{"id":121,"date":"2019-08-07T03:39:34","date_gmt":"2019-08-07T03:39:34","guid":{"rendered":"http:\/\/sites.exeter.ac.uk\/tedfeldpausch\/?page_id=121"},"modified":"2026-06-22T17:47:21","modified_gmt":"2026-06-22T17:47:21","slug":"research-findings","status":"publish","type":"page","link":"https:\/\/sites.exeter.ac.uk\/ted-feldpausch\/research-findings\/","title":{"rendered":"Research Findings"},"content":{"rendered":"

Research themes<\/a> | Key publications<\/a> | Publications by year<\/a><\/p>\n

\n

Our research group has published on tropical forest and savanna ecology, with research themes spanning the effects of fire, deforestation, drought, and climate change on carbon stocks, soil properties, and biodiversity across Amazonia and African forests.<\/p>\n

Research findings by theme<\/h3>\n
\n
\n
Forest carbon dynamics<\/strong><\/p>\n

Amazonian trees are getting larger on average, yet the continental carbon sink is weakening as species composition shifts faster than trees can adapt to rising temperatures. Across tropical Andean and Amazonian forests, tree diversity is changing at rates that outpace local adaptation, with montane forests showing the fastest compositional turnover.<\/p>\n<\/div>\n

Fire and forest degradation<\/strong><\/p>\n

Repeated burning in the southern Amazon causes stepwise simplification of forest structure and species composition, even in secondary vegetation recovering from earlier clearing. Canopy recovery after fire is strongly stage-dependent: younger regrowth is more vulnerable but recovers faster, while older secondary growth is more resilient but rebuilds more slowly.<\/p>\n<\/div>\n

Land-use and climate change<\/strong><\/p>\n

Agricultural conversion eliminates 38% of soil organic carbon in addition to 100% of aboveground biomass, yet fire alone does not significantly reduce soil carbon. Across elevation gradients from lowland Amazonia to the Colombian Andes, climate and soil type together determine how much carbon accumulates and persists after disturbance.<\/p>\n<\/div>\n

Biodiversity and community ecology<\/strong><\/p>\n

In the South American Cerrado, 30 hyperdominant tree species account for a disproportionate share of biomass \u2014 and these same species show the greatest vulnerability to future climate change. Across tropical Andean and Amazonian forests, tree diversity is shifting in response to warming and land-use change, with distinct thresholds between montane and lowland systems.<\/p>\n<\/div>\n

Remote sensing and modelling<\/strong><\/p>\n

GEDI satellite lidar detects consistent structural differences across Amazonian degradation gradients \u2014 from intact forest to burned and cleared plots \u2014 providing a scalable tool for tracking fire impacts and carbon stock changes. L-band SAR backscatter is primarily controlled by vegetation water content and structure rather than biomass alone in dry tropical ecosystems, informing how satellite-based carbon mapping should be calibrated.<\/p>\n<\/div>\n

Forest recovery, resilience, and restoration<\/strong><\/p>\n

Amazonian secondary forests show stage-dependent responses to fire: younger forests are more vulnerable but recover faster, while older secondary growth is structurally more resilient but rebuilds more slowly after disturbance. At the continental scale, tropical forests in the Americas are not shifting their composition fast enough to track the pace of climate change, raising fundamental questions about long-term carbon sink stability.<\/p>\n<\/div>\n<\/div>\n<\/div>\n

\n

Key publications<\/h3>\n
\n
\nFeldpausch TR, Carvalho L, Macario KD, Ascough PL, Flores CF, Honorio Coronado EN, Kalamandeen M, Phillips OL, Staff RA (2022). Forest fire history in Amazonia inferred from intensive soil charcoal sampling and radiocarbon dating<\/strong>. Frontiers in Forests and Global Change<\/em>, 5<\/em>. Full text<\/a>.\n<\/div>\n
\nKoele N, Bird M, Haig J, Marimon-Junior BH, Marimon BS, Phillips OL, de Oliveira EA, Quesada CA, Feldpausch TR (2017). Amazon Basin forest pyrogenic carbon stocks: First estimate of deep storage<\/strong>. Geoderma<\/em>, 306, 237–243<\/em>. Full text<\/a>.\n<\/div>\n
\nFeldpausch TR, Phillips OL, Brienen RJW, Gloor E, Lloyd J, Lopez-Gonzalez G, Monteagudo-Mendoza A, Malhi Y, Alarc\u00f3n A, \u00c1lvarez D\u00e1vila E, et al (2016). Amazon forest response to repeated droughts<\/strong>. Global Biogeochemical Cycles<\/em>, 30(7), 964–982<\/em>. Full text<\/a>.\n<\/div>\n
\nDoughty CE, Metcalfe DB, Girardin CAJ, Am\u00e9zquita FF, Cabrera DG, Huasco WH, Silva-Espejo JE, Araujo-Murakami A, da Costa MC, Rocha W, et al (2015). Drought impact on forest carbon dynamics and fluxes in Amazonia<\/strong>. Nature<\/em>, 519(7541), 78–82<\/em>. Author URL<\/a> Full text<\/a>.\n<\/div>\n
\nBrienen RJW, Phillips OL, Feldpausch TR, Gloor E, Baker TR, Lloyd J, Lopez-Gonzalez G, Monteagudo-Mendoza A, Malhi Y, Lewis SL, et al (2015). Long-term decline of the Amazon carbon sink<\/strong>. Nature<\/em>, 519(7543), 344–348<\/em>. Author URL<\/a> Full text<\/a>.\n<\/div>\n
\nMitchard ETA, Feldpausch TR, Brienen RJW, Lopez-Gonzalez G, Monteagudo A, Baker TR, Lewis SL, Lloyd J, Quesada CA, Gloor M, et al (2014). Markedly divergent estimates of Amazon forest carbon density from ground plots and satellites<\/strong>. Global Ecology and Biogeography<\/em>, 23(8), 935–946<\/em>. Full text<\/a>.\n<\/div>\n
\nFeldpausch TR, Lloyd J, Lewis SL, Brienen RJW, Gloor M, Monteagudo Mendoza A, Lopez-Gonzalez G, Banin L, Abu Salim K, Affum-Baffoe K, et al (2012). Tree height integrated into pantropical forest biomass estimates<\/strong>. Biogeosciences<\/em>, 9(8), 3381–3403<\/em>. Full text<\/a>.\n<\/div>\n<\/div>\n
<\/div>\n
\n

Publications by year<\/h3>\n

2026<\/h3>\n
\nWang Y, Gallego-Sala AV, Quesada CA, Feldpausch TR, et al (2026). Unprecedented burning in tropical peatlands during the 20th century compared to the previous two millennia<\/strong>. Global Change Biology<\/em>, 32<\/em>(3). Full text<\/a>\n<\/div>\n
\nAlvarez F, Marimon-Junior BH, Marimon BS, Feldpausch TR, et al (2026). Hyperdominant trees reveal savanna vulnerability under climate change<\/strong>. Global Change Biology<\/em>, 32<\/em>(4). Full text<\/a>\n<\/div>\n
\nFadrique B, Costa FRC, Feldpausch TR, et al (2026). Tree diversity is changing across tropical Andean and Amazonian forests in response to global change<\/strong>. Nature Ecology and Evolution<\/em>, 10<\/em>(2), 267–280. Full text<\/a>\n<\/div>\n

2025<\/h3>\n
\nAguirre-Guti\u00e9rrez J, D\u00edaz S, Rifai SW, Feldpausch TR, et al (2025). Tropical forests in the Americas are changing too slowly to track climate change<\/strong>. Science<\/em>, 387<\/em>(6738). Full text<\/a>\n<\/div>\n
\nEsquivel-Muelbert A, Banbury Morgan R, Brienen RJW, Gloor E, Lewis SL, Dexter KG, Feldpausch TR, et al (2025). Increasing tree size across Amazonia<\/strong>. Nature Plants<\/em>, 11<\/em>(10), 2016–2025. Full text<\/a>\n<\/div>\n
\nRocha LM, Marimon-Junior BH, Barradas ACS, Carvalho MA, Soares CS, Marimon BS, Feldpausch TR, et al (2025). Fire-induced floristic and structural degradation across a vegetation gradient in the southern Amazon<\/strong>. Forests<\/em>, 16<\/em>(8), 1218. Full text<\/a>\n<\/div>\n
\nWang Y, Gallego-Sala AV, Bird MI, Moss PT, McGowan HA, Benavides JC, Feldpausch TR, et al (2025). Wildfire legacies on pyrogenic carbon stocks in Amazonian peatlands<\/strong>. Communications Earth and Environment<\/em>, 6<\/em>(1). Full text<\/a>\n<\/div>\n
\nAlvarez F, Marimon-Junior BH, Marimon BS, ter Steege H, Phillips OL, Feldpausch TR, et al (2025). Tree species hyperdominance and rarity in the South American Cerrado<\/strong>. Communications Biology<\/em>, 8<\/em>(1). Full text<\/a>\n<\/div>\n
\nNaval MR, Bieluczyk W, Alvarez F, Carvalho L, Feldpausch TR, et al (2025). Impacts of repeated forest fires and agriculture on soil organic matter and health in southern Amazonia<\/strong>. CATENA<\/em>, 254<\/em>, 108924. Full text<\/a>\n<\/div>\n
\nDoyle EJ, Graham HA, Boulton CA, Lenton TM, Feldpausch TR, Cunliffe AM (2025). Evaluating GEDI for quantifying forest structure across a gradient of degradation in Amazonia<\/strong>. Environmental Research Letters<\/em>, 20<\/em>(5), 054016. Full text<\/a>\n<\/div>\n
\nMontes-Pulido CR, Bird M, da Silva Carvalho L, Serrano JC, Quesada CA, Feldpausch TR (2025). Climatic and edaphic drivers of soil organic carbon and pyrogenic carbon stocks across elevation and land-use gradients<\/strong>. Global Change Biology<\/em>, 31<\/em>(7). Full text<\/a>\n<\/div>\n

2024<\/h3>\n
\nLuize BG, Bauman D, ter Steege H, Palma\u2010Silva C, et al (2024). Geography and ecology shape the phylogenetic composition of Amazonian tree communities<\/strong>. Journal of Biogeography<\/em>, 51<\/em>(7), 1163-1184. Full text<\/a>\n<\/div>\n
\nZou Y, Zohner CM, Averill C, Ma H, et al (2024). Positive feedbacks and alternative stable states in forest leaf types<\/strong>. Nature Communications<\/em>, 15<\/em>(1). Full text<\/a>\n<\/div>\n
\nHouseholder JE, Wittmann F, Sch\u00f6ngart J, Piedade MTF, et al (2024). One sixth of Amazonian tree diversity is dependent on river floodplains<\/strong>. Nature Ecology & Evolution<\/em>, 8<\/em>(5), 901-911. Full text<\/a>\n<\/div>\n
\nHouseholder JE, Wittmann F, Sch\u00f6ngart J, Piedade MTF, et al (2024). Author Correction: One sixth of Amazonian tree diversity is dependent on river floodplains<\/strong>. Nature Ecology & Evolution<\/em>, 8<\/em>(5), 1046-1047. Full text<\/a>\n<\/div>\n
\nCooper DLM, Lewis SL, Sullivan MJP, Prado PI, et al (2024). Consistent patterns of common species across tropical tree communities<\/strong>. Nature<\/em>, 625<\/em>(7996), 728-734. Full text<\/a>\n<\/div>\n
\nHordijk I, Bialic\u2010Murphy L, Lauber T, Routh D, et al (2024). Dominance and rarity in tree communities across the globe: Patterns, predictors and consequences<\/strong>. Global Ecology and Biogeography<\/em>, 33<\/em>(10). Full text<\/a>\n<\/div>\n

2023<\/h3>\n
\nMo L, Zohner CM, Reich PB, Liang J, et al (2023). Integrated global assessment of the natural forest carbon potential<\/strong>. Nature<\/em>, 624<\/em>(7990), 92-101. Full text<\/a>\n<\/div>\n
\nter Steege H, Pitman NCA, do Amaral IL, de Souza Coelho L, et al (2023). Mapping density, diversity and species-richness of the Amazon tree flora<\/strong>. Communications Biology<\/em>, 6<\/em>(1). Full text<\/a>\n<\/div>\n
\nMa H, Crowther TW, Mo L, Maynard DS, et al (2023). The global biogeography of tree leaf form and habit<\/strong>. Nature Plants<\/em>, 9<\/em>(11), 1795-1809. Full text<\/a>\n<\/div>\n
\nPeripato V, Levis C, Moreira GA, Gamerman D, et al (2023). More than 10,000 pre-Columbian earthworks are still hidden throughout Amazonia<\/strong>. Science<\/em>, 382<\/em>(6666), 103-109. Full text<\/a>\n<\/div>\n
\nDelavaux CS, Crowther TW, Zohner CM, Robmann NM, et al (2023). Native diversity buffers against severity of non-native tree invasions<\/strong>. Nature<\/em>, 621<\/em>(7980), 773-781. Full text<\/a>\n<\/div>\n
\nDelavaux CS, Crowther TW, Zohner CM, Robmann NM, et al (2023). Author Correction: Native diversity buffers against severity of non-native tree invasions<\/strong>. Nature<\/em>, 622<\/em>(7982), E2-E2. Full text<\/a>\n<\/div>\n
\nde Lima RB, G\u00f6rgens EB, da Silva DAS, de Oliveira CP, et al (2023). Giants of the Amazon: How does environmental variation drive the diversity patterns of hyperdominant tree species?<\/strong>. Global Change Biology<\/em>, 29<\/em>(17), 4861-4879. Full text<\/a>\n<\/div>\n
\nBennett AC, Rodrigues de Sousa T, Monteagudo-Mendoza A, Esquivel-Muelbert A, et al (2023). Sensitivity of South American tropical forests to an extreme climate anomaly<\/strong>. Nature Climate Change<\/em>, 13<\/em>(9), 967-974. Full text<\/a>\n<\/div>\n
\nCarvalho RL, Resende AF, Barlow J, Fran\u00e7a FM, et al (2023). Pervasive gaps in Amazonian ecological research<\/strong>. Current Biology<\/em>, 33<\/em>(16), 3495-3504.e4. Full text<\/a>\n<\/div>\n
\nHill J, Black S, Araujo-Murakami A, Boot R, et al (2023). An Assessment of Soil Phytolith Analysis as a Palaeoecological Tool for Identifying Past Fire Regimes<\/strong>. Quaternary<\/em>, 6<\/em>(2), 33. Full text<\/a>\n<\/div>\n
\nHordijk I, Maynard DS, Hart SP, Lidong M, et al (2023). Evenness mediates the global relationship between forest productivity and richness<\/strong>. Journal of Ecology<\/em>, 111<\/em>(6), 1308-1326. Full text<\/a>\n<\/div>\n
\nTavares JV, Oliveira RS, Mencuccini M, Signori-M\u00fcller C, et al (2023). Basin-wide variation in tree hydraulic safety margins predicts the carbon balance of tropical forests<\/strong>. Nature<\/em>, 617<\/em>(7959), 111-117. Full text<\/a>\n<\/div>\n
\nPos E, de Souza Coelho L, de Andrade Lima Filho D, Salom\u00e3o RP, et al (2023). Unraveling Amazon tree community assembly using Maximum Information Entropy: a quantitative analysis of the importance of regional and local ecological drivers<\/strong>. Scientific Reports<\/em>, 13<\/em>(1). Full text<\/a>\n<\/div>\n
\nVedovato LB, Carvalho LCS, Arag\u00e3o LEOC, Bird M, et al (2023). Ancient fires enhance Amazon forest drought resistance<\/strong>. Frontiers in Forests and Global Change<\/em>, 6<\/em>. Full text<\/a>\n<\/div>\n
\nCrawford AJ, Feldpausch TR, Marimon Junior BH, de Oliveira EA, et al (2023). Effect of tree wood density on energy release and charcoal reflectance under controlled combustion<\/strong>. International Journal of Wildland Fire<\/em>, 32<\/em>(12), 1788-1797. Full text<\/a>\n<\/div>\n
\nCorrea DF, Stevenson PR, Uma\u00f1a MN, Coelho LdS, et al (2023). Geographic patterns of tree dispersal modes in Amazonia and their ecological correlates<\/strong>. Global Ecology and Biogeography<\/em>, 32<\/em>(1), 49-69. Full text<\/a>\n<\/div>\n
\nFortalech\u00e9 Rodr\u00edguez YF, Pe\u00f1a Urue\u00f1a ML, Cadena S\u00e1nchez AO (2023). Investigating the Effect of Multitemporal Land Use Changes to the Middle Magdalena Valley Carbon Stocks<\/strong>. International Journal of Hydrology<\/em>, 7<\/em>(3), 119-124. Full text<\/a>\n<\/div>\n

2022<\/h3>\n
Rozendaal DMA, Requena Suarez D, De Sy V, Avitabile V, Carter S, Adou Yao CY, Alvarez-Davila E, Anderson-Teixeira K, Araujo-Murakami A, Arroyo L, et al\u00a0(2022).\u00a0Aboveground forest biomass varies across continents, ecological zones and successional stages: Refined IPCC default values for tropical and subtropical forests<\/strong>.\u00a0Environmental Research Letters<\/em>,\u00a017<\/em>(1).\u00a0Abstract<\/a>.\u00a0\"Article<\/a><\/span><\/div>\n
Reis SM, Marimon BS, Esquivel-Muelbert A, Marimon BH, Morandi PS, Elias F, de Oliveira EA, Galbraith D, Feldpausch TR, Menor IO, et al\u00a0(2022).\u00a0Climate and crown damage drive tree mortality in southern Amazonian edge forests<\/strong>.\u00a0Journal of Ecology<\/em>,\u00a0110<\/em>(4), 876-888.\u00a0Abstract<\/a>.\u00a0\"Article<\/a><\/span><\/div>\n
Alvarez F, Morandi PS, Marimon-Junior BH, Exavier R, Ara\u00fajo I, Mariano LH, Muller AO, Feldpausch TR, Marimon BS\u00a0(2022).\u00a0Climate defined but not soil-restricted: the distribution of a Neotropical tree through space and time<\/strong>.\u00a0Plant and Soil<\/em>,\u00a0471<\/em>(1-2), 175-191.\u00a0Abstract<\/a>.\u00a0\"Article<\/a><\/span><\/div>\n
Gatti RC, Reich PB, Gamarra JGP, Crowther T, Hui C, Morera A, Bastin JF, de-Miguel S, Nabuurs GJ, Svenning JC, et al\u00a0(2022).\u00a0Erratum: the number of tree species on Earth (Proceedings of the National Academy of Sciences of the United States of America (2022) 119 (e2115329119) DOI: 10.1073\/pnas.2115329119)<\/strong>.\u00a0Proceedings of the National Academy of Sciences of the United States of America<\/em>,\u00a0119<\/em>(13).\u00a0Abstract<\/a>.<\/div>\n
Feldpausch TR, Carvalho L, Macario KD, Ascough PL, Flores CF, Coronado ENH, Kalamandeen M, Phillips OL, Staff RA\u00a0(2022).\u00a0Forest Fire History in Amazonia Inferred from Intensive Soil Charcoal Sampling and Radiocarbon Dating<\/strong>.\u00a0Frontiers in Forests and Global Change<\/em>,\u00a05<\/em>\u00a0Abstract<\/a>.\u00a0\"Article<\/a><\/span><\/div>\n
Marca-Zevallos MJ, Moulatlet GM, Sousa TR, Schietti J, Coelho LDS, Ramos JF, Lima Filho DDA, Amaral IL, de Almeida Matos FD, Rinc\u00f3n LM, et al\u00a0(2022).\u00a0Local hydrological conditions influence tree diversity and composition across the Amazon basin<\/strong>.\u00a0Ecography<\/em>,\u00a02022<\/em>(11).\u00a0Abstract<\/a>.\u00a0\"Article<\/a><\/span><\/div>\n
Adzhar R, Kelley DI, Dong N, George C, Torello Raventos M, Veenendaal E, Feldpausch TR, Phillips OL, Lewis SL, Sonk\u00e9 B, et al\u00a0(2022).\u00a0MODIS Vegetation Continuous Fields tree cover needs calibrating in tropical savannas<\/strong>.\u00a0Biogeosciences<\/em>,\u00a019<\/em>(5), 1377-1394.\u00a0Abstract<\/a>.\u00a0\"Article<\/a><\/span><\/div>\n
Lima \u00c9FDC, Ribeiro SC, Mews HA, Costa RS, Garvizu NGS, Brown IF, Perz SG, Schmidt FA, Silveira M, Phillips OL, et al\u00a0(2022).\u00a0Primary modes of tree mortality in southwestern Amazon forests<\/strong>.\u00a0Trees, Forests and People<\/em>,\u00a07<\/em>\u00a0Abstract<\/a>.\u00a0\"Article<\/a><\/span><\/div>\n
de Oliveira EA, Feldpausch TR, Marimon BS, Morandi PS, Phillips OL, Bird M, Murakami AA, Arroyo L, Quesada CA, Marimon-Junior BH, et al\u00a0(2022).\u00a0Soil pyrogenic carbon in southern Amazonia: Interaction between soil, climate, and above-ground biomass<\/strong>.\u00a0Frontiers in Forests and Global Change<\/em>,\u00a05<\/em>\u00a0Abstract<\/a>.\u00a0\"Article<\/a><\/span><\/div>\n
Jucker T, Fischer FJ, Chave J, Coomes DA, Caspersen J, Ali A, Loubota Panzou GJ, Feldpausch TR, Falster D, Usoltsev VA, et al\u00a0(2022).\u00a0Tallo: a global tree allometry and crown architecture database<\/strong>.\u00a0Glob Chang Biol<\/em>,\u00a028<\/em>(17), 5254-5268.\u00a0Abstract<\/a>. \u00a0Author URL<\/a>.\u00a0\"Article<\/a><\/span><\/div>\n
Cazzolla Gatti R, Reich PB, Gamarra JGP, Crowther T, Hui C, Morera A, Bastin J-F, de-Miguel S, Nabuurs G-J, Svenning J-C, et al\u00a0(2022).\u00a0The number of tree species on Earth<\/strong>.\u00a0Proc Natl Acad Sci U S A<\/em>,\u00a0119<\/em>(6).\u00a0Abstract<\/a>. \u00a0Author URL<\/a>.\u00a0\"Article<\/a><\/span><\/div>\n

2021<\/h3>\n
Draper FC, Costa FRC, Arellano G, Phillips OL, Duque A, Mac\u00eda MJ, Ter Steege H, Asner GP, Berenguer E, Schietti J, et al\u00a0(2021).\u00a0Amazon tree dominance across forest strata<\/strong>.\u00a0Nat Ecol Evol<\/em>,\u00a05<\/em>(6), 757-767.\u00a0Abstract<\/a>. \u00a0Author URL<\/a>.\u00a0\"Article<\/a><\/span><\/div>\n
Signori-M\u00fcller C, Oliveira RS, Barros FDV, Tavares JV, Gilpin M, Diniz FC, Zevallos MJM, Yupayccana CAS, Acosta M, Bacca J, et al\u00a0(2021).\u00a0Non-structural carbohydrates mediate seasonal water stress across Amazon forests<\/strong>.\u00a0Nat Commun<\/em>,\u00a012<\/em>(1).\u00a0Abstract<\/a>. \u00a0Author URL<\/a>.\u00a0\"Article<\/a><\/span><\/div>\n
Panzou GJL, Fayolle A, Jucker T, Phillips OL, Bohlman S, Banin LF, Lewis SL, Affum-Baffoe K, Alves LF, Antin C, et al\u00a0(2021).\u00a0Pantropical variability in tree crown allometry<\/strong>.\u00a0GLOBAL ECOLOGY AND BIOGEOGRAPHY<\/em>,\u00a030<\/em>(2), 459-475.\u00a0Author URL<\/a>.\u00a0\"Article<\/a><\/span><\/div>\n
Bennett AC, Dargie GC, Cuni-Sanchez A, Tshibamba Mukendi J, Hubau W, Mukinzi JM, Phillips OL, Malhi Y, Sullivan MJP, Cooper DLM, et al\u00a0(2021).\u00a0Resistance of African tropical forests to an extreme climate anomaly<\/strong>.\u00a0Proc Natl Acad Sci U S A<\/em>,\u00a0118<\/em>(21).\u00a0Abstract<\/a>. \u00a0Author URL<\/a>.\u00a0\"Article<\/a><\/span><\/div>\n
Forest PN, Blundo C, Carilla J, Grau R, Malizia A, Malizia L, Osinaga-Acosta O, Bird M, Bradford M, Catchpole D, et al\u00a0(2021).\u00a0Taking the pulse of Earth’s tropical forests using networks of highly distributed plots<\/strong>.\u00a0Biological Conservation<\/em>,\u00a0260<\/em>\u00a0Abstract<\/a>.\u00a0\"Article<\/a><\/span><\/div>\n
Fahey T, Bohlen P, Feldpausch TR, Fisk M, Goebel M, Groffman PM, Maerz J, Yavitt J\u00a0(2021).\u00a0Tracing carbon flow through a sugar maple forest and its soil components: role of invasive earthworms<\/strong>.\u00a0Plant and Soil<\/em>,\u00a0464<\/em>(1-2), 517-537.\u00a0Abstract<\/a>.\u00a0\"Article<\/a><\/span><\/div>\n
Pos E, de Souza Coelho L, de Andrade Lima Filho D, Salom\u00e3o RP, Amaral IL, de Almeida Matos FD, Castilho CV, Phillips OL, Guevara JE, de Jesus Veiga Carim M, et al\u00a0(2021).\u00a0Unraveling Amazon tree community assembly using Maximum Information Entropy: a quantitative analysis of tropical forest ecology<\/strong>.\u00a0\"Article<\/a><\/span><\/div>\n
Djagbletey GD, Addo-Danso SD, Duah-Gyamfi A, Veenendaal EM, Feldpausch TR, Schrodt F, Domingues TF, Saiz G, Affum-Baffoe K, Bird M, et al\u00a0(2021).\u00a0WOODY PLANT COMPOSITION, DIVERSITY AND CONSERVATION STATUS OF a PROTECTED AREA IN THE TRANSITION ZONE OF GHANA<\/strong>.\u00a0Journal of the Ghana Science Association<\/em>,\u00a020<\/em>(2), 6-16.\u00a0Abstract<\/a>.<\/div>\n

2020<\/h3>\n
Wannes H, Simon L, et al. (including Feldpausch T.R.), 2020. Asynchronous Carbon Sink Saturation in African and Amazonian Tropical Forests<\/strong>. Nature. 579<\/b>,\u00a0pages<\/span>80\u201387 (<\/em>\u00a0Full text)<\/a>.<\/div>\n
ter Steege H, Prado PI, Lima RAFD, Pos E, de Souza Coelho L, de Andrade Lima Filho D, Salom\u00e3o RP, Amaral IL, de Almeida Matos FD, Castilho CV, et al\u00a0(2020).\u00a0Biased-corrected richness estimates for the Amazonian tree flora<\/strong>.\u00a0Sci Rep<\/em>,\u00a010<\/em>(1). \u00a0Author URL<\/a>. \u00a0Full text<\/a>.\"Article<\/a><\/span><\/div>\n
Reis SM, Marimon BS, Morandi PS, Elias F, Esquivel-Muelbert A, Marimon Junior BH, Fauset S, de Oliveira EA, van der Heijden GMF, Galbraith D, et al\u00a0(2020).\u00a0Causes and consequences of liana infestation in southern Amazonia<\/strong>.\u00a0Journal of Ecology<\/em>,\u00a0108<\/em>(6), 2184-2197. \u00a0Full text<\/a>.\"Article<\/a><\/span><\/div>\n
Rozendaal DMA, Phillips OL, Lewis SL, Affum-Baffoe K, Alvarez-Davila E, Andrade A, Arag\u00e3o LEOC, Araujo-Murakami A, Baker TR, B\u00e1nki O, et al\u00a0(2020).\u00a0Competition influences tree growth, but not mortality, across environmental gradients in Amazonia and tropical Africa<\/strong>.\u00a0Ecology<\/em>,\u00a0101<\/em>(7). \u00a0Author URL<\/a>. \u00a0Full text<\/a>.\"Article<\/a><\/span><\/div>\n
Marimon BS, Oliveira-Santos C, Marimon-Junior BH, Elias F, de Oliveira EA, Morandi PS, Nayane NCCD, Mariano LH, Pereira OR, Feldpausch TR, et al\u00a0(2020).\u00a0Drought generates large, long-term changes in tree and liana regeneration in a monodominant Amazon forest<\/strong>.\u00a0Plant Ecology<\/em>,\u00a0221<\/em>(8), 733-747. \u00a0Full text<\/a>.\"Article<\/a><\/span><\/div>\n
Burton C, Betts RA, Jones CD, Feldpausch TR, Cardoso M, Anderson LO\u00a0(2020).\u00a0El Ni\u00f1o Driven Changes in Global Fire 2015\/16<\/strong>.\u00a0Frontiers in Earth Science<\/em>. \u00a0Full text<\/a>.\"Article<\/a><\/span><\/div>\n
Moonlight PW, Banda\u2010R K, Phillips OL, Dexter KG, Pennington RT, Baker TR, C. de Lima H, Fajardo L, Gonz\u00e1lez\u2010M. R, Linares\u2010Palomino R, et al\u00a0(2020).\u00a0Expanding tropical forest monitoring into Dry Forests: the DRYFLOR protocol for permanent plots<\/strong>.\u00a0PLANTS, PEOPLE, PLANET<\/em>,\u00a03<\/em>(3), 295-300.\u00a0Full text<\/a>.\"Article<\/a><\/span><\/div>\n
Prestes NCCDS, Massi KG, Silva EA, Nogueira DS, de Oliveira EA, Freitag R, Marimon BS, Marimon-Junior BH, Keller M, Feldpausch TR, et al\u00a0(2020).\u00a0Fire Effects on Understory Forest Regeneration in Southern Amazonia<\/strong>.\u00a0Frontiers in Forests and Global Change<\/em>, . \u00a0Full text<\/a>.\"Article<\/a><\/span><\/div>\n
Oliveira EA, Marimon\u2010Junior BH, Marimon BS, Iriarte J, Morandi PS, Maezumi SY, Nogueira DS, Arag\u00e3o LEOC, Silva IB, Feldpausch TR, et al\u00a0(2020).\u00a0Legacy of Amazonian Dark Earth soils on forest structure and species composition<\/strong>.\u00a0Global Ecology and Biogeography<\/em>,\u00a029<\/em>(9), 1458-1473.\u00a0Full text<\/a>.\"Article<\/a><\/span> (one of the 10 most downloaded papers during its first 12 months of publication).<\/div>\n
Sullivan MJP, Lewis SL, Affum-Baffoe K, Castilho C, Costa F, Sanchez AC, Ewango CEN, Hubau W, Marimon B, Monteagudo-Mendoza A, et al\u00a0(2020).\u00a0Long-term thermal sensitivity of Earth’s tropical forests<\/strong>.\u00a0Science<\/em>,\u00a0368<\/em>(6493), 869-874. \u00a0Author URL<\/a>. \u00a0Full text<\/a>.\"Article<\/a><\/span><\/div>\n
Marimon-Junior BH, Hay JDV, Oliveras I, Jancoski H, Umetsu RK, Feldpausch TR, Galbraith DR, Gloor EU, Phillips OL, Marimon BS, et al\u00a0(2020).\u00a0Soil water-holding capacity and monodominance in Southern Amazon tropical forests<\/strong>.\u00a0Plant and Soil<\/em>,\u00a0450<\/em>(1-2), 65-79. \u00a0Full text<\/a>.\"Article<\/a><\/span><\/div>\n
Muscarella R, Emilio T, Phillips OL, Lewis SL, Slik F, Baker WJ, Couvreur TLP, Eiserhardt WL, Svenning JC, Affum-Baffoe K, et al\u00a0(2020).\u00a0The global abundance of tree palms<\/strong>.\u00a0Global Ecology and Biogeography<\/em>,\u00a029<\/em>(9), 1495-1514. \u00a0Full text<\/a>.<\/div>\n
(one of the 10 most downloaded papers during its first 12 months of publication).<\/div>\n
Morandi PS, Marimon BS, Marimon-Junior BH, Ratter JA, Feldpausch TR, Colli GR, Munhoz CBR, da Silva J\u00fanior MC, de Souza Lima E, Haidar RF, et al\u00a0(2020).\u00a0Tree diversity and above-ground biomass in the South America Cerrado biome and their conservation implications<\/strong>.\u00a0Biodiversity and Conservation<\/em>,\u00a029<\/em>(5), 1519-1536. \u00a0Full text<\/a>.\"Article<\/a><\/span><\/div>\n
Esquivel-Muelbert A, Phillips OL, Brienen RJW, Fauset S, Sullivan MJP, Baker TR, Chao K-J, Feldpausch TR, Gloor E, Higuchi N, et al\u00a0(2020).\u00a0Tree mode of death and mortality risk factors across Amazon forests<\/strong>.\u00a0Nat Commun<\/em>,\u00a011<\/em>(1). \u00a0Author URL<\/a>. \u00a0Full text<\/a>.\"Article<\/a><\/span><\/p>\n

2019<\/h3>\n
Steidinger BS, Crowther TW, Liang J, Van Nuland ME, Werner GDA, Reich PB, Nabuurs G, de-Miguel S, Zhou M, Picard N, et al\u00a0(2019).\u00a0Climatic controls of decomposition drive the global biogeography of forest-tree symbioses<\/strong>.\u00a0Nature<\/em>,\u00a0569<\/em>(7756), 404-408. \u00a0Full text<\/a>.\"Article<\/a><\/span><\/div>\n
Esquivel-Muelbert A, Baker TR, Dexter KG, Lewis SL, Brienen RJW, Feldpausch TR, Lloyd J, Monteagudo-Mendoza A, Arroyo L, \u00c1lvarez-D\u00e1vila E, et al\u00a0(2019).\u00a0Compositional response of Amazon forests to climate change<\/strong>.\u00a0Global Change Biology<\/em>,\u00a025<\/em>(1), 39-56. \u00a0Full text<\/a>.\"Article<\/a><\/span><\/div>\n
Aguirre-Guti\u00e9rrez J, Oliveras I, Rifai S, Fauset S, Adu-Bredu S, Affum-Baffoe K, Baker TR, Feldpausch TR, Gvozdevaite A, Hubau W, et al\u00a0(2019).\u00a0Drier tropical forests are susceptible to functional changes in response to a long-term drought<\/strong>.\u00a0Ecol Lett<\/em>,\u00a022<\/em>(5), 855-865. \u00a0Author URL<\/a>. \u00a0Full text<\/a>.\"Article<\/a><\/span><\/div>\n
Requena Suarez D, Rozendaal DMA, De Sy V, Phillips OL, Alvarez-D\u00e1vila E, Anderson-Teixeira K, Araujo-Murakami A, Arroyo L, Baker TR, Bongers F, et al\u00a0(2019).\u00a0Estimating aboveground net biomass change for tropical and subtropical forests: Refinement of IPCC default rates using forest plot data<\/strong>.\u00a0Glob Chang Biol<\/em>,\u00a025<\/em>(11), 3609-3624. \u00a0Author URL<\/a>. \u00a0Full text<\/a>.\"Article<\/a><\/span><\/div>\n
Coelho de Souza F, Dexter KG, Phillips OL, Pennington RT, Neves D, Sullivan MJP, Alvarez-Davila E, Alves \u00c1, Amaral I, Andrade A, et al\u00a0(2019).\u00a0Evolutionary diversity is associated with wood productivity in Amazonian forests<\/strong>.\u00a0Nat Ecol Evol<\/em>,\u00a03<\/em>(12), 1754-1761. \u00a0Author URL<\/a>. \u00a0Full text<\/a>.\"Article<\/a><\/span><\/div>\n
Nogueira DS, Marimon BS, Marimon-Junior BH, Oliveira EA, Morandi P, Reis SM, Elias F, Neves EC, Feldpausch TR, Lloyd J, et al\u00a0(2019).\u00a0Impacts of Fire on Forest Biomass Dynamics at the Southern Amazon Edge<\/strong>.\u00a0Environmental Conservatio<\/em>. \u00a0Full text<\/a>.\"Article<\/a><\/span><\/div>\n
Burton C (2019). Impacts of fire, climate and land-use change on terrestrial ecosystems<\/strong>. \u00a0Full text<\/a>.<\/div>\n
Fauset S, Gloor M, Fyllas NM, Phillips OL, Asner GP, Baker TR, Patrick Bentley L, Brienen RJW, Christoffersen BO, del Aguila-Pasquel J, et al\u00a0(2019).\u00a0Individual-based modeling of amazon forests suggests that climate controls productivity while traits control demography<\/strong>.\u00a0Frontiers in Earth Science<\/em>,\u00a07<\/em>. \u00a0Full text<\/a>.\"Article<\/a><\/span><\/div>\n
ter Steege H, Henkel TW, Helal N, Marimon BS, Marimon-Junior BH, Huth A, Groeneveld J, Sabatier D, Coelho LDS, Filho DDAL, et al\u00a0(2019).\u00a0Rarity of monodominance in hyperdiverse Amazonian forests<\/strong>.\u00a0Scientific Reports<\/em>,\u00a09<\/em>(1). \u00a0Full text<\/a>.\"Article<\/a><\/span><\/div>\n
Burton C, Betts R, Cardoso M, Feldpausch TR, Harper A, Jones CD, Kelley DI, Robertson E, Wiltshire A\u00a0(2019).\u00a0Representation of fire, land-use change and vegetation dynamics in the Joint UK Land Environment Simulator vn4.9 (JULES)<\/strong>.\u00a0GEOSCIENTIFIC MODEL DEVELOPMENT<\/em>,\u00a012<\/em>(1), 179-193.\u00a0Author URL<\/a>. \u00a0Full text<\/a>.\"Article<\/a><\/span><\/div>\n
Marimon-Junior BH, Hay JDV, Oliveras I, Jancoski H, Umetsu RK, Feldpausch TR, Galbraith DR, Gloor EU, Phillips OL, Marimon BS, et al\u00a0(2019).\u00a0Soil water-holding capacity and monodominance in Southern Amazon tropical forests<\/strong>.\u00a0Plant and Soil<\/em>. \u00a0Full text<\/a>.\"Article<\/a><\/span><\/div>\n
Schepaschenko D, Chave J, Phillips OL, Lewis SL, Davies SJ, R\u00e9jou-M\u00e9chain M, Sist P, Scipal K, Perger C, Herault B, et al\u00a0(2019).\u00a0The Forest Observation System, building a global reference dataset for remote sensing of forest biomass<\/strong>.\u00a0Scientific data<\/em>,\u00a06<\/em>(1). \u00a0Full text<\/a>.\"Article<\/a><\/span><\/div>\n
Hubau W, De Mil T, Van den Bulcke J, Phillips OL, Angoboy Ilondea B, Van Acker J, Sullivan MJP, Nsenga L, Toirambe B, Couralet C, et al\u00a0(2019).\u00a0The persistence of carbon in the African forest understory<\/strong>.\u00a0Nature Plants<\/em>,\u00a05<\/em>(2), 133-140. \u00a0Full text<\/a>.\"Article<\/a><\/span><\/div>\n
\nHarrison ME, Ottay JB, D\u2019Arcy LJ, Cheyne SM, Anggodo, Belcher C, Cole L, Dohong A, Ermiasi Y, Feldpausch T, et al\u00a0(2019).\u00a0Tropical forest and peatland conservation in Indonesia: Challenges and directions<\/strong>.\u00a0People and Nature<\/em>,\u00a02<\/em>(1), 4-28.\u00a0Full text<\/a>.\"Article<\/a><\/span><\/p>\n

2018<\/h3>\n
\nReis SM, Marimon BS, Marimon Junior BH, Morandi PS, de Oliveira EA, Elias F, Das Neves EC, de Oliveira B, Nogueira DDS, Umetsu RK, et al\u00a0(2018).\u00a0Climate and fragmentation affect forest structure at the southern border of amazonia<\/strong>.\u00a0Plant Ecology and Diversity<\/em>,\u00a011<\/em>(1), 13-25. \u00a0Full text<\/a>.\u00a0\"Article<\/a><\/span><\/p>\n<\/div>\n
\nSullivan MJP, Lewis SL, Hubau W, Qie L, Baker TR, Banin LF, Chave J, Cuni-Sanchez A, Feldpausch TR, Lopez-Gonzalez G, et al\u00a0(2018).\u00a0Field methods for sampling tree height for tropical forest biomass estimation<\/strong>.\u00a0Methods in Ecology and Evolution<\/em>,\u00a09<\/em>(5), 1179-1189. \u00a0Full text<\/a>.\u00a0\"Article<\/a><\/span><\/p>\n<\/div>\n
\nBastin JF, Rutishauser E, Kellner JR, Saatchi S, P\u00e9lissier R, H\u00e9rault B, Slik F, Bogaert J, De Canni\u00e8re C, Marshall AR, et al\u00a0(2018).\u00a0Pan-tropical prediction of forest structure from the largest trees<\/strong>.\u00a0Global Ecology and Biogeography<\/em>,\u00a027<\/em>(11), 1366-138. \u00a0Full text<\/a>.\u00a0\"Article<\/a><\/span><\/p>\n<\/div>\n
\nPassos FB, Marimon BS, Phillips OL, Morandi PS, das Neves EC, Elias F, Reis SM, de Oliveira B, Feldpausch TR, Marimon J\u00fanior BH, et al\u00a0(2018).\u00a0Savanna turning into forest: concerted vegetation change at the ecotone between the Amazon and \u201cCerrado\u201d biomes<\/strong>.\u00a0Revista Brasileira de Botanica<\/em>,\u00a041<\/em>(3), 611-619. \u00a0Full text<\/a>.\u00a0\"Article<\/a><\/span><\/p>\n<\/div>\n
\nMorandi PS, Marimon BS, Marimon-Junior BH, Ratter JA, Feldpausch TR, Colli GR, Munhoz CBR, da Silva J\u00fanior MC, de Souza Lima E, Haidar RF, et al\u00a0(2018).\u00a0Tree diversity and above-ground biomass in the South America Cerrado biome and their conservation implications<\/strong>.\u00a0Biodiversity and Conservation<\/em>, 1-18. \u00a0Full text<\/a>.\u00a0\"Article<\/a><\/span><\/p>\n<\/div>\n
\nLoubota Panzou GJ, Fayolle A, Feldpausch TR, Ligot G, Doucet JL, Forni E, Zombo I, Mazengue M, Loumeto JJ, Gourlet-Fleury S, et al\u00a0(2018).\u00a0What controls local-scale aboveground biomass variation in central Africa? Testing structural, composition and architectural attributes<\/strong>.\u00a0Forest Ecology and Management<\/em>,\u00a0429<\/em>, 570-578. \u00a0Full text<\/a>.\u00a0\"Article<\/a><\/span><\/p>\n<\/div>\n

2017<\/h3>\n
\nKoele N, Bird M, Haig J, Marimon-Junior BH, Marimon BS, Phillips OL, de Oliveira EA, Quesada CA, Feldpausch TR\u00a0(2017).\u00a0Amazon Basin forest pyrogenic carbon stocks: First estimate of deep storage<\/strong>.\u00a0Geoderma<\/em>,\u00a0306<\/em>, 237-243. \u00a0Full text<\/a>.\u00a0\"Article<\/a><\/span><\/p>\n<\/div>\n
Goulart AC, Macario KD, Scheel-Ybert R, Alves EQ, Bachelet C, Pereira BB, Levis C, Marimon Junior BH, Marimon BS, Quesada CA, et al\u00a0(2017).\u00a0Charcoal chronology of the Amazon forest: a record of biodiversity preserved by ancient fires<\/strong>.\u00a0Quaternary Geochronology<\/em>,\u00a041<\/em>, 180-186. \u00a0Full text<\/a>.<\/div>\n
\nMassi KG, Bird M, Marimon BS, Marimon BH, Nogueira DS, Oliveira EA, Phillips OL, Quesada CA, Andrade AS, Brienen RJW, et al\u00a0(2017).\u00a0Does soil pyrogenic carbon determine plant functional traits in Amazon Basin forests?<\/strong>.\u00a0Plant Ecology<\/em>,\u00a0218<\/em>(9), 1047-1062. \u00a0Full text<\/a>.\u00a0\"Article<\/a><\/span><\/p>\n<\/div>\n
\nLevis C, Costa FRC, Bongers F, Pena-Claros M, Clement CR, Junqueira AB, Neves EG, Tamanaha EK, Figueiredo FOG, Salomao RP, et al\u00a0(2017).\u00a0Persistent effects of pre-Columbian plant domestication on Amazonian forest composition<\/strong>.\u00a0Science<\/em>,\u00a0355<\/em>(6328), 925-+.\u00a0Author URL<\/a>. \u00a0Full text<\/a>.\u00a0\"Article<\/a><\/span><\/p>\n<\/div>\n
\nNingthoujam RK, Balzter H, Tansey K, Feldpausch TR, Mitchard ETA, Wani AA, Joshi PK\u00a0(2017).\u00a0Relationships of S-band radar backscatter and forest aboveground biomass in different forest types<\/strong>.\u00a0Remote Sensing<\/em>,\u00a09<\/em>(11). \u00a0Full text<\/a>.\u00a0\"Article<\/a><\/span><\/p>\n<\/div>\n
\nEsquivel-Muelbert A, Baker TR, Dexter KG, Lewis SL, ter Steege H, Lopez-Gonzalez G, Monteagudo Mendoza A, Brienen R, Feldpausch TR, Pitman N, et al\u00a0(2017).\u00a0Seasonal drought limits tree species across the Neotropics<\/strong>.\u00a0Ecography<\/em>,\u00a040<\/em>(5), 618-629. \u00a0Full text<\/a>.\u00a0\"Article<\/a><\/span><\/p>\n<\/div>\n

2016<\/h3>\n
\nFeldpausch TR, Phillips OL, Brienen RJW, Gloor E, Lloyd J, Lopez-Gonzalez G, Monteagudo-Mendoza A, Malhi Y, Alarc\u00f3n A, \u00c1lvarez D\u00e1vila E, et al\u00a0(2016).\u00a0Amazon forest response to repeated droughts<\/strong>.\u00a0Global Biogeochemical Cycles<\/em>,\u00a030<\/em>(7), 964-982. \u00a0Full text<\/a>.\u00a0\"Article<\/a><\/span><\/p>\n<\/div>\n
Watling J, Iriarte J, Whitney BS, Consuelo E, Mayle F, Castro W, Schaan D, Feldpausch TR\u00a0(2016).\u00a0Differentiation of neotropical ecosystems by modern soil phytolith assemblages and its implications for palaeoenvironmental and archaeological reconstructions II: Southwestern Amazonian forests<\/strong>.\u00a0Review of Palaeobotany and Palynology<\/em>,\u00a0226<\/em>, 30-43. \u00a0Full text<\/a>.<\/div>\n
\nLevine NM, Zhang K, Longo M, Baccini A, Phillips OL, Lewis SL, Alvarez-D\u00e1vila E, Segalin de Andrade AC, Brienen RJW, Erwin TL, et al\u00a0(2016).\u00a0Ecosystem heterogeneity determines the ecological resilience of the Amazon to climate change<\/strong>.\u00a0Proc Natl Acad Sci U S A<\/em>,\u00a0113<\/em>(3), 793-797. \u00a0Author URL<\/a>. \u00a0Full text<\/a>.\u00a0\"Article<\/a><\/span><\/p>\n<\/div>\n
\nTymen B, R\u00e9jou-M\u00e9chain M, Dalling JW, Fauset S, Feldpausch TR, Norden N, Phillips OL, Turner BL, Viers J, Chave J, et al\u00a0(2016).\u00a0Evidence for arrested succession in a liana-infested Amazonian forest<\/strong>.\u00a0Journal of Ecology<\/em>,\u00a0104<\/em>(1), 149-159. \u00a0Full text<\/a>.\u00a0\"Article<\/a><\/span><\/p>\n<\/div>\n
\nMorandi PS, Marimon BS, Eisenlohr PV, Marimon-Junior BH, Oliveira-Santos C, Feldpausch TR, De Oliveira EA, Reis SM, Lloyd J, Phillips OL, et al\u00a0(2016).\u00a0Patterns of tree species composition at watershed-scale in the Amazon ‘arc of deforestation’: Implications for conservation<\/strong>.\u00a0Environmental Conservation<\/em>,\u00a043<\/em>(4), 317-326. \u00a0Full text<\/a>.\u00a0\"Article<\/a><\/span><\/p>\n<\/div>\n
\nHo Tong Minh D, Le Toan T, Rocca F, Tebaldini S, Villard L, R\u00e9jou-M\u00e9chain M, Phillips OL, Feldpausch TR, Dubois-Fernandez P, Scipal K, et al\u00a0(2016).\u00a0SAR tomography for the retrieval of forest biomass and height: Cross-validation at two tropical forest sites in French Guiana<\/strong>.\u00a0Remote Sensing of Environment<\/em>,\u00a0175<\/em>, 138-147. \u00a0Full text<\/a>.\u00a0\"Article<\/a><\/span><\/p>\n<\/div>\n

2015<\/h3>\n
\nFerreira Domingues T, Ishida FY, Feldpausch TR, Grace J, Meir P, Saiz G, Sene O, Schrodt F, Sonk\u00e9 B, Taedoumg H, et al\u00a0(2015).\u00a0Biome-specific effects of nitrogen and phosphorus on the photosynthetic characteristics of trees at a forest-savanna boundary in Cameroon<\/strong>.\u00a0Oecologia<\/em>. \u00a0Full text<\/a>.\u00a0\"Article<\/a><\/span><\/p>\n<\/div>\n
Maracahipes Santos L, Lenza E, dos Santos JO, Marimon BS, Eisenlohr PV, Marimon Junior BH, Feldpausch TR\u00a0(2015).\u00a0Diversity, floristic composition, and structure of the woody vegetation of the Cerrado in the Cerrado\u2013Amazon transition zone in Mato Grosso, Brazil<\/strong>.\u00a0Revista Brasileira de Botanica<\/em>,\u00a038<\/em>(4), 877-887. \u00a0Full text<\/a>.<\/div>\n
\nDoughty CE, Metcalfe DB, Girardin CAJ, Am\u00e9zquita FF, Cabrera DG, Huasco WH, Silva-Espejo JE, Araujo-Murakami A, da Costa MC, Rocha W, et al\u00a0(2015).\u00a0Drought impact on forest carbon dynamics and fluxes in Amazonia<\/strong>.\u00a0Nature<\/em>,\u00a0519<\/em>(7541), 78-82. \u00a0Author URL<\/a>. \u00a0Full text<\/a>.\u00a0\"Article<\/a><\/span><\/p>\n<\/div>\n
\nMarimon BS, Colli GR, Marimon-Junior BH, Mews HA, Eisenlohr PV, Feldpausch TR, Phillips OL\u00a0(2015).\u00a0Ecology of floodplain campos de murundus savanna in southern Amazonia<\/strong>.\u00a0International Journal of Plant Sciences<\/em>,\u00a0176<\/em>(7), 670-681. \u00a0Full text<\/a>.\u00a0\"Article<\/a><\/span><\/p>\n<\/div>\n
\nLloyd J, Domingues TF, Schrodt F, Ishida FY, Feldpausch TR, Saiz G, Quesada CA, Schwarz M, Torello-Raventos M, Gilpin M, et al\u00a0(2015).\u00a0Edaphic, structural and physiological contrasts across Amazon Basin forest-savanna ecotones suggest a role for potassium as a key modulator of tropical woody vegetation structure and function<\/strong>.\u00a0Biogeosciences<\/em>,\u00a012<\/em>(22), 6529-6571. \u00a0Full text<\/a>.\u00a0\"Article<\/a><\/span><\/p>\n<\/div>\n
\nEsp\u00edrito-Santo FD, Gloor M, Keller M, Malhi Y, Saatchi S, Nelson B, Junior RCO, Pereira C, Lloyd J, Frolking S, et al\u00a0(2015).\u00a0Erratum: Corrigendum: Size and frequency of natural forest disturbances and the Amazon forest carbon balance<\/strong>.\u00a0Nature Communications<\/em>,\u00a06<\/em>(1).\u00a0Full text<\/a>.\u00a0\"Article<\/a><\/span><\/p>\n<\/div>\n
\nTer Steege H, Pitman NCA, Killeen TJ, Laurance WF, Peres CA, Guevara JE, Salom\u00e3o RP, Castilho CV, Amaral IL, de Almeida Matos FD, et al\u00a0(2015).\u00a0Estimating the global conservation status of more than 15,000 Amazonian tree species<\/strong>.\u00a0Sci Adv<\/em>,\u00a01<\/em>(10). \u00a0Author URL<\/a>. \u00a0Full text<\/a>.\u00a0\"Article<\/a><\/span><\/p>\n<\/div>\n
\nDexter KG, Smart B, Baldauf C, Baker TR, Balinga MPB, Brienen RJW, Fauset S, Feldpausch TR, Ferreira-Da Silva L, Muledi JI, et al\u00a0(2015).\u00a0Floristics and biogeography of vegetation in seasonally dry tropical regions<\/strong>.\u00a0INTERNATIONAL FORESTRY REVIEW<\/em>,\u00a017<\/em>, 10-32.\u00a0Author URL<\/a>. \u00a0Full text<\/a>.\u00a0\"Article<\/a><\/span><\/p>\n<\/div>\n
\nSchrodt F, Domingues TF, Feldpausch TR, Saiz G, Quesada CA, Schwarz M, Ishida FY, Compaore H, Diallo A, Djagbletey G, et al\u00a0(2015).\u00a0Foliar trait contrasts between African forest and savanna trees: Genetic versus environmental effects<\/strong>.\u00a0Functional Plant Biology<\/em>,\u00a042<\/em>(1), 63-83. \u00a0Full text<\/a>.<\/p>\n<\/div>\n
\nFauset S, Johnson MO, Gloor M, Baker TR, Monteagudo M A, Brienen RJW, Feldpausch TR, Lopez-Gonzalez G, Malhi Y, ter Steege H, et al\u00a0(2015).\u00a0Hyperdominance in Amazonian forest carbon cycling<\/strong>.\u00a0Nat Commun<\/em>,\u00a06<\/em>. \u00a0Author URL<\/a>. \u00a0Full text<\/a>.\u00a0\"Article<\/a><\/span><\/p>\n<\/div>\n
\nBrienen RJW, Phillips OL, Feldpausch TR, Gloor E, Baker TR, Lloyd J, Lopez-Gonzalez G, Monteagudo-Mendoza A, Malhi Y, Lewis SL, et al\u00a0(2015).\u00a0Long-term decline of the Amazon carbon sink<\/strong>.\u00a0Nature<\/em>,\u00a0519<\/em>(7543), 344-348. \u00a0Author URL<\/a>. \u00a0Full text<\/a>.\u00a0\"Article<\/a><\/span><\/p>\n<\/div>\n
\nHonorio Coronado EN, Dexter KG, Pennington RT, Chave J, Lewis SL, Alexiades MN, Alvarez E, Alves de Oliveira A, Amaral IL, Araujo-Murakami A, et al\u00a0(2015).\u00a0Phylogenetic diversity of Amazonian tree communities<\/strong>.\u00a0Diversity and Distributions<\/em>. \u00a0Full text<\/a>.\u00a0\"Article<\/a><\/span><\/p>\n<\/div>\n
\nReis SM, Lenza E, Marimon BS, Gomes L, Forsthofer M, Morandi PS, Junior BHM, Feldpausch TR, Elias F\u00a0(2015).\u00a0Post-fire dynamics of the woody vegetation of a savanna forest (Cerrad\u00e3o) in the Cerrado-Amazon transition zone<\/strong>.\u00a0Acta Botanica Brasilica<\/em>,\u00a029<\/em>(3), 408-416. \u00a0Full text<\/a>.\u00a0\"Article<\/a><\/span><\/p>\n<\/div>\n
\nGloor M, Barichivich J, Ziv G, Brienen R, Sch\u00f6ngart J, Peylin P, Ladvocat Cintra BB, Feldpausch T, Phillips O, Baker J, et al\u00a0(2015).\u00a0Recent Amazon climate as background for possible ongoing and future changes of Amazon humid forests<\/strong>.\u00a0Global Biogeochemical Cycles<\/em>,\u00a029<\/em>(9), 1384-1399. \u00a0Full text<\/a>.\u00a0\"Article<\/a><\/span><\/p>\n<\/div>\n
\nVeenendaal EM, Torello-Raventos M, Feldpausch TR, Domingues TF, Gerard F, Schrodt F, Saiz G, Quesada CA, Djagbletey G, Ford A, et al\u00a0(2015).\u00a0Structural, physiognomic and above-ground biomass variation in savanna-forest transition zones on three continents – How different are co-occurring savanna and forest formations?<\/strong>.\u00a0Biogeosciences<\/em>,\u00a012<\/em>(10), 2927-2951. \u00a0Full text<\/a>.\u00a0\"Article<\/a><\/span><\/p>\n<\/div>\n
\nSaiz G, Bird M, Wurster C, Quesada CA, Ascough P, Domingues T, Schrodt F, Schwarz M, Feldpausch TR, Veenendaal E, et al\u00a0(2015).\u00a0The influence of C3 and C4 vegetation on soil organic matter dynamics in contrasting semi-natural tropical ecosystems<\/strong>.\u00a0Biogeosciences<\/em>,\u00a012<\/em>(16), 5041-5059. \u00a0Full text<\/a>.<\/p>\n<\/div>\n
\nR\u00e9jou-M\u00e9chain M, Tymen B, Blanc L, Fauset S, Feldpausch TR, Monteagudo A, Phillips OL, Richard H, Chave J\u00a0(2015).\u00a0Using repeated small-footprint LiDAR acquisitions to infer spatial and temporal variations of a high-biomass Neotropical forest<\/strong>.\u00a0Remote Sensing of Environment<\/em>,\u00a0169<\/em>, 93-101. \u00a0Full text<\/a>.<\/p>\n<\/div>\n

2014<\/h3>\n
\nMitchard ETA, Feldpausch TR, Brienen RJW, Lopez-Gonzalez G, Monteagudo A, Baker TR, Lewis SL, Lloyd J, Quesada CA, Gloor M, et al\u00a0(2014).\u00a0Markedly divergent estimates of amazon forest carbon density from ground plots and satellites<\/strong>.\u00a0Global Ecology and Biogeography<\/em>\u00a0Full text<\/a>.<\/p>\n<\/div>\n
\nTalbot J, Lewis SL, Lopez-Gonzalez G, Brienen RJW, Monteagudo A, Baker TR, Feldpausch TR, Malhi Y, Vanderwel M, Araujo Murakami A, et al\u00a0(2014).\u00a0Methods to estimate aboveground wood productivity from long-term forest inventory plots<\/strong>.\u00a0Forest Ecology and Management<\/em>,\u00a0320<\/em>, 30-38. \u00a0Full text<\/a>.\u00a0\"Article<\/a><\/span><\/p>\n<\/div>\n
\nEsp\u00edrito-Santo FDB, Gloor M, Keller M, Malhi Y, Saatchi S, Nelson B, Junior RCO, Pereira C, Lloyd J, Frolking S, et al\u00a0(2014).\u00a0Size and frequency of natural forest disturbances and the Amazon forest carbon balance<\/strong>.\u00a0Nat Commun<\/em>,\u00a05<\/em>. \u00a0Author URL<\/a>. \u00a0Full text<\/a>.\u00a0\"Article<\/a><\/span><\/p>\n<\/div>\n
\nMartins DL, Schietti J, Feldpausch TR, Luiz\u00e3o FJ, Phillips OL, Andrade A, Castilho CV, Laurance SG, Oliveira \u00c1, Amaral IL, et al\u00a0(2014).\u00a0Soil-induced impacts on forest structure drive coarse woody debris stocks across central Amazonia<\/strong>.\u00a0Plant Ecology and Diversity<\/em>\u00a0Full text<\/a>.<\/p>\n<\/div>\n

2013<\/h3>\n
\nLewis SL, Sonk\u00e9 B, Sunderland T, Begne SK, Lopez-Gonzalez G, van der Heijden GMF, Phillips OL, Affum-Baffoe K, Baker TR, Banin L, et al\u00a0(2013).\u00a0Above-ground biomass and structure of 260 African tropical forests<\/strong>.\u00a0Philosophical Transactions of the Royal Society B: Biological Sciences<\/em>,\u00a0368<\/em>(1625). \u00a0Full text<\/a>.\u00a0\"Article<\/a><\/span><\/p>\n<\/div>\n
Butler A, Marimon-Junior BH, Maracahipes L, Marimon BS, Silv\u00e9rio DV, Oliveira EA, Lenza E, Feldpausch TR, Meir P, J. G, et al\u00a0(2013).\u00a0Absorbing Roots Areas and Transpiring Leaf Areas at the Tropical Forest and Savanna Boundary in Brazil. In Perrault C, Bellamy L\u00a0(Eds.)<\/strong>\u00a0Savannas: Climate, Biodiversity and Ecological Significance<\/em>, Hauppauge, New York: Nova Science Publishers, Inc. 107-126. \u00a0Full text<\/a>.<\/div>\n
\nTer Steege H, Pitman NCA, Sabatier D, Baraloto C, Salom\u00e3o RP, Guevara JE, Phillips OL, Castilho CV, Magnusson WE, Molino JF, et al\u00a0(2013).\u00a0Hyperdominance in the Amazonian tree flora<\/strong>.\u00a0Science<\/em>,\u00a0342<\/em>(6156). \u00a0Full text<\/a>.\u00a0\"Article<\/a><\/span><\/p>\n<\/div>\n
\nGloor M, Brienen RJW, Galbraith D, Feldpausch TR, Sch\u00f6ngart J, Guyot JL, Espinoza JC, Lloyd J, Phillips OL\u00a0(2013).\u00a0Intensification of the Amazon hydrological cycle over the last two decades<\/strong>.\u00a0Geophysical Research Letters<\/em>,\u00a040<\/em>(9), 1729-1733. \u00a0Full text<\/a>.\u00a0\"Article<\/a><\/span><\/p>\n<\/div>\n
\nTorello-Raventos M, Feldpausch TR, Veenendaal E, Schrodt F, Saiz G, Domingues TF, Djagbletey G, Ford A, Kemp J, Marimon BS, et al\u00a0(2013).\u00a0On the delineation of tropical vegetation types with an emphasis on forest\/savanna transitions<\/strong>.\u00a0Plant Ecology and Diversity<\/em>,\u00a06<\/em>(1), 101-137.<\/p>\n<\/div>\n

2012<\/h3>\n
\nFauset S, Baker TR, Lewis SL, Feldpausch TR, Affum-Baffoe K, Foli EG, Hamer KC, Swaine MD\u00a0(2012).\u00a0Drought-induced shifts in the floristic and functional composition of tropical forests in Ghana<\/strong>.\u00a0Ecol Lett<\/em>,\u00a015<\/em>(10), 1120-1129. \u00a0Author URL<\/a>.\u00a0\"Article<\/a><\/span><\/p>\n<\/div>\n
\nGloor M, Gatti L, Brienen R, Feldpausch TR, Phillips OL, Miller J, Ometto JP, Rocha H, Baker T, De Jong B, et al\u00a0(2012).\u00a0The carbon balance of South America: a review of the status, decadal trends and main determinants<\/strong>.\u00a0Biogeosciences<\/em>,\u00a09<\/em>(12), 5407-543. \u00a0Full text<\/a>.\u00a0\"Article<\/a><\/span><\/p>\n<\/div>\n
\nFeldpausch TR, Lloyd J, Lewis SL, Brienen RJW, Gloor M, Monteagudo Mendoza A, Lopez-Gonzalez G, Banin L, Abu Salim K, Affum-Baffoe K, et al\u00a0(2012).\u00a0Tree height integrated into pantropical forest biomass estimates<\/strong>.\u00a0Biogeosciences<\/em>,\u00a09<\/em>(8), 3381-3403.\u00a0Author URL<\/a>. \u00a0Full text<\/a>.<\/p>\n<\/div>\n
\nSaiz G, Bird MI, Domingues T, Schrodt F, Schwarz M, Feldpausch TR, Veenendaal E, Djagbletey G, Hien F, Compaore H, et al\u00a0(2012).\u00a0Variation in soil carbon stocks and their determinants across a precipitation gradient in West Africa<\/strong>.\u00a0Global Change Biology<\/em>,\u00a018<\/em>(5), 1670-1683.<\/p>\n<\/div>\n
\nBanin L, Feldpausch TR, Phillips OL, Baker TR, Lloyd J, Affum-Baffoe K, Arets EJMM, Berry NJ, Bradford M, Brienen RJW, et al\u00a0(2012).\u00a0What controls tropical forest architecture? Testing environmental, structural and floristic drivers<\/strong>.\u00a0Global Ecology and Biogeography<\/em>,\u00a021<\/em>(12), 1179-1190.\u00a0\"Article<\/a><\/span><\/p>\n<\/div>\n

2011<\/h3>\n
\nMitchard ETA, Saatchi SS, Lewis SL, Feldpausch TR, Gerard FF, Woodhouse IH, Meir P\u00a0(2011).\u00a0Comment on ‘A first map of tropical Africa’s above-ground biomass derived from satellite imagery’<\/strong>.\u00a0Environmental Research Letters<\/em>,\u00a06<\/em>(4). \u00a0Full text<\/a>.\u00a0\"Article<\/a><\/span><\/p>\n<\/div>\n
\nFeldpausch TR, Banin L, Phillips OL, Baker TR, Lewis SL, Quesada CA, Affum-Baffoe K, Arets EJMM, Berry NJ, Bird M, et al\u00a0(2011).\u00a0Height-diameter allometry of tropical forest trees<\/strong>.\u00a0Biogeosciences<\/em>,\u00a08<\/em>(5), 1081-1106. \u00a0Full text<\/a>.\u00a0\"Article<\/a><\/span><\/p>\n<\/div>\n
\nMitchard ETA, Saatchi SS, Lewis SL, Feldpausch TR, Woodhouse IH, Sonk\u00e9 B, Rowland C, Meir P\u00a0(2011).\u00a0Measuring biomass changes due to woody encroachment and deforestation\/degradation in a forest-savanna boundary region of central Africa using multi-temporal L-band radar backscatter<\/strong>.\u00a0Remote Sensing of Environment<\/em>,\u00a0115<\/em>(11), 2861-2873.<\/p>\n<\/div>\n
\nAraujo-Murakami A, Parada AG, Ter\u00e1n JJ, Baker TR, Feldpausch TR, Phillips OL, Brienen RJW\u00a0(2011).\u00a0Necromass in forests of Madre de Dios, Peru: a comparison between terra firme and lowland forests<\/strong>.\u00a0Revista Peruana de Biologia<\/em>,\u00a018<\/em>(1), 113-118. \u00a0Full text<\/a>.<\/p>\n<\/div>\n
\nBarlow J, Ewers RM, Anderson L, Aragao LEOC, Baker TR, Boyd E, Feldpausch TR, Gloor E, Hall A, Malhi Y, et al\u00a0(2011).\u00a0Using learning networks to understand complex systems: a case study of biological, geophysical and social research in the Amazon<\/strong>.\u00a0Biol Rev Camb Philos Soc<\/em>,\u00a086<\/em>(2), 457-474. \u00a0Author URL<\/a>.\u00a0\"Article<\/a><\/span><\/p>\n<\/div>\n

2010<\/h3>\n
\nvan der Heijden GMF, Feldpausch TR, Herrero ADLF, van der Velden NK, Phillips OL\u00a0(2010).\u00a0Calibrating the liana crown occupancy index in Amazonian forests<\/strong>.\u00a0Forest Ecology and Management<\/em>,\u00a0260<\/em>(4), 549-555.<\/p>\n<\/div>\n
\nDomingues TF, Meir P, Feldpausch TR, Saiz G, Veenendaal EM, Schrodt F, Bird M, Djagbletey G, Hien F, Compaore H, et al\u00a0(2010).\u00a0Co-limitation of photosynthetic capacity by nitrogen and phosphorus in West Africa woodlands<\/strong>.\u00a0Plant Cell Environ<\/em>,\u00a033<\/em>(6), 959-980. \u00a0Author URL<\/a>.<\/p>\n<\/div>\n
\nPhillips OL, van der Heijden G, Lewis SL, L\u00f3pez-Gonz\u00e1lez G, Arag\u00e3o LEOC, Lloyd J, Malhi Y, Monteagudo A, Almeida S, D\u00e1vila EA, et al\u00a0(2010).\u00a0Drought-mortality relationships for tropical forests<\/strong>.\u00a0New Phytol<\/em>,\u00a0187<\/em>(3), 631-646. \u00a0Author URL<\/a>.\u00a0\"Article<\/a><\/span><\/p>\n<\/div>\n
\nFeldpausch TR, Couto EG, Rodrigues LC, Pauletto D, Johnson MS, Fahey TJ, Lehmann J, Riha SJ\u00a0(2010).\u00a0Nitrogen aboveground turnover and soil stocks to 8 m depth in primary and selectively logged forest in southern Amazonia<\/strong>.\u00a0Global Change Biology<\/em>,\u00a016<\/em>(6), 1793-1805.<\/p>\n<\/div>\n

2009<\/h3>\n
\nStropp J, ter Steege H, Malhi Y, Monteagudo A, Prieto A, Rudas A, Araujo-Murakami A, de Oliveira AA, Alonso A, Fuentes A, et al\u00a0(2009).\u00a0Disentangling regional and local tree diversity in the Amazon<\/strong>.\u00a0ECOGRAPHY<\/em>,\u00a032<\/em>(1), 46-54.\u00a0Author URL<\/a>. \u00a0Full text<\/a>.<\/p>\n<\/div>\n
\nGloor M, Phillips OL, Lloyd JJ, Lewis SL, Malhi Y, Baker TR, Lopez-Gonzalez G, Peacock J, Almeida S, Alves de Oliveira AC, et al\u00a0(2009).\u00a0Does the disturbance hypothesis explain the biomass increase in basin-wide Amazon forest plot data?<\/strong>.\u00a0GLOBAL CHANGE BIOLOGY<\/em>,\u00a015<\/em>(10), 2418-2430.\u00a0Author URL<\/a>.\u00a0\"Article<\/a><\/span><\/p>\n<\/div>\n
\nPhillips OL, Arag\u00e3o LEOC, Lewis SL, Fisher JB, Lloyd J, L\u00f3pez-Gonz\u00e1lez G, Malhi Y, Monteagudo A, Peacock J, Quesada CA, et al\u00a0(2009).\u00a0Drought sensitivity of the Amazon rainforest<\/strong>.\u00a0Science<\/em>,\u00a0323<\/em>(5919), 1344-1347. \u00a0Author URL<\/a>.\u00a0\"Article<\/a><\/span><\/p>\n<\/div>\n
\nLewis SL, Lopez-Gonzalez G, Sonk\u00e9 B, Affum-Baffoe K, Baker TR, Ojo LO, Phillips OL, Reitsma JM, White L, Comiskey JA, et al\u00a0(2009).\u00a0Increasing carbon storage in intact African tropical forests<\/strong>.\u00a0Nature<\/em>,\u00a0457<\/em>(7232), 1003-1006. \u00a0Author URL<\/a>.\u00a0\"Article<\/a><\/span><\/p>\n<\/div>\n
\nHorowitz ME, Fahey TJ, Yavitt JB, Feldpausch TR, Sherman RE\u00a0(2009).\u00a0Patterns of late-season photosynthate movement in sugar maple saplings<\/strong>.\u00a0Canadian Journal of Forest Research<\/em>,\u00a039<\/em>(12), 2294-2298.<\/p>\n<\/div>\n
\nMitchard ETA, Saatchi SS, Woodhouse IH, Nangendo G, Ribeiro NS, Williams M, Ryan CM, Lewis SL, Feldpausch TR, Meir P, et al\u00a0(2009).\u00a0Using satellite radar backscatter to predict above-ground woody biomass: a consistent relationship across four different African landscapes<\/strong>.\u00a0Geophysical Research Letters<\/em>,\u00a036<\/em>(23). \u00a0Full text<\/a>.<\/p>\n<\/div>\n

2008<\/h3>\n
\nSilva CEMD, Gon\u00e7alves JFDC, Feldpausch TR\u00a0(2008).\u00a0Water-use efficiency of tree species following calcium and phosphorus application on an abandoned pasture, central Amazonia, Brazil<\/strong>.\u00a0Environmental and Experimental Botany<\/em>,\u00a064<\/em>(2), 189-195.<\/p>\n<\/div>\n

2007<\/h3>\n
\nJirka S, McDonald AJ, Johnson MS, Feldpausch TR, Couto EG, Riha SJ\u00a0(2007).\u00a0Relationships between soil hydrology and forest structure and composition in the southern Brazilian Amazon<\/strong>.\u00a0Journal of Vegetation Science<\/em>,\u00a018<\/em>(2), 183-194.<\/p>\n<\/div>\n
\nFeldpausch TR, da Conceicao Prates-Clark C, Fernandes ECM, Riha SJ\u00a0(2007).\u00a0Secondary forest growth deviation from chronosequence predictions in central Amazonia<\/strong>.\u00a0Global Change Biology<\/em>,\u00a013<\/em>(5), 967-979.\u00a0\"Article<\/a><\/span><\/p>\n<\/div>\n

2006<\/h3>\n
\nFeldpausch TR, McDonald AJ, Passos CAM, Lehmann J, Riha SJ\u00a0(2006).\u00a0Biomass, harvestable area, and forest structure estimated from commercial timber inventories and remotely sensed imagery in southern Amazonia<\/strong>.\u00a0Forest Ecology and Management<\/em>,\u00a0233<\/em>(1), 121-132.<\/p>\n<\/div>\n
\ndos Santos UM, de Carvalho Gon\u00e7alves JF, Feldpausch TR\u00a0(2006).\u00a0Growth, leaf nutrient concentration and photosynthetic nutrient use efficiency in tropical tree species planted in degraded areas in central Amazonia<\/strong>.\u00a0Forest Ecology and Management<\/em>,\u00a0226<\/em>(1-3), 299-309.<\/p>\n<\/div>\n
\nSilva CEM, Gon\u00e7alves JFDC, Feldpausch TR, Luiz\u00e3o FJ, Morais RR, Ribeiro GO\u00a0(2006).\u00a0Nutrient use efficiency for pioneer species grown on abandoned pastures in central Amazonia<\/strong>.\u00a0Acta Amazonica<\/em>,\u00a036<\/em>(4), 503-512. \u00a0Full text<\/a>.<\/p>\n<\/div>\n

2005<\/h3>\n
\nFeldpausch TR, Riha SJ, Fernandes ECM, Wandelli EV\u00a0(2005).\u00a0Development of forest structure and leaf area in secondary forests regenerating on abandoned pastures in central Amaz\u00f4nia<\/strong>.\u00a0Earth Interactions<\/em>,\u00a09<\/em>(6). \u00a0Full text<\/a>.<\/p>\n<\/div>\n
\nZarin DJ, Davidson EA, Brondizio E, Vieira ICG, S\u00e1 T, Feldpausch T, Schuur EAG, Mesquita R, Moran E, Delamonica P, et al\u00a0(2005).\u00a0Legacy of fire slows carbon accumulation in Amazonian forest regrowth<\/strong>.\u00a0Frontiers in Ecology and the Environment<\/em>,\u00a03<\/em>(7), 365-369. \u00a0Full text<\/a>.<\/p>\n<\/div>\n
\nFeldpausch TR, Jirka S, Passos CAM, Jasper F, Riha SJ\u00a0(2005).\u00a0When big trees fall: Damage and carbon export by reduced impact logging in southern Amazonia<\/strong>.\u00a0Forest Ecology and Management<\/em>,\u00a0219<\/em>(2-3), 199-215.<\/p>\n<\/div>\n

2004<\/h3>\n
\nFeldpausch TR, Rondon MA, Fernandes ECM, Riha SJ, Wandelli E\u00a0(2004).\u00a0Carbon and nutrient accumulation in secondary forests regenerating on pastures in central Amazonia<\/strong>.\u00a0Ecological Applications<\/em>,\u00a014<\/em>(4 SUPPL.). \u00a0Full text<\/a>.<\/p>\n<\/div>\n
\nKeller M, Alencar A, Asner GP, Braswell B, Bustamante M, Davidson E, Feldpausch T, Fernandes E, Goulden M, Kabat P, et al\u00a0(2004).\u00a0Ecological research in the Large-scale Biosphere-Atmosphere Experiment in Amazonia: Early results<\/strong>.\u00a0Ecological Applications<\/em>,\u00a014<\/em>(4 SUPPL.). \u00a0Full text<\/a>.<\/p>\n<\/div>\n
<\/div>\n

Read more at:
\nhttp:\/\/geography.exeter.ac.uk\/staff\/index.php?web_id=Ted_Feldpausch&tab=research#publications<\/p>\n

Google scholar profile<\/a> | ORCID: 0000-0002-6631-7962<\/a> | Exeter Research Profile<\/a><\/p>\n<\/div>\n<\/div>\n<\/div>\n<\/div>\n","protected":false},"excerpt":{"rendered":"

Publications from the Feldpausch Research Group on tropical forest ecology, fire effects on carbon stocks, forest dynamics, and biodiversity in Amazonia and Africa.<\/p>\n","protected":false},"author":999,"featured_media":535,"parent":0,"menu_order":0,"comment_status":"closed","ping_status":"closed","template":"page-sidebar-boxed-feature-img.php","meta":{"_acf_changed":false,"footnotes":""},"categories":[],"tags":[],"acf":[],"yoast_head":"\nResearch Findings | Feldpausch Research Group | University of Exeter<\/title>\n<meta name=\"description\" content=\"Recent research findings from the Feldpausch Research Group on tropical forest carbon, fire ecology, pyrogenic carbon, soil dynamics, and biodiversity in A\" \/>\n<meta name=\"robots\" content=\"index, follow, max-snippet:-1, max-image-preview:large, max-video-preview:-1\" \/>\n<link rel=\"canonical\" href=\"https:\/\/sites.exeter.ac.uk\/ted-feldpausch\/research-findings\/\" \/>\n<meta property=\"og:locale\" content=\"en_US\" \/>\n<meta property=\"og:type\" content=\"article\" \/>\n<meta property=\"og:title\" content=\"Research Findings | Feldpausch Research Group | University of Exeter\" \/>\n<meta property=\"og:description\" content=\"Recent research findings from the Feldpausch Research Group on tropical forest carbon, fire ecology, pyrogenic carbon, soil dynamics, and biodiversity in A\" \/>\n<meta property=\"og:url\" content=\"https:\/\/sites.exeter.ac.uk\/ted-feldpausch\/research-findings\/\" \/>\n<meta property=\"og:site_name\" content=\"Prof. Ted Feldpausch\" \/>\n<meta property=\"article:modified_time\" content=\"2026-06-22T17:47:21+00:00\" \/>\n<meta property=\"og:image\" content=\"https:\/\/sites.exeter.ac.uk\/ted-feldpausch\/wp-content\/uploads\/sites\/257\/2019\/09\/DSC_3185_Feldpausch-1024x681.png\" \/>\n\t<meta property=\"og:image:width\" content=\"1024\" \/>\n\t<meta property=\"og:image:height\" content=\"681\" \/>\n\t<meta property=\"og:image:type\" content=\"image\/png\" \/>\n<meta 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