Literatura académica sobre el tema "Drought-Induced tree mortality"
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Artículos de revistas sobre el tema "Drought-Induced tree mortality"
Shenkin, Alexander, Benjamin Bolker, Marielos Peña-Claros, Juan Carlos Licona, Nataly Ascarrunz y Francis E. Putz. "Interactive effects of tree size, crown exposure and logging on drought-induced mortality". Philosophical Transactions of the Royal Society B: Biological Sciences 373, n.º 1760 (8 de octubre de 2018): 20180189. http://dx.doi.org/10.1098/rstb.2018.0189.
Texto completoArend, Matthias, Roman M. Link, Rachel Patthey, Günter Hoch, Bernhard Schuldt y Ansgar Kahmen. "Rapid hydraulic collapse as cause of drought-induced mortality in conifers". Proceedings of the National Academy of Sciences 118, n.º 16 (12 de abril de 2021): e2025251118. http://dx.doi.org/10.1073/pnas.2025251118.
Texto completoWang, Weifeng, Changhui Peng, Daniel D. Kneeshaw, Guy R. Larocque y Zhibin Luo. "Drought-induced tree mortality: ecological consequences, causes, and modeling". Environmental Reviews 20, n.º 2 (junio de 2012): 109–21. http://dx.doi.org/10.1139/a2012-004.
Texto completoHajek, Peter, Roman M. Link, Charles A. Nock, Jürgen Bauhus, Tobias Gebauer, Arthur Gessler, Kyle Kovach et al. "Mutually inclusive mechanisms of drought‐induced tree mortality". Global Change Biology 28, n.º 10 (17 de marzo de 2022): 3365–78. http://dx.doi.org/10.1111/gcb.16146.
Texto completoAnderegg, William R. L., Alan Flint, Cho-ying Huang, Lorraine Flint, Joseph A. Berry, Frank W. Davis, John S. Sperry y Christopher B. Field. "Tree mortality predicted from drought-induced vascular damage". Nature Geoscience 8, n.º 5 (30 de marzo de 2015): 367–71. http://dx.doi.org/10.1038/ngeo2400.
Texto completoZheng, Wuji, Xiaohua Gou, Jiajia Su, Haowen Fan, Ailing Yu, Wenhuo Liu, Yang Deng, Rubén D. Manzanedo y Patrick Fonti. "Physiological and Growth Responses to Increasing Drought of an Endangered Tree Species in Southwest China". Forests 10, n.º 6 (17 de junio de 2019): 514. http://dx.doi.org/10.3390/f10060514.
Texto completoHillabrand, Rachel M., Uwe G. Hacke y Victor J. Lieffers. "Defoliation constrains xylem and phloem functionality". Tree Physiology 39, n.º 7 (17 de mayo de 2019): 1099–108. http://dx.doi.org/10.1093/treephys/tpz029.
Texto completoMacAllister, Sarah, Maurizio Mencuccini, Ulf Sommer, Jasper Engel, Andrew Hudson, Yann Salmon y Kyle G. Dexter. "Drought-induced mortality in Scots pine: opening the metabolic black box". Tree Physiology 39, n.º 8 (21 de junio de 2019): 1358–70. http://dx.doi.org/10.1093/treephys/tpz049.
Texto completoSun, Shoujia, Lanfen Qiu, Chunxia He, Chunyou Li, Jinsong Zhang y Ping Meng. "Drought-Affected Populus simonii Carr. Show Lower Growth and Long-Term Increases in Intrinsic Water-Use Efficiency Prior to Tree Mortality". Forests 9, n.º 9 (13 de septiembre de 2018): 564. http://dx.doi.org/10.3390/f9090564.
Texto completoKlein, T. "Drought-induced tree mortality: from discrete observations to comprehensive research". Tree Physiology 35, n.º 3 (1 de marzo de 2015): 225–28. http://dx.doi.org/10.1093/treephys/tpv029.
Texto completoTesis sobre el tema "Drought-Induced tree mortality"
Adams, Henry. "Temperature Sensitivity, Physiological Mechanism, and Implications of Drought-Induced Tree Mortality". Diss., The University of Arizona, 2012. http://hdl.handle.net/10150/228494.
Texto completoGarcia, Forner Núria. "Understanding the mechanisms of drought-induced mortality in trees". Doctoral thesis, Universitat Autònoma de Barcelona, 2016. http://hdl.handle.net/10803/381267.
Texto completoPlants are exposed to several environmental stressors including drought and extreme temperatures that can limit their growth and survival. Water availability is considered the main limiting factor for plant productivity. Plants display a plethora of strategies to cope with drought and maintain an adequate water balance, including modifications of the leaf area, stomatal control, changes in biomass allocation, modifications of source/sink carbon balance, and resistance to xylem embolism. Despite this, drought-induced forest mortality is a widespread phenomenon with potentially large ecosystem-level implications and is expected to increase due to increasing drought events as a result of ongoing climate change. Understanding how the complex network of traits involved in drought resistance determine species’ or individuals’ to survive drought is critical to assess the vulnerability of current vegetation to changes in climate and the potential impacts on ecosystem functioning and services. In 2008, McDowell et al. summarized drought-induced mortality mechanisms in a coherent and simple hydraulic framework. They hypothesized two main, non-exclusive physiological mechanisms leading to plant death under drought: hydraulic failure and carbon starvation. Hydraulic failure is the point at which whole-plant water transport becomes blocked due to excessive cavitation resulting from critical tensions in the xylem. Carbon starvation is the situation in which carbon supply from photosynthesis, carbon stocks or autophagy fails to meet the minimum metabolic needs. According to this framework, the preponderance of one or the other mechanism depends on the drought intensity and duration and plants' ability to regulate their water potential (Ψw). Isohydric species might be more vulnerable to carbon starvation due to earlier stomatal closure to maintain relatively constant Ψw (and avoid embolism), while anisohydric species would be more susceptible to hydraulic failure as soil dries as they operate with narrow hydraulic safety margins due to their lower Ψw. The previous framework is centered on stomatal behavior, regardless of the plethora of traits involved in plant drought responses. In addition, stomata respond to several factors besides Ψw, hence assuming that iso/anisohydric regulation of Ψw is able to fully explain stomatal behavior may be misleading. For these reasons, the main objectives in this thesis were to: (1) determine if differences in stomatal regulation between species relate to iso/anisohydric behaviors and how these are associated to different mortality mechanisms under drought, warming or both; (2) test the assumptions that relate anisohydric behaviors with higher stomatal conductances and longer periods of carbon uptake under drought, and isohydric behaviors with stronger stomatal control and wider hydraulic safety margins; and (3) understand how morphological and physiological traits and their plasticity in response to drought explain, and to what extent, time until death within species. To address targets (1) and (2) we studied two reference models with contrasted drought-vulnerability between species: piñon-juniper and holm oak systems. In both cases, we compared drought responses between isohydric (Pinus edulis and Quercus ilex) and anisohydric species (Juniperus mosperma and Phillyrea latifolia), emphasizing stomatal regulation and carbon and water economies. In these species, we provided evidence that more anisohydric behavior is not necessarily related with looser stomatal responses to Ψw and, thus, with higher levels of xylem embolism. Likewise, stronger regulation of Ψw (isohydric behavior) was neither associated with earlier stomatal closure under drought nor with higher carbon constrains. Both studies challenge widespread notions and warn against linking iso/anisohydry with contrasted stomatal behaviors and mortality mechanisms. At the tree level (3), sustaining carbon uptake and carbon stocks above some critical level was the key factor prolonging survival under extreme drought, even at expenses of higher water losses. Fully integrating carbon and water economies is the key challenge to advance our understanding of drought responses and mortality mechanisms in plants.
Yao, Yitong. "Impacts of drought on biomass and carbon fluxes in the Amazon rainforest : a modeling approach". Electronic Thesis or Diss., université Paris-Saclay, 2022. http://www.theses.fr/2022UPASJ010.
Texto completoDroughts have recurrently impacted the Amazon rainforests, undermining the forest biomass carbon sink capacity due to a quicker increase of biomass mortality compared to growth. Most global land surface models used for assessments of the Global Carbon Budget and future climate projections have not incorporated drought-induced tree mortality. Their prediction of biomass dynamics are therefore subject to large uncertainties, as a result of (1) lack of explicit simulation of hydraulic transportin the continuum from soil to leaves; (2) lack of process-based equations connecting the impairment of the hydraulic transport system of trees to mortality; (3) lack of representation of mortality across trees sizes. To address these critical research gaps, I improved plant hydraulic representation in ORCHIDEECAN. This model was re-calibrated and evaluated over rainforests in Amazon basin, and applied to simulate the future evolution of biomass dynamics facing droughts. Firstly, I implemented a mechanistic hydraulic architecture that was designed by E. Joetzjer, and a hydraulic-failure related tree mortality module that I designed into ORCHIDEE-CAN. The model was calibrated against the world’s longest running drought manipulation experiment of Caxiuana in the eastern Amazon. Our model produced comparable annual tree mortality rates than the observation andcaptured biomass dynamics. This work provides a basis for further research in assimilating experimental observation data to parameterize the hydraulic failure induced tree mortality. Secondly, I applied ORCHIDEE-CAN-NHA over the Amazon intact rainforest. The model reproduced the drought sensitivity of aboveground biomass (AGB) growth and mortality observed atnetworks of forest inventory plots across Amazon intact forests for the two recent mega-droughts of 2005 and 2010. We predicted a more negative sensitivity of the net biomass carbon sink to water deficits for the recent 2015/16 El Nino, which was the most severe drought in the historical record. In the model, even if climate change with droughts becoming more severe tended to intensify tree mortality, increased CO2 concentration contributed to attenuate the C loss due to mortality by suppressing transpiration.Lastly, I used the ORCHIDEE-CAN-NHA model for future simulations of biomass carbondynamics. Most climate models (ISIMIP2 program) consistently predict a drier trend in northeastern Amazon. The simulation forced by the HadGEM climate model in the RCP8.5 scenario shows the most pronounced drying in eastern and northeastern Amazon, with a cross-over point at which the carbon sink turned to a carbon source in the Guiana Shield and East-central Amazon in the middle of the 21st century. This study sheds light on predicting the future evolution of Amazon rainforest biomass dynamics with an improved process-based model able to reproduce climate-change induced mortality.In the conclusion and outlook sections, future developments and research priorities are proposed, which would improve the reliability and performances of the process-based model presented in this dissertation, allowing to better capture mechanisms that control the evolution of forest biomass dynamics in the face of more frequent drought risks
Duan, Honglang. "How will the main and interactive effects of elevated [CO2] and elevated temperature affect tree response to drought and drought-induced tree mortality?" Thesis, 2014. http://handle.uws.edu.au:8081/1959.7/546094.
Texto completoForner, Nuria Garcia. "Understanding the mechanisms of drought-induced mortality in trees". Doctoral thesis, 2018. http://hdl.handle.net/10316/47859.
Texto completoCapítulos de libros sobre el tema "Drought-Induced tree mortality"
Hurteau, Matthew D., Marissa G. Goodwin, Harold S. J. Zald y Malcolm P. North. "Increasing potential wildfire energy flux from climate-driven mortality and fuel aridity". En Advances in Forest Fire Research 2022, 1153–56. Imprensa da Universidade de Coimbra, 2022. http://dx.doi.org/10.14195/978-989-26-2298-9_175.
Texto completoInformes sobre el tema "Drought-Induced tree mortality"
Lawrence, David, Mike Tercek, Amber Runyon y Jeneva Wright. Historical and projected climate change for Grand Canyon National Park and surrounding areas. National Park Service, 2024. http://dx.doi.org/10.36967/2301726.
Texto completo