. As a preparatory step, we demonstrate the predictive power of the generalized framework exemplarily for simulations with the Max Planck Institute (MPI) Earth System Model. The whole approach turns out to be valid for perturbations of up to an about 100 ppm CO 2 rise above the pre-industrial level; beyond this value the response becomes non-linear. By means of the generalized framework we then derive the timescale dependence of the airborne fraction from the underlying climate–carbon-cycle feedbacks for an ensemble of CMIP5 models. Our analysis reveals that for all studied CMIP5 models (1) the total climate–carbon-cycle feedback is negative at all investigated timescales, (2) the airborne fraction generally decreases for increasing timescales, and (3) the land biogeochemical feedback dominates the model spread in the airborne fraction at all these timescales. Qualitatively similar results were previously found by employing the original α – β – γ framework to particular perturbation scenarios, but our study demonstrates that, although obtained from particular scenario simulations, they are characteristics of the coupled climate–carbon-cycle system as such, valid at all considered timescales. These more general conclusions are obtained by accounting for the internal memory of the system as encoded in the generalized sensitivities, which in contrast to the original α , β , and γ are scenario-independent. [ABSTRACT FROM AUTHOR]

Published
2024
Full Text
View/download PDF

33. Effects of idealised land cover and land management changes on the atmospheric water cycle

Author

De Hertog, Steven J., primary, Lopez Fabara, Carmen E., additional, van der Ent, Ruud, additional, Keune, Jessica, additional, Miralles, Diego G., additional, Portmann, Raphael, additional, Schemm, Sebastian, additional, Havermann, Felix, additional, Guo, Suqi, additional, Luo, Fei, additional, Manola, Iris, additional, Lejeune, Quentin, additional, Pongratz, Julia, additional, Schleussner, Carl-Friedrich, additional, Seneviratne, Sonia I., additional, and Thiery, Wim, additional

Published
2023
Full Text
View/download PDF

34. Global Carbon Budget 2023

Author

Friedlingstein, Pierre, primary, O'Sullivan, Michael, additional, Jones, Matthew W., additional, Andrew, Robbie M., additional, Bakker, Dorothee C. E., additional, Hauck, Judith, additional, Landschützer, Peter, additional, Le Quéré, Corinne, additional, Luijkx, Ingrid T., 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, Anthoni, Peter, additional, Barbero, Leticia, additional, Bates, Nicholas R., additional, Becker, Meike, additional, Bellouin, Nicolas, additional, Decharme, Bertrand, additional, Bopp, Laurent, additional, Brasika, Ida Bagus Mandhara, additional, Cadule, Patricia, additional, Chamberlain, Matthew A., additional, Chandra, Naveen, additional, Chau, Thi-Tuyet-Trang, additional, Chevallier, Frédéric, additional, Chini, Louise P., additional, Cronin, Margot, additional, Dou, Xinyu, additional, Enyo, Kazutaka, additional, Evans, Wiley, additional, Falk, Stefanie, additional, Feely, Richard A., additional, Feng, Liang, additional, Ford, Daniel J., additional, Gasser, Thomas, additional, Ghattas, Josefine, additional, Gkritzalis, Thanos, additional, Grassi, Giacomo, additional, Gregor, Luke, additional, Gruber, Nicolas, additional, Gürses, Özgür, additional, Harris, Ian, additional, Hefner, Matthew, additional, Heinke, Jens, additional, Houghton, Richard A., additional, Hurtt, George C., additional, Iida, Yosuke, additional, Ilyina, Tatiana, additional, Jacobson, Andrew R., additional, Jain, Atul, additional, Jarníková, Tereza, additional, Jersild, Annika, additional, Jiang, Fei, additional, Jin, Zhe, additional, Joos, Fortunat, additional, Kato, Etsushi, additional, Keeling, Ralph F., additional, Kennedy, Daniel, additional, Klein Goldewijk, Kees, additional, Knauer, Jürgen, additional, Korsbakken, Jan Ivar, additional, Körtzinger, Arne, additional, Lan, Xin, additional, Lefèvre, Nathalie, additional, Li, Hongmei, additional, Liu, Junjie, additional, Liu, Zhiqiang, additional, Ma, Lei, additional, Marland, Greg, additional, Mayot, Nicolas, additional, McGuire, Patrick C., additional, McKinley, Galen A., additional, Meyer, Gesa, additional, Morgan, Eric J., additional, Munro, David R., additional, Nakaoka, Shin-Ichiro, additional, Niwa, Yosuke, additional, O'Brien, Kevin M., additional, Olsen, Are, additional, Omar, Abdirahman M., additional, Ono, Tsuneo, additional, Paulsen, Melf, additional, Pierrot, Denis, additional, Pocock, Katie, additional, Poulter, Benjamin, additional, Powis, Carter M., additional, Rehder, Gregor, additional, Resplandy, Laure, additional, Robertson, Eddy, additional, Rödenbeck, Christian, additional, Rosan, Thais M., additional, Schwinger, Jörg, additional, Séférian, Roland, additional, Smallman, T. Luke, additional, Smith, Stephen M., additional, Sospedra-Alfonso, Reinel, additional, Sun, Qing, additional, Sutton, Adrienne J., additional, Sweeney, Colm, additional, Takao, Shintaro, additional, Tans, Pieter P., additional, Tian, Hanqin, additional, Tilbrook, Bronte, additional, Tsujino, Hiroyuki, additional, Tubiello, Francesco, additional, van der Werf, Guido R., additional, van Ooijen, Erik, additional, Wanninkhof, Rik, additional, Watanabe, Michio, additional, Wimart-Rousseau, Cathy, additional, Yang, Dongxu, additional, Yang, Xiaojuan, additional, Yuan, Wenping, additional, Yue, Xu, additional, Zaehle, Sönke, additional, Zeng, Jiye, additional, and Zheng, Bo, additional

Published
2023
Full Text
View/download PDF

36. Supplementary material to "Global Carbon Budget 2023"

Author

Friedlingstein, Pierre, primary, O'Sullivan, Michael, additional, Jones, Matthew W., additional, Andrew, Robbie M., additional, Bakker, Dorothee C. E., additional, Hauck, Judith, additional, Landschützer, Peter, additional, Le Quéré, Corinne, additional, Luijkx, Ingrid T., 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, Anthoni, Peter, additional, Barbero, Leticia, additional, Bates, Nicholas R., additional, Becker, Meike, additional, Bellouin, Nicolas, additional, Decharme, Bertrand, additional, Bopp, Laurent, additional, Brasika, Ida Bagus Mandhara, additional, Cadule, Patricia, additional, Chamberlain, Matthew A., additional, Chandra, Naveen, additional, Chau, Thi-Tuyet-Trang, additional, Chevallier, Frédéric, additional, Chini, Louise P., additional, Cronin, Margot, additional, Dou, Xinyu, additional, Enyo, Kazutaka, additional, Evans, Wiley, additional, Falk, Stefanie, additional, Feely, Richard A., additional, Feng, Liang, additional, Ford, Daniel. J., additional, Gasser, Thomas, additional, Ghattas, Josefine, additional, Gkritzalis, Thanos, additional, Grassi, Giacomo, additional, Gregor, Luke, additional, Gruber, Nicolas, additional, Gürses, Özgür, additional, Harris, Ian, additional, Hefner, Matthew, additional, Heinke, Jens, additional, Houghton, Richard A., additional, Hurtt, George C., additional, Iida, Yosuke, additional, Ilyina, Tatiana, additional, Jacobson, Andrew R., additional, Jain, Atul, additional, Jarníková, Tereza, additional, Jersild, Annika, additional, Jiang, Fei, additional, Jin, Zhe, additional, Joos, Fortunat, additional, Kato, Etsushi, additional, Keeling, Ralph F., additional, Kennedy, Daniel, additional, Klein Goldewijk, Kees, additional, Knauer, Jürgen, additional, Korsbakken, Jan Ivar, additional, Körtzinger, Arne, additional, Lan, Xin, additional, Lefèvre, Nathalie, additional, Li, Hongmei, additional, Liu, Junjie, additional, Liu, Zhiqiang, additional, Ma, Lei, additional, Marland, Greg, additional, Mayot, Nicolas, additional, McGuire, Patrick C., additional, McKinley, Galen A., additional, Meyer, Gesa, additional, Morgan, Eric J., additional, Munro, David R., additional, Nakaoka, Shin-Ichiro, additional, Niwa, Yosuke, additional, O'Brien, Kevin M., additional, Olsen, Are, additional, Omar, Abdirahman M., additional, Ono, Tsuneo, additional, Paulsen, Melf E., additional, Pierrot, Denis, additional, Pocock, Katie, additional, Poulter, Benjamin, additional, Powis, Carter M., additional, Rehder, Gregor, additional, Resplandy, Laure, additional, Robertson, Eddy, additional, Rödenbeck, Christian, additional, Rosan, Thais M., additional, Schwinger, Jörg, additional, Séférian, Roland, additional, Smallman, T. Luke, additional, Smith, Stephen M., additional, Sospedra-Alfonso, Reinel, additional, Sun, Qing, additional, Sutton, Adrienne J., additional, Sweeney, Colm, additional, Takao, Shintaro, additional, Tans, Pieter P., additional, Tian, Hanqin, additional, Tilbrook, Bronte, additional, Tsujino, Hiroyuki, additional, Tubiello, Francesco, additional, van der Werf, Guido R., additional, van Ooijen, Erik, additional, Wanninkhof, Rik, additional, Watanabe, Michio, additional, Wimart-Rousseau, Cathy, additional, Yang, Dongxu, additional, Yang, Xiaojuan, additional, Yuan, Wenping, additional, Yue, Xu, additional, Zaehle, Sönke, additional, Zeng, Jiye, additional, and Zheng, Bo, additional

Published
2023
Full Text
View/download PDF

37. The consolidated European synthesis of CO2 emissions and removals for the European Union and United Kingdom: 1990–2020

Author

McGrath, Matthew J., primary, Petrescu, Ana Maria Roxana, additional, Peylin, Philippe, additional, Andrew, Robbie M., additional, Matthews, Bradley, additional, Dentener, Frank, additional, Balkovič, Juraj, additional, Bastrikov, Vladislav, additional, Becker, Meike, additional, Broquet, Gregoire, additional, Ciais, Philippe, additional, Fortems-Cheiney, Audrey, additional, Ganzenmüller, Raphael, additional, Grassi, Giacomo, additional, Harris, Ian, additional, Jones, Matthew, additional, Knauer, Jürgen, additional, Kuhnert, Matthias, additional, Monteil, Guillaume, additional, Munassar, Saqr, additional, Palmer, Paul I., additional, Peters, Glen P., additional, Qiu, Chunjing, additional, Schelhaas, Mart-Jan, additional, Tarasova, Oksana, additional, Vizzarri, Matteo, additional, Winkler, Karina, additional, Balsamo, Gianpaolo, additional, Berchet, Antoine, additional, Briggs, Peter, additional, Brockmann, Patrick, additional, Chevallier, Frédéric, additional, Conchedda, Giulia, additional, Crippa, Monica, additional, Dellaert, Stijn N. C., additional, Denier van der Gon, Hugo A. C., additional, Filipek, Sara, additional, Friedlingstein, Pierre, additional, Fuchs, Richard, additional, Gauss, Michael, additional, Gerbig, Christoph, additional, Guizzardi, Diego, additional, Günther, Dirk, additional, Houghton, Richard A., additional, Janssens-Maenhout, Greet, additional, Lauerwald, Ronny, additional, Lerink, Bas, additional, Luijkx, Ingrid T., additional, Moulas, Géraud, additional, Muntean, Marilena, additional, Nabuurs, Gert-Jan, additional, Paquirissamy, Aurélie, additional, Perugini, Lucia, additional, Peters, Wouter, additional, Pilli, Roberto, additional, Pongratz, Julia, additional, Regnier, Pierre, additional, Scholze, Marko, additional, Serengil, Yusuf, additional, Smith, Pete, additional, Solazzo, Efisio, additional, Thompson, Rona L., additional, Tubiello, Francesco N., additional, Vesala, Timo, additional, and Walther, Sophia, additional

Published
2023
Full Text
View/download PDF

40. Effects of idealized land cover and land management changes on the atmospheric water cycle.

Author

De Hertog, Steven J., Lopez-Fabara, Carmen E., van der Ent, Ruud, Keune, Jessica, Miralles, Diego G., Portmann, Raphael, Schemm, Sebastian, Havermann, Felix, Guo, Suqi, Luo, Fei, Manola, Iris, Lejeune, Quentin, Pongratz, Julia, Schleussner, Carl-Friedrich, Seneviratne, Sonia I., and Thiery, Wim

Subjects
LAND cover, HYDROLOGIC cycle, HUMIDITY, LAND management, ATMOSPHERIC transport
Abstract

Land cover and land management changes (LCLMCs) play an important role in achieving low-end warming scenarios through land-based mitigation. However, their effects on moisture fluxes and recycling remain uncertain, although they have important implications for the future viability of such strategies. Here, we analyse the impact of idealized LCLMC scenarios on atmospheric moisture transport in three different Earth system model (ESMs): the Community Earth System Model (CESM), the Max Planck Institute Earth System Model (MPI-ESM), and the European Consortium Earth System Model (EC-EARTH). The LCLMC scenarios comprise of a full cropland world, a fully afforested world, and a cropland world with unlimited irrigation expansion. The effects of these LCLMC in the different ESMs are analysed for precipitation, evaporation, and vertically integrated moisture flux convergence to understand the LCLMC-induced changes in the atmospheric moisture cycle. Then, a moisture tracking algorithm is applied to assess the effects of LCLMC on moisture recycling at the local (grid cell level) and the global scale (continental moisture recycling). By applying a moisture tracking algorithm on fully coupled ESM simulations we are able to quantify the complete effects of LCLMC on moisture recycling (including circulation changes), which are generally not considered in moisture recycling studies. Our results indicate that cropland expansion is generally causing a drying and reduced local moisture recycling, while afforestation and irrigation expansion generally cause wetting and increased local moisture recycling. However, the strength of this effect varies across ESMs and shows a large dependency on the dominant driver. Some ESMs show a dominance of large-scale atmospheric circulation changes while other ESMs show a dominance of local to regional changes in the atmospheric water cycle only within the vicinity of the LCLMC. Overall, these results corroborate that LCLMC can induce substantial effects on the atmospheric water cycle and moisture recycling, both through local effects and changes in atmospheric circulation. However, more research is needed to constrain the uncertainty of these effects within ESMs to better inform future land-based mitigation strategies. [ABSTRACT FROM AUTHOR]

Published
2024
Full Text
View/download PDF

41. Pantropical CO2 emissions and removals for the AFOLU sector in the period 1990–2018.

Author

Nyawira, Sylvia S., Herold, Martin, Mulatu, Kalkidan Ayele, Roman-Cuesta, Rosa Maria, Houghton, Richard A., Grassi, Giacomo, Pongratz, Julia, Gasser, Thomas, and Verchot, Louis

Abstract

Transparent, accurate, comparable, and complete estimates of greenhouse gas emissions and removals are needed to support mitigation goals and performance assessments under the Paris Agreement. Here, we present a comparative analysis of the agriculture forestry and other land use (AFOLU) emission estimates from different datasets, including National Greenhouse Gas Inventories (NGHGIs), FAOSTAT, the BLUE, OSCAR, and Houghton (here after updated H&N2017) bookkeeping models; Emissions Database for Global Atmospheric Research (EDGAR); and the US Environmental Protection Agency (EPA). We disaggregate the fluxes for the forestry and other land use (FOLU) sector into forest land, deforestation, and other land uses (including non-forest land uses), while agricultural emissions are disaggregated according to the sources (i.e., livestock, croplands, rice cultivation, and agricultural fires). Considering different time periods (1990–1999, 2000–2010, and 2011–2018), we analyse the trend of the fluxes with a key focus on the tropical regions (i.e., Latin America, sub-Saharan Africa, and South and Southeast Asia). Three of the five data sources indicated a decline in the net emissions over the tropics over the period 1990–2018. The net FOLU emissions for the tropics varied with values of 5.47, 5.22, 4.28, 3.21, and 1.17 GtCO2 year−1 (for BLUE, OSCAR, updated H&N2017, FAOSTAT, and NGHGIs, respectively) over the recent period (2011–2018). Gross deforestation emissions over the same period were 5.87, 7.16, 5.48, 3.96, and 3.74 GtCO2 year−1 (for BLUE, OSCAR, updated H&N2017, FAOSTAT, and NGHGIs). The net forestland sink was −1.97, −3.08, −2.09, −0.53, and −3.00 GtCO2 year−1 (for BLUE, OSCAR, updated H&N2017, FAOSTAT, and NGHGIs). Continental analysis indicated that the differences between the data sources are much large in sub-Saharan Africa and South and Southeast Asia than in Latin America. Disagreements in the FOLU emission estimates are mainly explained by differences in the managed land areas and the processes considered (i.e., direct vs indirect effects of land use change, and gross vs net accounting for deforestation). Net agricultural emissions from cropland, livestock, and rice cultivation were more homogenous across the FAOSTAT, EDGAR, and EPA datasets, with all the data sources indicating an increase in the emissions over the tropics. However, there were notable differences in the emission from agricultural fires. This study highlights the importance of investing and improving data sources for key fluxes to achieve a more robust and transparent global stocktake. [ABSTRACT FROM AUTHOR]

Published
2024
Full Text
View/download PDF

42. Country-level estimates of gross and net carbon fluxes from land use, land-use change and forestry.

Author

Obermeier, Wolfgang Alexander, Schwingshackl, Clemens, Bastos, Ana, Conchedda, Giulia, Gasser, Thomas, Grassi, Giacomo, Houghton, Richard A., Tubiello, Francesco Nicola, Sitch, Stephen, and Pongratz, Julia

Subjects
CARBON emissions, LAND use, CLIMATE change, COUNTRIES, CARBON dioxide, FORESTS & forestry, GREENHOUSE gases
Abstract

The reduction of CO 2 emissions and the enhancement of CO 2 removals related to land use are considered essential for future pathways towards net-zero emissions and mitigating climate change. With the growing pressure under global climate treaties, country-level land-use CO 2 flux data are becoming increasingly important. So far, country-level estimates are mainly available through official country reports, such as the greenhouse gas inventories reported to the United Nations Framework Convention on Climate Change (UNFCCC). Recently, different modelling approaches, namely dynamic global vegetation models (DGVMs) and bookkeeping models, have moved to higher spatial resolutions, which makes it possible to obtain model-based country-level estimates that are globally consistent in their methodology. To progress towards a largely independent assessment of country reports using models, we analyse the robustness of country-level CO 2 flux estimates from different modelling approaches in the period 1950–2021 and compare them with estimates from country reports. Our results highlight the general ability of modelling approaches to estimate land-use CO 2 fluxes at the country level and at higher spatial resolution. Modelled land-use CO 2 flux estimates generally agree well, but the investigation of multiple DGVMs and bookkeeping models reveals that the robustness of their estimates strongly varies across countries, and substantial uncertainties remain, even for top emitters. Similarly, modelled land-use CO 2 flux estimates and country-report-based estimates agree reasonably well in many countries once their differing definitions are accounted for, although differences remain in some other countries. A separate analysis of CO 2 emissions and removals from land use using bookkeeping models also shows that historical peaks in net fluxes stem from emission peaks in most countries, whereas the long-term trends are more connected to removal dynamics. The ratio of the net flux to the sum of CO 2 emissions and removals from land use (the net-to-gross flux ratio) underlines the spatio-temporal heterogeneity in the drivers of net land-use CO 2 flux trends. In many tropical regions, net-to-gross flux ratios of about 50 % are due to much larger emissions than removals; in many temperate countries, ratios close to zero show that emissions and removals largely offset each other. Considering only the net flux thus potentially masks large emissions and removals and the different timescales upon which they act, particularly if averaged over countries or larger regions, highlighting the need for future studies to focus more on the gross fluxes. Data from this study are openly available via the Zenodo portal at 10.5281/zenodo.8144174. [ABSTRACT FROM AUTHOR]

Published
2024
Full Text
View/download PDF

43. Time-scale dependence of airborne fraction and underlying climate-carbon cycle feedbacks for weak perturbations in CMIP5 models

Author

Torres Mendonça, Guilherme L., Reick, Christian H., and Pongratz, Julia

Abstract

The response of the global climate-carbon cycle system to anthropogenic perturbations happens differently at different time scales. The unraveling of the memory structure underlying this time-scale dependence is a major challenge in climate research. Recently the widely applied α-β-γ framework proposed by Friedlingstein et al. (2003) to quantify climate-carbon cycle feedbacks has been generalized to account also for such internal memory. By means of this generalized framework, we investigate the time-scale dependence of the airborne fraction for a set of Earth System Models that participated in CMIP5 (Coupled Model Intercomparison Project Phase 5); the analysis is based on published simulation data from C4MIP-type experiments with these models. Independently of the considered scenario, the proposed generalization describes at global scale the reaction of the climate-carbon system to sufficiently weak perturbations. One prediction from this theory is how the time-scale resolved airborne fraction depends on the underlying feedbacks between climate and carbon cycle. These feedbacks are expressed as time-scale resolved functions depending solely on analogues of the α, β, and γ sensitivities, introduced in the generalized framework as linear response functions. In this way a feedback-dependent quantity (airborne fraction) is predicted from feedback-independent quantities (the sensitivities). This is the key relation underlying our study. As a preparatory step, we demonstrate the predictive power of the generalized framework exemplarily for simulations with the MPI Earth System Model. The whole approach turns out to be valid for perturbations up to about 100 ppm CO2 rise above pre-industrial level; beyond this value the response gets nonlinear. By means of the generalized framework we then derive the time-scale dependence of the airborne fraction from the underlying climate-carbon cycle feedbacks for an ensemble of CMIP5 models. Our analysis reveals that for all studied CMIP5 models (1) the total climate-carbon cycle feedback is negative at all investigated time scales; (2) the airborne fraction generally decreases for increasing time scales; and (3) the land biogeochemical feedback dominates the model spread in the airborne fraction at all these time scales. Qualitatively similar results were previously found by employing the original α-β-γ framework to particular perturbation scenarios, but our study demonstrates that, although obtained from particular scenario simulations, they are characteristics of the coupled climate-carbon cycle system as such, valid at all considered time scales. These more general conclusions are obtained by accounting for the internal memory of the system as encoded in the generalized sensitivities, which in contrast to the original α, β, and γ are scenario-independent.

Published
2023

44. Aufforstung, Wiederaufforstung und nachhaltige Waldbewirtschaftung für die Klimawandelmitigation

Author

Obermeier, Wolfgang, Egerer, Sabine, and Pongratz, Julia

Subjects
Afforestation, reforestation, sustainable forest management, climate change mitigation, negative emission technologies (NET), forest productivity, wood for energy, wood extraction
Abstract

Afforestation, reforestation and sustainable forest management for climate change mitigation: Afforestation, reforesta­tion, and sustainable forest management are considered accepted negative emission technologies (NET) with great potential for climate change mitigation. However, future forest development is highly dependent on changing environmental conditions as well as adapted forest management. For example, the increase and intensification of disturbances and extreme weather conditions (e.g., windthrow, insect infestations, fires, and drought) can greatly reduce forest productivity, especially in monocultures; at the same time, rising atmospheric CO2 concentrations and forest productivity extended into boreal latitudes can favor the NET potential. In addition, the way wood products are used affects the future NET potential. For example, long-term usage as construction timber is particularly effective, especially if it replaces fossil building materials. Similarly, the usage of wood for energy can mitigate climate change, provided that wood extraction does not exceed regrowth. Biogeophysical effects can also influence local and non-local climate, for example through changes in albedo, roughness, and transpiration. This occurs depending on local conditions as well as forestry adaptation and underscores the need to weigh the various effects of an action that affect climate. In addition, a variety of potentially positive as well as negative side effects on other ecosystem services must be considered - most importantly, biodiversity, water availability, and the need for land for food production.

Published
2023
Full Text
View/download PDF

45. Indicators of Global Climate Change 2022: annual update of large-scale indicators of the state of the climate system and human influence

Author

Forster, Piers M., primary, Smith, Christopher J., additional, Walsh, Tristram, additional, Lamb, William F., additional, Lamboll, Robin, additional, Hauser, Mathias, additional, Ribes, Aurélien, additional, Rosen, Debbie, additional, Gillett, Nathan, additional, Palmer, Matthew D., additional, Rogelj, Joeri, additional, von Schuckmann, Karina, additional, Seneviratne, Sonia I., additional, Trewin, Blair, additional, Zhang, Xuebin, additional, Allen, Myles, additional, Andrew, Robbie, additional, Birt, Arlene, additional, Borger, Alex, additional, Boyer, Tim, additional, Broersma, Jiddu A., additional, Cheng, Lijing, additional, Dentener, Frank, additional, Friedlingstein, Pierre, additional, Gutiérrez, José M., additional, Gütschow, Johannes, additional, Hall, Bradley, additional, Ishii, Masayoshi, additional, Jenkins, Stuart, additional, Lan, Xin, additional, Lee, June-Yi, additional, Morice, Colin, additional, Kadow, Christopher, additional, Kennedy, John, additional, Killick, Rachel, additional, Minx, Jan C., additional, Naik, Vaishali, additional, Peters, Glen P., additional, Pirani, Anna, additional, Pongratz, Julia, additional, Schleussner, Carl-Friedrich, additional, Szopa, Sophie, additional, Thorne, Peter, additional, Rohde, Robert, additional, Rojas Corradi, Maisa, additional, Schumacher, Dominik, additional, Vose, Russell, additional, Zickfeld, Kirsten, additional, Masson-Delmotte, Valérie, additional, and Zhai, Panmao, additional

Published
2023
Full Text
View/download PDF

48. Indicators of Global Climate Change 2022: Annual update of large-scale indicators of the state of the climate system and the human influence

Author

Forster, Piers Maxwell, primary, Smith, Christopher J., additional, Walsh, Tristram, additional, Lamb, William F., additional, Palmer, Matthew D., additional, von Schuckmann, Karina, additional, Trewin, Blair, additional, Allen, Myles, additional, Andrew, Robbie, additional, Birt, Arlene, additional, Borger, Alex, additional, Boyer, Tim, additional, Broersma, Jiddu A., additional, Cheng, Lijing, additional, Dentener, Frank, additional, Friedlingstein, Pierre, additional, Gillett, Nathan, additional, Gutiérrez, José M., additional, Gütschow, Johannes, additional, Hauser, Mathias, additional, Hall, Bradley, additional, Ishii, Masayoshi, additional, Jenkins, Stuart, additional, Lamboll, Robin, additional, Lan, Xin, additional, Lee, June-Yi, additional, Morice, Colin, additional, Kadow, Christopher, additional, Kennedy, John, additional, Killick, Rachel, additional, Minx, Jan, additional, Naik, Vaishali, additional, Peters, Glen, additional, Pirani, Anna, additional, Pongratz, Julia, additional, Ribes, Aurélien, additional, Rogelj, Joeri, additional, Rosen, Debbie, additional, Schleussner, Carl-Friedrich, additional, Seneviratne, Sonia, additional, Szopa, Sophie, additional, Thorne, Peter, additional, Rohde, Robert, additional, Rojas Corradi, Maisa, additional, Schumacher, Dominik, additional, Vose, Russell, additional, Zickfeld, Kirsten, additional, Zhang, Xuebin, additional, Masson-Delmotte, Valérie, additional, and Zhai, Panmao, additional

Published
2023
Full Text
View/download PDF

49. 10 New Insights in Climate Science 2023/2024

Author

Bustamante, Mercedes, Roy, Joyashree, Ospina, Daniel, Achakulwisut, Ploy, Aggarwal, Anubha, Bastos, Ana, Broadgate, Wendy, Canadell, Josep G., Carr, Edward R., Chen, Deliang, Cleugh, Helen A., Ebi, Kristie L., Edwards, Clea, Farbotko, Carol, Fernández-Martínez, Marcos, Frölicher, Thomas L., Fuss, Sabine, Geden, Oliver, Gruber, Nicolas, Harrington, Luke J., Hauck, Judith, Hausfather, Zeke, Hebden, Sophie, Hebinck, Aniek, Huq, Saleemul, Huss, Matthias, Jamero, Laurice P., Juhola, Sirkku, Kumarasinghe, Nilushi, Lwasa, Shuaib, Mallick, Bishawjit, Martin, Maria, McGreevy, Steven, Mirazo, Paula, Mukherji, Aditi, Muttitt, Greg, Nemet, Gregory F., Obura, David, Okereke, Chukwumerije, Oliver, Tom, Orlove, Ben, Ouedraogo, Nadia S., Patra, Prabir K., Pelling, Mark, Pereira, Laura M., Persson, Åsa, Pongratz, Julia, Prakash, Anjal, Rammig, Anja, Raymond, Colin, Redman, Aaron, Reveco, Cristobal, Rockström, Johan, Rodrigues, Regina, Rounce, David R., Schipper, Lisa F., Schlosser, Peter, Selomane, Odirilwe, Semieniuk, Gregor, Shin, Yunne Jai, Siddiqui, Tasneem A., Singh, Vartika, Sioen, Giles B., Sokona, Youba, Stammer, Detlef, Steinert, Norman J., Suk, Sunhee, Sutton, Rowan, Thalheimer, Lisa, Thompson, Vikki, Trencher, Gregory, Van Der Geest, Kees, Werners, Saskia E., Wübbelmann, Thea, Wunderling, Nico, Yin, Jiabo, Zickfeld, Kirsten, Zscheischler, Jakob, Blome, Tanja, Wolff, Maria, Bustamante, Mercedes, Roy, Joyashree, Ospina, Daniel, Achakulwisut, Ploy, Aggarwal, Anubha, Bastos, Ana, Broadgate, Wendy, Canadell, Josep G., Carr, Edward R., Chen, Deliang, Cleugh, Helen A., Ebi, Kristie L., Edwards, Clea, Farbotko, Carol, Fernández-Martínez, Marcos, Frölicher, Thomas L., Fuss, Sabine, Geden, Oliver, Gruber, Nicolas, Harrington, Luke J., Hauck, Judith, Hausfather, Zeke, Hebden, Sophie, Hebinck, Aniek, Huq, Saleemul, Huss, Matthias, Jamero, Laurice P., Juhola, Sirkku, Kumarasinghe, Nilushi, Lwasa, Shuaib, Mallick, Bishawjit, Martin, Maria, McGreevy, Steven, Mirazo, Paula, Mukherji, Aditi, Muttitt, Greg, Nemet, Gregory F., Obura, David, Okereke, Chukwumerije, Oliver, Tom, Orlove, Ben, Ouedraogo, Nadia S., Patra, Prabir K., Pelling, Mark, Pereira, Laura M., Persson, Åsa, Pongratz, Julia, Prakash, Anjal, Rammig, Anja, Raymond, Colin, Redman, Aaron, Reveco, Cristobal, Rockström, Johan, Rodrigues, Regina, Rounce, David R., Schipper, Lisa F., Schlosser, Peter, Selomane, Odirilwe, Semieniuk, Gregor, Shin, Yunne Jai, Siddiqui, Tasneem A., Singh, Vartika, Sioen, Giles B., Sokona, Youba, Stammer, Detlef, Steinert, Norman J., Suk, Sunhee, Sutton, Rowan, Thalheimer, Lisa, Thompson, Vikki, Trencher, Gregory, Van Der Geest, Kees, Werners, Saskia E., Wübbelmann, Thea, Wunderling, Nico, Yin, Jiabo, Zickfeld, Kirsten, Zscheischler, Jakob, Blome, Tanja, and Wolff, Maria

Abstract

Each year, Future Earth, the Earth League and the World Climate Research Programme gather leading scholars from around the world to review the most pressing findings in climate research. The result is the 10 New Insights in Climate Science, delivered as two self-standing products: a peer-reviewed scientific article and this policy report providing a rich and valuable synthesis for policymakers and society at large. The scientific evidence underpinning this year’s report was published between January 2022–June 2023. For policymakers responding to the urgent challenge of the climate crisis, the 10 New Insights in Climate Science 2023/2024 offers credible guidance through 2024 and beyond.

Published
2023

50. The drivers and impacts of Amazon forest degradation

Author

Lapola, David M., Pinho, Patricia, Barlow, Jos, Aragão, Luiz E. O. C., Berenguer, Erika, Carmenta, Rachel, Liddy, Hannah M., Seixas, Hugo, Silva, Camila V. J., Silva-Junior, Celso H. L., Alencar, Ane A. C., Anderson, Liana O., Armenteras, Dolors, Brovkin, Victor, Calders, Kim, Chambers, Jeffrey, Chini, Louise, Costa, Marcos H., Faria, Bruno L., Fearnside, Philip M., Ferreira, Joice, Gatti, Luciana, Gutierrez-Velez, Victor Hugo, Han, Zhangang, Hibbard, Kathleen, Koven, Charles, Lawrence, Peter, Pongratz, Julia, Portela, Bruno T. T., Rounsevell, Mark, Ruane, Alex C., Schaldach, Rüdiger, da Silva, Sonaira S., von Randow, Celso, Walker, Wayne S., Lapola, David M., Pinho, Patricia, Barlow, Jos, Aragão, Luiz E. O. C., Berenguer, Erika, Carmenta, Rachel, Liddy, Hannah M., Seixas, Hugo, Silva, Camila V. J., Silva-Junior, Celso H. L., Alencar, Ane A. C., Anderson, Liana O., Armenteras, Dolors, Brovkin, Victor, Calders, Kim, Chambers, Jeffrey, Chini, Louise, Costa, Marcos H., Faria, Bruno L., Fearnside, Philip M., Ferreira, Joice, Gatti, Luciana, Gutierrez-Velez, Victor Hugo, Han, Zhangang, Hibbard, Kathleen, Koven, Charles, Lawrence, Peter, Pongratz, Julia, Portela, Bruno T. T., Rounsevell, Mark, Ruane, Alex C., Schaldach, Rüdiger, da Silva, Sonaira S., von Randow, Celso, and Walker, Wayne S.

Abstract

Approximately 2.5 × 10 6 square kilometers of the Amazon forest are currently degraded by fire, edge effects, timber extraction, and/or extreme drought, representing 38% of all remaining forests in the region. Carbon emissions from this degradation total up to 0.2 petagrams of carbon per year (Pg C year −1 ), which is equivalent to, if not greater than, the emissions from Amazon deforestation (0.06 to 0.21 Pg C year −1 ). Amazon forest degradation can reduce dry-season evapotranspiration by up to 34% and cause as much biodiversity loss as deforestation in human-modified landscapes, generating uneven socioeconomic burdens, mainly to forest dwellers. Projections indicate that degradation will remain a dominant source of carbon emissions independent of deforestation rates. Policies to tackle degradation should be integrated with efforts to curb deforestation and complemented with innovative measures addressing the disturbances that degrade the Amazon forest.

Published
2023

Catalog

Books, media, physical & digital resources
See catalog results