Ramirez, J. A.; Craven, D.; Herrera-Ramirez, D.; Posada, J. M.; Reu, B.; Sierra, C. A.; Hoch, G.; Handa, I. T.; Messier, C.: Non-structural carbohydrate concentrations in tree organs vary across biomes and leaf habits, but are independent of the fast-slow plant economic spectrum. Frontiers in Plant Science 15, 1375958 (2024)
Muñoz, E.; Chanca, I.; González-Sosa, M.; Sarquis, A.; Tangarife-Escobar, A.; Sierra, C.: On the importance of time in carbon sequestration in soils and climate change mitigation. Global Change Biology 30 (3), e17229 (2024)
Tangarife-Escobar, A.; Guggenberger, G.; Feng, X.; Dai, G.; Urbina-Malo, C.; Azizi-Rad, M.; Sierra, C. A.: Moisture and temperature effects on the radiocarbon signature of respired carbon dioxide to assess stability of soil carbon in the Tibetan Plateau. Biogeosciences 21 (5), pp. 1277 - 1299 (2024)
Estupinan-Suarez, L. M.; Mahecha, M. D.; Brenning, A.; Kraemer, G.; Poveda, G.; Reichstein, M.; Sierra, C.: Spatial patterns of vegetation activity related to ENSO in Northern South America. Journal of Geophysical Research: Biogeosciences 129 (1), e2022JG007344 (2024)
Sierra, C.; Ahrens, B.; Bolinder, M. A.; Braakhekke, M. C.; von Fromm, S. F.; Kätterer, T.; Luo, Z.; Parvin, N.; Wang, G.: Carbon sequestration in the subsoil and the time required to stabilize carbon for climate change mitigation. Global Change Biology 30 (1), e17153 (2024)
Munoz, E.; Chanca, I.; Sierra, C.: Increased atmospheric CO2 and the transit time of carbon in terrestrial ecosystems. Global Change Biology 29 (23), pp. 6441 - 6452 (2023)
Eglinton, T. I.; Graven, H. D.; Raymond, P. A.; Trumbore, S. E.; Aluwihare, L.; Bard, E.; Basu, S.; Friedlingstein, P.; Hammer, S.; Lester, J.et al.; Sanderman, J.; Schuur, E. A. G.; Sierra, C. A.; Synal, H.-A.; Turnbull, J. C.; Wacker, L.: Making the case for an International Decade of Radiocarbon. Philosophical Transactions of the Royal Society of London - Series A: Mathematical Physical and Engineering Sciences 381 (2261), 20230081 (2023)
Munoz, E.; Sierra, C. A.: Deterministic and stochastic components of atmospheric CO2 inside forest canopies and consequences for predicting carbon and water exchange. Agricultural and Forest Meteorology 341, 109624 (2023)
Stoner, S.; Trumbore, S. E.; González-Pérez, J. A.; Schrumpf, M.; Sierra, C. A.; Hoyt, A. M.; Chadwick, O.; Doetterl, S.: Relating mineral–organic matter stabilization mechanisms to carbon quality and age distributions using ramped thermal analysis. Philosophical Transactions of the Royal Society of London - Series A: Mathematical Physical and Engineering Sciences 381 (2261), 20230139 (2023)
Stoner, S.; Schrumpf, M.; Hoyt, A. M.; Sierra, C. A.; Doetterl, S.; Galy, V.; Trumbore, S. E.: How well does ramped thermal oxidation quantify the age distribution of soil carbon? Assessing thermal stability of physically and chemically fractionated soil organic matter. Biogeosciences 20 (15), pp. 3151 - 3163 (2023)
Sarquis, A.; Sierra, C. A.: Information content in time series of litter decomposition studies and the transit time of litter in arid lands. Biogeosciences 20 (9), pp. 1759 - 1771 (2023)
Giraldo, J. A.; Valle, J. I. d.; González-Caro, S.; David, D. A.; Taylor, T.; Tobón, C.; Sierra, C. A.: Tree growth periodicity in the ever-wet tropical forest of the Americas. Journal of Ecology 111 (4), pp. 889 - 902 (2023)
Sierra, C. A.; Quetin, G. R.; Metzler, H.; Mueller, M.: A decrease in the age of respired carbon from the terrestrial biosphere and increase in the asymmetry of its distribution. Philosophical Transactions of the Royal Society of London - Series A: Mathematical Physical and Engineering Sciences 381 (2261), 20220200 (2023)
Wells, J. M.; Crow, S. E.; Sierra, C.; Deenik, J. L.; Carlson, K. M.; Meki, M. N.; Kiniry, J.: Edaphic controls of soil organic carbon in tropical agricultural landscapes. Scientific Reports 12, 21574 (2022)
Europe is the fastest warming continent in the world. According to the European Environment Agency’s assessment, many of these risks have already reached critical levels and could become catastrophic without urgent and decisive action.
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.
Removing a tonne of CO2 from the air and thus undoing a tonne of emissions? Doesn't quite work, says a study. And provides four objections in view of Earth systems.
The new report by the Global Carbon Project shows: Fossil CO2 emissions will reach a record high in 2023. If emissions remain this high, the carbon budget that remains before reaching the 1.5°C limit will probably be used up in seven years. Although emissions from land use are decreasing slightly, they are still too high to be compensated by renewable forests and reforestation.
Global experts have unveiled the annual 10 New Insights in Climate Science report. The report equips policymakers with the latest and most pivotal climate science research from the previous 18 months, synthesised to help inform negotiations at COP28 and policy implementation through 2024 and beyond.
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.