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1. Droughts, Wildfires, and Forest Carbon Cycling: A Pantropical Synthesis

   https://doi.org/10.1146/annurev-earth-082517-010235  

   Brando, Paulo M.; Paolucci, Lucas; Ummenhofer, Caroline C.; Ordway, Elsa M.; Hartmann, Henrik; Cattau, Megan E.; Rattis, Ludmila; Medjibe, Vincent; Coe, Michael T.; Balch, Jennifer (May 2019, Annual Review of Earth and Planetary Sciences)

   Tropical woody plants store ∼230 petagrams of carbon (PgC) in their aboveground living biomass. This review suggests that these stocks are currently growing in primary forests at rates that have decreased in recent decades. Droughts are an important mechanism in reducing forest C uptake and stocks by decreasing photosynthesis, elevating tree mortality, increasing autotrophic respiration, and promoting wildfires. Tropical forests were a C source to the atmosphere during the 2015–2016 El Niño–related drought, with some estimates suggesting that up to 2.3 PgC were released. With continued climate change, the intensity and frequency of droughts and fires will likely increase. It is unclear at what point the impacts of severe, repeated disturbances by drought and fires could exceed tropical forests’ capacity to recover. Although specific threshold conditions beyond which ecosystem properties could lead to alternative stable states are largely unknown, the growing body of scientific evidence points to such threshold conditions becoming more likely as climate and land use change across the tropics. ▪ Droughts have reduced forest carbon uptake and stocks by elevating tree mortality, increasing autotrophic respiration, and promoting wildfires. ▪ Threshold conditions beyond which tropical forests are pushed into alternative stable states are becoming more likely as effects of droughts intensify. 

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2. Anthromes and forest carbon responses to global change

   https://doi.org/10.1002/ppp3.10609  

   Hogan, J Aaron; Lichstein, Jeremy W; Helmer, Eileen H; Craig, Matthew E; Fricke, Evan; Henrich, Viola; Kannenberg, Steven A; Koven, Charles D; Goldewjik, Kees Klein; Lapola, David M; et al (July 2025, PLANTS, PEOPLE, PLANET)

   Societal Impact StatementForest ecosystems absorb and store about 25% of global carbon dioxide emissions annually and are increasingly shaped by human land use and management. Climate change interacts with land use and forest dynamics to influence observed carbon stocks and the strength of the land carbon sink. We show that climate change effects on modeled forest land carbon stocks are strongest in tropical wildlands that have limited human influence. Global forest carbon stocks and carbon sink strength may decline as climate change and anthropogenic influences intensify, with wildland tropical forests, especially in Amazonia, likely being especially vulnerable. SummaryHuman effects on ecosystems date back thousands of years, and anthropogenic biomes—anthromes—broadly incorporate the effects of human population density and land use on ecosystems. Forests are integral to the global carbon cycle, containing large biomass carbon stocks, yet their responses to land use and climate change are uncertain but critical to informing climate change mitigation strategies, ecosystem management, and Earth system modeling.Using an anthromes perspective and the site locations from the Global Forest Carbon (ForC) Database, we compare intensively used, cultured, and wildland forest lands in tropical and extratropical regions. We summarize recent past (1900‐present) patterns of land use intensification, and we use a feedback analysis of Earth system models from the Coupled Model Intercomparison Project Phase 6 to estimate the sensitivity of forest carbon stocks to CO₂and temperature change for different anthromes among regions.Modeled global forest carbon stock responses are positive for CO₂increase but neutral to negative for temperature increase. Across anthromes (intensively used, cultured, and wildland forest areas), modeled forest carbon stock responses of temperate and boreal forests are less variable than those of tropical forests. Tropical wildland forest areas appear especially sensitive to CO₂and temperature change, with the negative temperature response highlighting the potential vulnerability of the globally significant carbon stock in tropical forests.The net effect of anthropogenic activities—including land‐use intensification and environmental change and their interactions with natural forest dynamics—will shape future forest carbon stock changes. These interactive effects will likely be strongest in tropical wildlands. 

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3. A high spatial resolution land surface phenology dataset for AmeriFlux and NEON sites

   https://doi.org/10.1038/s41597-022-01570-5  

   Moon, Minkyu; Richardson, Andrew D.; Milliman, Thomas; Friedl, Mark A. (July 2022, Scientific Data)

   Abstract Vegetation phenology is a key control on water, energy, and carbon fluxes in terrestrial ecosystems. Because vegetation canopies are heterogeneous, spatially explicit information related to seasonality in vegetation activity provides valuable information for studies that use eddy covariance measurements to study ecosystem function and land-atmosphere interactions. Here we present a land surface phenology (LSP) dataset derived at 3 m spatial resolution from PlanetScope imagery across a range of plant functional types and climates in North America. The dataset provides spatially explicit information related to the timing of phenophase changes such as the start, peak, and end of vegetation activity, along with vegetation index metrics and associated quality assurance flags for the growing seasons of 2017–2021 for 10 × 10 km windows centred over 104 eddy covariance towers at AmeriFlux and National Ecological Observatory Network (NEON) sites. These LSP data can be used to analyse processes controlling the seasonality of ecosystem-scale carbon, water, and energy fluxes, to evaluate predictions from land surface models, and to assess satellite-based LSP products. 

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4. Land–atmosphere interactions in the tropics – a review

   https://doi.org/10.5194/hess-23-4171-2019  

   Gentine, Pierre; Massmann, Adam; Lintner, Benjamin R.; Hamed Alemohammad, Sayed; Fu, Rong; Green, Julia K.; Kennedy, Daniel; Vilà-Guerau de Arellano, Jordi (January 2019, Hydrology and Earth System Sciences)

   Abstract. The continental tropics play a leading role in the terrestrial energy,water, and carbon cycles. Land–atmosphere interactions are integral in theregulation of these fluxes across multiple spatial and temporal scales overtropical continents. We review here some of the important characteristics oftropical continental climates and how land–atmosphere interactions regulatethem. Along with a wide range of climates, the tropics manifest a diversearray of land–atmosphere interactions. Broadly speaking, in tropicalrainforest climates, light and energy are typically more limiting thanprecipitation and water supply for photosynthesis and evapotranspiration (ET),whereas in savanna and semi-arid climates, water is the critical regulatorof surface fluxes and land–atmosphere interactions. We discuss the impact ofthe land surface, how it affects shallow and deep clouds, and how theseclouds in turn can feed back to the surface by modulating surface radiationand precipitation. Some results from recent research suggest that shallowclouds may be especially critical to land–atmosphere interactions. On theother hand, the impact of land-surface conditions on deep convection appearsto occur over larger, nonlocal scales and may be a more relevantland–atmosphere feedback mechanism in transitional dry-to-wet regions andclimate regimes. 

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5. Water Stress Dominates 21st‐Century Tropical Land Carbon Uptake

   https://doi.org/10.1029/2023GB007702  

   Levine, Paul A.; Bloom, A. Anthony; Bowman, Kevin W.; Reager, John T.; Worden, John R.; Liu, Junjie; Parazoo, Nicholas C.; Meyer, Victoria; Konings, Alexandra G.; Longo, Marcos (December 2023, Global Biogeochemical Cycles)

   Abstract Water stress regulates land‐atmosphere carbon dioxide (CO₂) exchanges in the tropics; however, its role remains poorly characterized due to the confounding roles of radiation, temperature and canopy dynamics. In particular, uncertainty stems from the relative roles of plant‐available water (supply) and atmospheric water vapor deficit (demand) as mechanistic drivers of photosynthetic carbon (C) uptake variability. Using satellite measurements of gravity, CO₂and fluorescence to constrain a mechanistic carbon‐water cycle model from 2001 to 2018, we found that the interannual variability (IAV) of water stress on photosynthetic C uptake was 52% greater than the combined effects of other factors. Surprisingly, the dominance of water stress on C uptake IAV was greater in the wet tropics (94%) than in the dry tropics (26%). Plant‐available water supply and atmospheric demand both contributed to the IAV of water stress on photosynthetic C uptake across the tropics, but the IAV of demand effects was 21% greater than the IAV of supply effects (33% greater in the wet tropics and 6% greater in the dry tropics). We found that the IAV of water stress on C uptake was 24% greater than the IAV of the combination of other factors in the net land‐atmosphere C sink in the whole tropics, 26% greater in the wet tropics, and 7% greater in the dry tropics. Given the recent trends in tropical precipitation and atmospheric humidity, our findings indicate that water stress——from both supply and demand——will likely dominate the climate response of land C sink across tropical ecosystems in the coming decades. 

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