Planting trees in livestock landscapes to protect soil and water also delivers carbon sequestration
暂无分享,去创建一个
[1] M. Ibrahim,et al. Silvopastoral systems and remnant forests enhance carbon storage in livestock-dominated landscapes in Mexico , 2022, Scientific Reports.
[2] S. Ohrel,et al. How the future of the global forest sink depends on timber demand, forest management, and carbon policies , 2022, Global environmental change : human and policy dimensions.
[3] J. Pezzopane,et al. Silvopastoral system is an alternative to improve animal welfare and productive performance in meat production systems , 2021, Scientific Reports.
[4] E. Koomen,et al. Projecting future impacts of cropland reclamation policies on carbon storage , 2020, Ecological Indicators.
[5] G. Correa-Londoño,et al. Leaf Litter Decomposition in Diverse Silvopastoral Systems in a Neotropical Environment , 2020, Journal of Sustainable Forestry.
[6] K. Calvin,et al. Which practices co‐deliver food security, climate change mitigation and adaptation, and combat land degradation and desertification? , 2019, Global change biology.
[7] K. Anna,et al. Assessment of carbon dynamics in Ecuadorian forests through the Mathematical Spatial Model of Global Carbon Cycle and the Normalized Differential Vegetation Index (NDVI) , 2019, E3S Web of Conferences.
[8] D. Edwards,et al. Secondary forest fragments offer important carbon and biodiversity cobenefits , 2019, Global change biology.
[9] Claude A. Garcia,et al. The global tree restoration potential , 2019, Science.
[10] R. Fischer,et al. Degradation of Ecosystem Services and Deforestation in Landscapes With and Without Incentive-Based Forest Conservation in the Ecuadorian Amazon , 2019, Forests.
[11] M. Nielsen,et al. Not Seeing the Forest for the Trees: The Oversight of Defaunation in REDD+ and Global Forest Governance , 2019, Forests.
[12] A. Balmford,et al. Carbon Storage and Land-Use Strategies in Agricultural Landscapes across Three Continents , 2018, Current Biology.
[13] Andy Reisinger,et al. How much do direct livestock emissions actually contribute to global warming? , 2018, Global change biology.
[14] R. Houghton,et al. Negative emissions from stopping deforestation and forest degradation, globally , 2018, Global change biology.
[15] P. Hildebrandt,et al. Natural or assisted succession as approach of forest recovery on abandoned lands with different land use history in the Andes of Southern Ecuador , 2017, New Forests.
[16] A. Huth,et al. The carbon fluxes in different successional stages: modelling the dynamics of tropical montane forests in South Ecuador , 2017, Forest Ecosystems.
[17] S. Speelman,et al. Farmers’ Preferences for PES Contracts to Adopt Silvopastoral Systems in Southern Ecuador, Revealed Through a Choice Experiment , 2017, Environmental Management.
[18] M. Rivera-Ferre,et al. Re‐framing the climate change debate in the livestock sector: mitigation and adaptation options , 2016 .
[19] H. Griffiths,et al. The potential for land sparing to offset greenhouse gas emissions from agriculture , 2016 .
[20] Pete Smith,et al. Greenhouse gas mitigation potentials in the livestock sector , 2016 .
[21] Pete Smith,et al. Soil and tree biomass carbon sequestration potential of silvopastoral and woodland-pasture systems in North East Scotland , 2016, Agroforestry Systems.
[22] O. Ovaskainen,et al. Defaunation affects carbon storage in tropical forests , 2015, Science Advances.
[23] Benjamin Leon Bodirsky,et al. Global Food Demand Scenarios for the 21st Century , 2015, PloS one.
[24] E. Somanathan,et al. Status and trends in global primary forest, protected areas, and areas designated for conservation of biodiversity from the Global Forest Resources Assessment 2015☆ , 2015 .
[25] P. Ciais,et al. Negative emissions physically needed to keep global warming below 2 °C , 2015, Nature Communications.
[26] Jürgen Homeier,et al. Is tropical montane forest heterogeneity promoted by a resource-driven feedback cycle? Evidence from nutrient relations, herbivory and litter decomposition along a topographical gradient , 2015 .
[27] J. Pezzopane,et al. Microclimate and soil moisture in a silvopastoral system in southeastern Brazil , 2015 .
[28] B. Nelson,et al. Improved allometric models to estimate the aboveground biomass of tropical trees , 2014, Global change biology.
[29] Simone Bastianoni,et al. Global and regional trends in greenhouse gas emissions from livestock , 2014, Climatic Change.
[30] Tomoko Hasegawa,et al. The future of food demand: understanding differences in global economic models , 2014 .
[31] G. Berndes,et al. How much land is needed for global food production under scenarios of dietary changes and livestock productivity increases in 2030 , 2010 .
[32] J. Aune,et al. Changes in carbon stocks and tree diversity in agro-ecosystems in south western Uganda: what role for carbon sequestration payments? , 2010, New Forests.
[33] F. Chapin,et al. A safe operating space for humanity , 2009, Nature.
[34] Ariel E. Lugo,et al. The Potential for Carbon Sequestration Through Reforestation of Abandoned Tropical Agricultural and Pasture Lands , 2000 .
[35] Eileen H. Helmer,et al. Root biomass allocation in the world's upland forests , 1997, Oecologia.
[36] M. Saleem,et al. The effect of livestock grazing on surface runoff and soil erosion from sloping pasture lands in the Ethiopian highlands , 1997 .