Aparecido, L. M. T.; Santos, J. d.; Higuchi, N.; Kunert, N.: Relevance of wood anatomy and size of Amazonian trees in the determination and allometry of sapwood area. Acta Amazonica 49 (1), pp. 1 - 10 (2019)
Muhr, J.; Trumbore, S. E.; Higuchi, N.; Kunert, N.: Living on borrowed time – Amazonian trees use decade‐old storage carbon to survive for months after complete stem girdling. New Phytologist 220 (1), pp. 111 - 120 (2018)
Kunert, N.; Aparecido, L. M. T.; Wolff, S.; Higuchi, N.; Santos, J. d.; de Araujo, A. C.; Trumbore, S. E.: A revised hydrological model for the Central Amazon: The importance of emergent canopy trees in the forest water budget. Agricultural and Forest Meteorology 239, pp. 47 - 57 (2017)
Hilman, B.; Muhr, J.; Trumbore, S. E.; Kunert, N.; Carbone, M. S.; Yuval, P.; Wright, S. J.; Moreno, G.; Pérez‑Priego, O.; Migliavacca, M.et al.; Carrara, A.; Grünzweig, J. M.; Osem, Y.; Weiner, T.; Angert, A.: Comparison of CO2 and O2 fluxes demonstrate retention of respired CO2 in tree stems from a range of tree species. Biogeosciences 16 (1), pp. 177 - 191 (2017)
Kunert, N.: Curios relationship revealed by looking at long term data sets—The geometry and allometric scaling of diel xylem sap flux in tropical trees. Journal of Plant Physiology 205, pp. 80 - 83 (2016)
Aparecido, L. M. T.; dos Santos, J.; Higuchi, N.; Kunert, N.: Ecological applications of differences in the hydraulic efficiency of palms and broad leaved trees. Trees 29, pp. 1431 - 1445 (2015)
Da Silva, F.; Suwa, R.; Kajimoto, T.; Ishizuka, M.; Higuchi, N.; Kunert, N.: Allometric equations for estimating biomass of Euterpe precatoria, the most abundant palm species in the Amazon. Forests 6 (2), pp. 450 - 463 (2015)
Kunert, N.; Aparecido, L. M. T.; Barros, P.; Higuchi, N.: Modeling potential impacts of planting palms or tree in small holder fruit plantations on ecohydrological processes in the Central Amazon. Forests 6 (8), pp. 2530 - 2544 (2015)
Kunert, N.; Aparecido, L. M. T.; dos Santos, J.; Higuchi, N.; Trumbore, S. E.: Higher tree transpiration due to road-associated edge effects in a tropical moist lowland forest. Agricultural and Forest Meteorology 213, pp. 183 - 192 (2015)
Schwendenmann, L.; Pendall, E.; Sanchez-Bragado, R.; Kunert, N.; Hölscher, D.: Tree water uptake in a tropical plantation varying in tree diversity: interspecific differences, seasonal shifts and complementarity. Ecohydrology 8 (1), pp. 1 - 12 (2015)
Trumbore, S. E.; Angert, A.; Kunert, N.; Muhr, J.; Chambers, J. Q.: What's the flux? Unraveling how CO2 fluxes from trees reflect underlying physiological processes. New Phytologist 197 (2), pp. 353 - 355 (2013)
Kunert, N.; Mercado Cardenas, A.: Effects of xylem water transport on CO2 efflux of woody tissue in a tropical tree, Amazonas State. Hoehnea 39 (1), pp. 139 - 144 (2012)
A new study shows a natural solution to mitigate the effects of climate change such as extreme weather events. Researchers found that a diverse plant community acts as a buffer against fluctuations in soil temperature. This buffer, in turn, can have a decisive influence on important ecosystem processes.
Storing carbon in the soil can help to mitigate climate change. Soil organic matter bound to minerals in particular can store carbon in the long term. A new study shows that the formation of mineral-associated organic matter depends primarily on the type of mineral, but is also influenced by land use and cultivation intensity.
The future of the Amazon rainforest and its influence on the global climate were the focus of the visit by Frank-Walter Steinmeier and Steffi Lemke to the ATTO in Brazil. The President and the Federal Minister for the Environment visited the German-Brazilian research station on January 2nd.
Dr. Henrik Hartmann, group leader at the MPI for Biogeochemistry, takes over the management of the newly founded Institute for Forest Conservation at the Julius Kühn Institute (JKI) in Quedlinburg. We are happy with him about his new area of responsibility and we will stay in touch.
As part of the German-Brazilian cooperation project Amazon Tall Tower Observatory (ATTO), international scientists are studying the Amazon rainforest and its interaction with the atmosphere and climate. The recent project workshop clearly confirmed that ATTO has developed into a research site with globally unique capabilities – despite the pandemic and challenging field conditions.