Your search keyword '"Lomax, Guy"' showing total 25 results

1. National mitigation potential from natural climate solutions in the tropics

Author

Griscom, Bronson W., Busch, Jonah, Cook-Patton, Susan C., Ellis, Peter W., Funk, Jason, Leavitt, Sara M., Lomax, Guy, Turner, Will R., Chapman, Melissa, Engelmann, Jens, Gurwick, Noel P., Landis, Emily, Lawrence, Deborah, Malhi, Yadvinder, Murray, Lisa Schindler, Navarrete, Diego, Roe, Stephanie, Scull, Sabrina, Smith, Pete, Streck, Charlotte, Walker, Wayne S., and Worthington, Thomas

Published

2020

2. Climate policy decision making in contexts of deep uncertainty - from optimisation to robustness

Author

Workman, Mark, Darch, Geoff, Dooley, Kate, Lomax, Guy, Maltby, James, and Pollitt, Hector

Published

2021

3. Optimizing restoration: A holistic spatial approach to deliver Nature's Contributions to People with minimal tradeoffs and maximal equity.

Author

Gopalakrishna, Trisha, Visconti, Piero, Lomax, Guy, Boere, Esther, Malhi, Yadvinder, Roy, Parth Sarathi, Joshi, Pawan K., Fedele, Giacomo, and Ping Yowargana

Subjects

CLIMATE change mitigation, FOREST restoration, RESTORATION ecology, HOUSE construction, REFORESTATION

Abstract

Ecosystem restoration is inherently a complex activity with inevitable tradeoffs in environmental and societal outcomes. These tradeoffs can potentially be large when policies and practices are focused on single outcomes versus joint achievement of multiple outcomes. Few studies have assessed the tradeoffs in Nature's Contributions to People (NCP) and the distributional equity of NCP from forest restoration strategies. Here, we optimized a defined forest restoration area across India with systematic conservation planning to assess the tradeoffs between three NCP: i) climate change mitigation NCP, ii) biodiversity value NCP (habitat created for forest-dependent mammals), and iii) societal NCP (human direct use of restored forests for livelihoods, housing construction material, and energy). We show that restoration plans aimed at a single-NCP tend not to deliver other NCP outcomes efficiently. In contrast, integrated spatial forest restoration plans aimed at achievement of multiple outcomes deliver on average 83.3% (43.2 to 100%) of climate change mitigation NCP, 89.9% (63.8 to 100%) of biodiversity value NCP, and 93.9% (64.5 to 100%) of societal NCP delivered by single-objective plans. Integrated plans deliver NCP more evenly across the restoration area when compared to other plans that identify certain regions such as the Western Ghats and north-eastern India. Last, 38 to 41% of the people impacted by integrated spatial plans belong to socioeconomically disadvantaged groups, greater than their overall representation in India's population. Moving ahead, effective policy design and evaluation integrating ecosystem protection and restoration strategies can benefit from the blueprint we provide in this study for India. [ABSTRACT FROM AUTHOR]

Published

2024

4. Decision making in contexts of deep uncertainty - An alternative approach for long-term climate policy

Author

Workman, Mark, Dooley, Kate, Lomax, Guy, Maltby, James, and Darch, Geoff

Published

2020

5. Mapping carbon accumulation potential from global natural forest regrowth

Author

Cook-Patton, Susan C., Leavitt, Sara M., Gibbs, David, Harris, Nancy L., Lister, Kristine, Anderson-Teixeira, Kristina J., Briggs, Russell D., Chazdon, Robin L., Crowther, Thomas W., Ellis, Peter W., Griscom, Heather P., Herrmann, Valentine, Holl, Karen D., Houghton, Richard A., Larrosa, Cecilia, Lomax, Guy, Lucas, Richard, Madsen, Palle, Malhi, Yadvinder, Paquette, Alain, Parker, John D., Paul, Keryn, Routh, Devin, Roxburgh, Stephen, Saatchi, Sassan, van den Hoogen, Johan, Walker, Wayne S., Wheeler, Charlotte E., Wood, Stephen A., Xu, Liang, and Griscom, Bronson W.

Published

2020

6. Natural climate solutions

Author

Griscom, Bronson W., Adams, Justin, Ellis, Peter W., Houghton, Richard A., Lomax, Guy, Miteva, Daniela A., Schlesinger, William H., Shoch, David, Siikamäki, Juha V., Smith, Pete, Woodbury, Peter, Zganjar, Chris, Blackman, Allen, Campari, João, Conant, Richard T., Delgado, Christopher, Elias, Patricia, Gopalakrishna, Trisha, Hamsik, Marisa R., Herrero, Mario, Kiesecker, Joseph, Landis, Emily, Laestadius, Lars, Leavitt, Sara M., Minnemeyer, Susan, Polasky, Stephen, Potapov, Peter, Putz, Francis E., Sanderman, Jonathan, Silvius, Marcel, Wollenberg, Eva, and Fargione, Joseph

Published

2017

7. Reframing the policy approach to greenhouse gas removal technologies

Author

Lomax, Guy, Workman, Mark, Lenton, Timothy, and Shah, Nilay

Published

2015

8. The Value of Land Restoration as a Response to Climate Change

Author

Lomax, Guy, primary

Published

2016

9. Contributors

Author

Akça, Erhan, primary, Alexander, Sasha, additional, Bar (Kutiel), Pua, additional, Barbut, Monique, additional, Becker, Nir, additional, Behrend, Hartmut, additional, Birch, Julia, additional, Boesen, Lili Hernandez, additional, van den Broeck, Dieter, additional, Buckingham, Kathleen, additional, Buono, Jared, additional, Burger, Kees, additional, Catacutan, Delia C., additional, Chabay, Ilan, additional, Channer, Alan, additional, Davies, Jonathan, additional, DeWitt, Sean, additional, Dietz, Ton, additional, Duncan, Tom, additional, Etter, Hannes, additional, Ferwerda, Willem H., additional, Finnegan, Lynn, additional, Francis, Rob, additional, Freeman, Stephen, additional, van der Geest, Kees, additional, Gnacadja, Luc, additional, Hiller, Bradley T., additional, Hinton, Stephen, additional, Jayaram, Dhanasree, additional, Kang'ee, Ednah, additional, Kent, Rhamis, additional, Koelle, Bettina, additional, Koniuszewski, Adam, additional, Laestadius, Lars, additional, Lal, Rattan, additional, Liniger, Hanspeter, additional, Liu, John D., additional, Lomax, Guy, additional, McAllister, Georgina, additional, Montanarella, Luca, additional, Mulligan, Mark, additional, Nenova, Stela, additional, Oettle, Noel, additional, Providoli, Isabelle, additional, Rao, Jayashree, additional, Rinaudo, Tony, additional, Sato, Tetsu, additional, Savory, Allan, additional, Segev, Meira, additional, Studer, Rima Mekdaschi, additional, Takashi, Kume, additional, Talbot, Maura, additional, Thompson-Hall, Mary, additional, Villamor, Grace B., additional, Weston, Peter, additional, Wilhite, Donald A., additional, and Yelfaanibe, Augustine, additional

Published

2016

10. Existing land uses constrain climate change mitigation potential of forest restoration in India

Author

Gopalakrishna, Trisha, primary, Lomax, Guy, additional, Aguirre‐Gutiérrez, Jesús, additional, Bauman, David, additional, Roy, Parth Sarathi, additional, Joshi, Pawan K., additional, and Malhi, Yadvinder, additional

Published

2022

11. What Is the Impact of Mass Timber Utilization on Climate and Forests?

Author

Pasternack, Rachel, primary, Wishnie, Mark, additional, Clarke, Caitlin, additional, Wang, Yangyang, additional, Belair, Ethan, additional, Marshall, Steve, additional, Gu, Hongmei, additional, Nepal, Prakash, additional, Dolezal, Franz, additional, Lomax, Guy, additional, Johnston, Craig, additional, Felmer, Gabriel, additional, Morales-Vera, Rodrigo, additional, Puettmann, Maureen, additional, and Van den Huevel, Robyn, additional

Published

2022

12. Land-based measures to mitigate climate change: Potential and feasibility by country

Author

Roe, Stephanie, Streck, Charlotte, Beach, Robert, Busch, Jonah, Chapman, Melissa, Daioglou, Vassilis, Deppermann, Andre, Doelman, Jonathan, Emmet-Booth, Jeremy, Engelmann, Jens, Fricko, Oliver, Frischmann, Chad, Funk, Jason, Grassi, Giacomo, Griscom, Bronson, Havlik, Petr, Hanssen, Steef, Humpenöder, Florian, Landholm, David, Lomax, Guy, Lehmann, Johannes, Mesnildrey, Leah, Nabuurs, Gert-Jan, Popp, Alexander, Rivard, Charlotte, Sanderman, Jonathan, Sohngen, Brent, Smith, Pete, Stehfest, Elke, Woolf, Dominic, Lawrence, Deborah, Integr. Assessm. Global Environm. Change, Environmental Sciences, Integr. Assessm. Global Environm. Change, and Environmental Sciences

Subjects

Demand management, 010504 meteorology & atmospheric sciences, Natural resource economics, 020209 energy, demand management, Climate Change, Bos- en Landschapsecologie, Land management, Developing country, Climate change, AFOLU, 02 engineering and technology, 01 natural sciences, natural climate solutions, mitigation, Environmental Science(all), 11. Sustainability, 0202 electrical engineering, electronic engineering, information engineering, co-benefits, Environmental Chemistry, Forest and Landscape Ecology, Vegetatie, nature-based solutions, Ecosystem, 0105 earth and related environmental sciences, General Environmental Science, 2. Zero hunger, Global and Planetary Change, Vegetation, Ecology, business.industry, Corporate governance, 1. No poverty, land management, Agriculture, 15. Life on land, Investment (macroeconomics), Private sector, PE&RC, Policy, 13. Climate action, land sector, Feasibility Studies, Vegetatie, Bos- en Landschapsecologie, Vegetation, Forest and Landscape Ecology, Business, feasibility

Abstract

Land-based climate mitigation measures have gained significant attention and importance in public and private sector climate policies. Building on previous studies, we refine and update the mitigation potentials for 20 land-based measures in >200 countries and five regions, comparing "bottom-up" sectoral estimates with integrated assessment models (IAMs). We also assess implementation feasibility at the country level. Cost-effective (available up to $100/tCO2 eq) land-based mitigation is 8-13.8 GtCO2 eq yr-1 between 2020 and 2050, with the bottom end of this range representing the IAM median and the upper end representing the sectoral estimate. The cost-effective sectoral estimate is about 40% of available technical potential and is in line with achieving a 1.5°C pathway in 2050. Compared to technical potentials, cost-effective estimates represent a more realistic and actionable target for policy. The cost-effective potential is approximately 50% from forests and other ecosystems, 35% from agriculture, and 15% from demand-side measures. The potential varies sixfold across the five regions assessed (0.75-4.8 GtCO2eq yr-1 ) and the top 15 countries account for about 60% of the global potential. Protection of forests and other ecosystems and demand-side measures present particularly high mitigation efficiency, high provision of co-benefits, and relatively lower costs. The feasibility assessment suggests that governance, economic investment, and socio-cultural conditions influence the likelihood that land-based mitigation potentials are realized. A substantial portion of potential (80%) is in developing countries and LDCs, where feasibility barriers are of greatest concern. Assisting countries to overcome barriers may result in significant quantities of near-term, low-cost mitigation while locally achieving important climate adaptation and development benefits. Opportunities among countries vary widely depending on types of land-based measures available, their potential co-benefits and risks, and their feasibility. Enhanced investments and country-specific plans that accommodate this complexity are urgently needed to realize the large global potential from improved land stewardship.

Published

2021

13. Land-based measures to mitigate climate change: Potential and feasibility by country

Author

Integr. Assessm. Global Environm. Change, Environmental Sciences, Roe, Stephanie, Streck, Charlotte, Beach, Robert, Busch, Jonah, Chapman, Melissa, Daioglou, Vassilis, Deppermann, Andre, Doelman, Jonathan, Emmet-Booth, Jeremy, Engelmann, Jens, Fricko, Oliver, Frischmann, Chad, Funk, Jason, Grassi, Giacomo, Griscom, Bronson, Havlik, Petr, Hanssen, Steef, Humpenöder, Florian, Landholm, David, Lomax, Guy, Lehmann, Johannes, Mesnildrey, Leah, Nabuurs, Gert-Jan, Popp, Alexander, Rivard, Charlotte, Sanderman, Jonathan, Sohngen, Brent, Smith, Pete, Stehfest, Elke, Woolf, Dominic, Lawrence, Deborah, Integr. Assessm. Global Environm. Change, Environmental Sciences, Roe, Stephanie, Streck, Charlotte, Beach, Robert, Busch, Jonah, Chapman, Melissa, Daioglou, Vassilis, Deppermann, Andre, Doelman, Jonathan, Emmet-Booth, Jeremy, Engelmann, Jens, Fricko, Oliver, Frischmann, Chad, Funk, Jason, Grassi, Giacomo, Griscom, Bronson, Havlik, Petr, Hanssen, Steef, Humpenöder, Florian, Landholm, David, Lomax, Guy, Lehmann, Johannes, Mesnildrey, Leah, Nabuurs, Gert-Jan, Popp, Alexander, Rivard, Charlotte, Sanderman, Jonathan, Sohngen, Brent, Smith, Pete, Stehfest, Elke, Woolf, Dominic, and Lawrence, Deborah

Published

2021

14. We need both natural and energy solutions to stabilize our climate

Author

Griscom, Bronson W., primary, Lomax, Guy, additional, Kroeger, Timm, additional, Fargione, Joseph E., additional, Adams, Justin, additional, Almond, Lucy, additional, Bossio, Deborah, additional, Cook‐Patton, Susan C., additional, Ellis, Peter W., additional, Kennedy, Christina M., additional, and Kiesecker, Joseph, additional

Published

2019

15. Natural climate solutions for the United States

Author

Fargione, Joseph E., Bassett, Steven, Boucher, Timothy, Bridgham, Scott D., Conant, Richard T., Cook-Patton, Susan C., Ellis, Peter W., Falcucci, Alessandra, Fourqurean, James W., Gopalakrishna, Trisha, Gu, Huan, Henderson, Benjamin, Hurteau, Matthew D., Kroeger, Kevin D., Kroeger, Timm, Lark, Tyler J., Leavitt, Sara M., Lomax, Guy, McDonald, Robert I., Megonigal, J. Patrick, Miteva, Daniela A., Richardson, Curtis J., Sanderman, Jonathan, Shoch, David, Spawn, Seth A., Veldman, Joseph W., Williams, Christopher A., Woodbury, Peter B., Zganjar, Chris, Baranski, Marci, Elias, Patricia, Houghton, Richard A., Landis, Emily, McGlynn, Emily, Schlesinger, William H., Siikamaki, Juha V., Sutton-Grier, Ariana E., Griscom, Bronson W., Fargione, Joseph E., Bassett, Steven, Boucher, Timothy, Bridgham, Scott D., Conant, Richard T., Cook-Patton, Susan C., Ellis, Peter W., Falcucci, Alessandra, Fourqurean, James W., Gopalakrishna, Trisha, Gu, Huan, Henderson, Benjamin, Hurteau, Matthew D., Kroeger, Kevin D., Kroeger, Timm, Lark, Tyler J., Leavitt, Sara M., Lomax, Guy, McDonald, Robert I., Megonigal, J. Patrick, Miteva, Daniela A., Richardson, Curtis J., Sanderman, Jonathan, Shoch, David, Spawn, Seth A., Veldman, Joseph W., Williams, Christopher A., Woodbury, Peter B., Zganjar, Chris, Baranski, Marci, Elias, Patricia, Houghton, Richard A., Landis, Emily, McGlynn, Emily, Schlesinger, William H., Siikamaki, Juha V., Sutton-Grier, Ariana E., and Griscom, Bronson W.

Abstract

© The Author(s), 2018. This article is distributed under the terms of the Creative Commons Attribution License. The definitive version was published in Science Advances 4 (2018): eaat1869, doi:10.1126/sciadv.aat1869., Limiting climate warming to <2°C requires increased mitigation efforts, including land stewardship, whose potential in the United States is poorly understood. We quantified the potential of natural climate solutions (NCS)—21 conservation, restoration, and improved land management interventions on natural and agricultural lands—to increase carbon storage and avoid greenhouse gas emissions in the United States. We found a maximum potential of 1.2 (0.9 to 1.6) Pg CO2e year−1, the equivalent of 21% of current net annual emissions of the United States. At current carbon market prices (USD 10 per Mg CO2e), 299 Tg CO2e year−1 could be achieved. NCS would also provide air and water filtration, flood control, soil health, wildlife habitat, and climate resilience benefits., This study was made possible by funding from the Doris Duke Charitable Foundation. C.A.W. and H.G. acknowledge financial support from NASA’s Carbon Monitoring System program (NNH14ZDA001N-CMS) under award NNX14AR39G. S.D.B. acknowledges support from the DOE’s Office of Biological and Environmental Research Program under the award DE-SC0014416. J.W.F. acknowledges financial support from the Florida Coastal Everglades Long-Term Ecological Research program under National Science Foundation grant no. DEB-1237517.

Published

2018

16. Natural climate solutions for the United States

Author

Fargione, Joseph E., primary, Bassett, Steven, additional, Boucher, Timothy, additional, Bridgham, Scott D., additional, Conant, Richard T., additional, Cook-Patton, Susan C., additional, Ellis, Peter W., additional, Falcucci, Alessandra, additional, Fourqurean, James W., additional, Gopalakrishna, Trisha, additional, Gu, Huan, additional, Henderson, Benjamin, additional, Hurteau, Matthew D., additional, Kroeger, Kevin D., additional, Kroeger, Timm, additional, Lark, Tyler J., additional, Leavitt, Sara M., additional, Lomax, Guy, additional, McDonald, Robert I., additional, Megonigal, J. Patrick, additional, Miteva, Daniela A., additional, Richardson, Curtis J., additional, Sanderman, Jonathan, additional, Shoch, David, additional, Spawn, Seth A., additional, Veldman, Joseph W., additional, Williams, Christopher A., additional, Woodbury, Peter B., additional, Zganjar, Chris, additional, Baranski, Marci, additional, Elias, Patricia, additional, Houghton, Richard A., additional, Landis, Emily, additional, McGlynn, Emily, additional, Schlesinger, William H., additional, Siikamaki, Juha V., additional, Sutton-Grier, Ariana E., additional, and Griscom, Bronson W., additional

Published

2018

17. Chapter 3.2 - The Value of Land Restoration as a Response to Climate Change

Author

Lomax, Guy

Published

2015

18. Investing in negative emissions

Author

Lomax, Guy, primary, Lenton, Timothy M., additional, Adeosun, Adepeju, additional, and Workman, Mark, additional

Published

2015

19. Contributors

Author

Akça, Erhan, Alexander, Sasha, Bar (Kutiel), Pua, Barbut, Monique, Becker, Nir, Behrend, Hartmut, Birch, Julia, Boesen, Lili Hernandez, van den Broeck, Dieter, Buckingham, Kathleen, Buono, Jared, Burger, Kees, Catacutan, Delia C., Chabay, Ilan, Channer, Alan, Davies, Jonathan, DeWitt, Sean, Dietz, Ton, Duncan, Tom, Etter, Hannes, Ferwerda, Willem H., Finnegan, Lynn, Francis, Rob, Freeman, Stephen, van der Geest, Kees, Gnacadja, Luc, Hiller, Bradley T., Hinton, Stephen, Jayaram, Dhanasree, Kang'ee, Ednah, Kent, Rhamis, Koelle, Bettina, Koniuszewski, Adam, Laestadius, Lars, Lal, Rattan, Liniger, Hanspeter, Liu, John D., Lomax, Guy, McAllister, Georgina, Montanarella, Luca, Mulligan, Mark, Nenova, Stela, Oettle, Noel, Providoli, Isabelle, Rao, Jayashree, Rinaudo, Tony, Sato, Tetsu, Savory, Allan, Segev, Meira, Studer, Rima Mekdaschi, Takashi, Kume, Talbot, Maura, Thompson-Hall, Mary, Villamor, Grace B., Weston, Peter, Wilhite, Donald A., and Yelfaanibe, Augustine

Published

2015

20. Methods Details from National mitigation potential from natural climate solutions in the tropics

Author

Griscom, Bronson W., Busch, Jonah, Cook-Patton, Susan C., Ellis, Peter W., Funk, Jason, Leavitt, Sara M., Lomax, Guy, Turner, Will, Chapman, Melissa, Engelmann, Jens, Gurwick, Noel P., Landis, Emily, Lawrence, Deborah, Yadvinder Malhi, Murray, Lisa Schindler, Navarrete, Diego, Roe, Stephanie, Scull, Sabrina, Smith, Pete, Streck, Charlotte, Walker, Wayne S., and Worthington, Thomas

Subjects

13. Climate action, 11. Sustainability, 1. No poverty, 15. Life on land, 12. Responsible consumption

Abstract

Better land stewardship is needed to achieve the Paris Agreement's temperature goal, particularly in the tropics where greenhouse gas emissions from the destruction of ecosystems are largest, and where the potential for additional land carbon storage is greatest. As countries enhance their nationally determined contributions (NDCs) to the Paris Agreement, confusion persists about the potential contribution of better land stewardship to meeting the Agreement's goal to hold global warming below 2°C. We assess cost-effective tropical country-level potential of natural climate solutions (NCS): protection, improved management and restoration of ecosystems to deliver climate mitigation linked with sustainable development goals (SDGs). We identify groups of countries with distinctive NCS portfolios, and we explore factors (governance, financial capacity) influencing the feasibility of unlocking national NCS potential. Cost-effective tropical NCS offers globally significant climate mitigation in the coming decades (6.56 PgCO2e yr−1 at less than 100 USD MgCO2e−1). In half of the tropical countries, cost-effective NCS could mitigate over half of national emissions. In more than a quarter of tropical countries, cost-effective NCS potential is greater than national emissions. We identify countries where, with international financing and political will, NCS can cost-effectively deliver the majority of enhanced NDCs while transforming national economies and contributing to SDGs.This article is part of the theme issue ‘Climate change and ecosystems: threats, opportunities and solutions’.

21. Methods Details from National mitigation potential from natural climate solutions in the tropics

Author

Griscom, Bronson W., Busch, Jonah, Cook-Patton, Susan C., Ellis, Peter W., Funk, Jason, Leavitt, Sara M., Lomax, Guy, Turner, Will, Chapman, Melissa, Engelmann, Jens, Gurwick, Noel P., Landis, Emily, Lawrence, Deborah, Yadvinder Malhi, Murray, Lisa Schindler, Navarrete, Diego, Roe, Stephanie, Scull, Sabrina, Smith, Pete, Streck, Charlotte, Walker, Wayne S., and Worthington, Thomas

Subjects

13. Climate action, 11. Sustainability, 1. No poverty, 15. Life on land, 12. Responsible consumption

Abstract

Better land stewardship is needed to achieve the Paris Agreement's temperature goal, particularly in the tropics where greenhouse gas emissions from the destruction of ecosystems are largest, and where the potential for additional land carbon storage is greatest. As countries enhance their nationally determined contributions (NDCs) to the Paris Agreement, confusion persists about the potential contribution of better land stewardship to meeting the Agreement's goal to hold global warming below 2°C. We assess cost-effective tropical country-level potential of natural climate solutions (NCS): protection, improved management and restoration of ecosystems to deliver climate mitigation linked with sustainable development goals (SDGs). We identify groups of countries with distinctive NCS portfolios, and we explore factors (governance, financial capacity) influencing the feasibility of unlocking national NCS potential. Cost-effective tropical NCS offers globally significant climate mitigation in the coming decades (6.56 PgCO2e yr−1 at less than 100 USD MgCO2e−1). In half of the tropical countries, cost-effective NCS could mitigate over half of national emissions. In more than a quarter of tropical countries, cost-effective NCS potential is greater than national emissions. We identify countries where, with international financing and political will, NCS can cost-effectively deliver the majority of enhanced NDCs while transforming national economies and contributing to SDGs.This article is part of the theme issue ‘Climate change and ecosystems: threats, opportunities and solutions’.

22. National mitigation potential from natural climate solutions in the tropics

Author

Griscom, Bronson W, Busch, Jonah, Cook-Patton, Susan C, Ellis, Peter W, Funk, Jason, Leavitt, Sara M, Lomax, Guy, Turner, Will R, Chapman, Melissa, Engelmann, Jens, Gurwick, Noel P, Landis, Emily, Lawrence, Deborah, Malhi, Yadvinder, Schindler Murray, Lisa, Navarrete, Diego, Roe, Stephanie, Scull, Sabrina, Smith, Pete, Streck, Charlotte, Walker, Wayne S, and Worthington, Thomas

Subjects

Conservation of Natural Resources, climate mitigation, restoration, Climate Change, 1. No poverty, land management, Paris Agreement, 15. Life on land, protection, Global Warming, 12. Responsible consumption, natural climate solutions, Environmental Policy, 13. Climate action, 11. Sustainability, Government Regulation, Ecosystem

Abstract

Better land stewardship is needed to achieve the Paris Agreement's temperature goal, particularly in the tropics, where greenhouse gas emissions from the destruction of ecosystems are largest, and where the potential for additional land carbon storage is greatest. As countries enhance their nationally determined contributions (NDCs) to the Paris Agreement, confusion persists about the potential contribution of better land stewardship to meeting the Agreement's goal to hold global warming below 2°C. We assess cost-effective tropical country-level potential of natural climate solutions (NCS)-protection, improved management and restoration of ecosystems-to deliver climate mitigation linked with sustainable development goals (SDGs). We identify groups of countries with distinctive NCS portfolios, and we explore factors (governance, financial capacity) influencing the feasibility of unlocking national NCS potential. Cost-effective tropical NCS offers globally significant climate mitigation in the coming decades (6.56 Pg CO2e yr-1 at less than 100 US$ per Mg CO2e). In half of the tropical countries, cost-effective NCS could mitigate over half of national emissions. In more than a quarter of tropical countries, cost-effective NCS potential is greater than national emissions. We identify countries where, with international financing and political will, NCS can cost-effectively deliver the majority of enhanced NDCs while transforming national economies and contributing to SDGs. This article is part of the theme issue 'Climate change and ecosystems: threats, opportunities and solutions'.

23. Supplementary tables from National mitigation potential from natural climate solutions in the tropics

Author

Griscom, Bronson W., Busch, Jonah, Cook-Patton, Susan C., Ellis, Peter W., Funk, Jason, Leavitt, Sara M., Lomax, Guy, Turner, Will, Chapman, Melissa, Engelmann, Jens, Gurwick, Noel P., Landis, Emily, Lawrence, Deborah, Yadvinder Malhi, Murray, Lisa Schindler, Navarrete, Diego, Roe, Stephanie, Scull, Sabrina, Smith, Pete, Streck, Charlotte, Walker, Wayne S., and Worthington, Thomas

Subjects

13. Climate action, 15. Life on land

Abstract

Table S1: Maximum (with safeguards) mitigation potential of 11 natural climate solutions pathways. Table S2: Maximum climate mitigation potential of avoided mangrove loss and mangrove restoration in countries and territories not included in Table S1. Table S3: Mitigation potential of 12 natural climate solutions pathways at “cost-effective” levels.

24. Supplementary tables from National mitigation potential from natural climate solutions in the tropics

Author

Griscom, Bronson W., Busch, Jonah, Cook-Patton, Susan C., Ellis, Peter W., Funk, Jason, Leavitt, Sara M., Lomax, Guy, Turner, Will, Chapman, Melissa, Engelmann, Jens, Gurwick, Noel P., Landis, Emily, Lawrence, Deborah, Yadvinder Malhi, Murray, Lisa Schindler, Navarrete, Diego, Roe, Stephanie, Scull, Sabrina, Smith, Pete, Streck, Charlotte, Walker, Wayne S., and Worthington, Thomas

Subjects

13. Climate action, 15. Life on land

Abstract

Table S1: Maximum (with safeguards) mitigation potential of 11 natural climate solutions pathways. Table S2: Maximum climate mitigation potential of avoided mangrove loss and mangrove restoration in countries and territories not included in Table S1. Table S3: Mitigation potential of 12 natural climate solutions pathways at “cost-effective” levels.

25. National mitigation potential from natural climate solutions in the tropics.

Author

Griscom BW, Busch J, Cook-Patton SC, Ellis PW, Funk J, Leavitt SM, Lomax G, Turner WR, Chapman M, Engelmann J, Gurwick NP, Landis E, Lawrence D, Malhi Y, Schindler Murray L, Navarrete D, Roe S, Scull S, Smith P, Streck C, Walker WS, and Worthington T

Subjects

Global Warming legislation & jurisprudence, Government Regulation, Climate Change, Conservation of Natural Resources legislation & jurisprudence, Ecosystem, Environmental Policy legislation & jurisprudence, Global Warming prevention & control

Abstract

Better land stewardship is needed to achieve the Paris Agreement's temperature goal, particularly in the tropics, where greenhouse gas emissions from the destruction of ecosystems are largest, and where the potential for additional land carbon storage is greatest. As countries enhance their nationally determined contributions (NDCs) to the Paris Agreement, confusion persists about the potential contribution of better land stewardship to meeting the Agreement's goal to hold global warming below 2°C. We assess cost-effective tropical country-level potential of natural climate solutions (NCS)-protection, improved management and restoration of ecosystems-to deliver climate mitigation linked with sustainable development goals (SDGs). We identify groups of countries with distinctive NCS portfolios, and we explore factors (governance, financial capacity) influencing the feasibility of unlocking national NCS potential. Cost-effective tropical NCS offers globally significant climate mitigation in the coming decades (6.56 Pg CO 2 e yr -1 at less than 100 US$ per Mg CO 2 e). In half of the tropical countries, cost-effective NCS could mitigate over half of national emissions. In more than a quarter of tropical countries, cost-effective NCS potential is greater than national emissions. We identify countries where, with international financing and political will, NCS can cost-effectively deliver the majority of enhanced NDCs while transforming national economies and contributing to SDGs. This article is part of the theme issue 'Climate change and ecosystems: threats, opportunities and solutions'.

Published

2020