@article {2450, title = {The Growth Stop Phenomenon Of Baobabs (Adansonia Spp.) Identified By Radiocarbon DatingAbstract}, journal = {Radiocarbon}, volume = {59504754164661}, year = {2017}, month = {Jan-04-2017}, pages = {435 - 448}, abstract = {The article reports the growth stop phenomenon, which was documented only for baobabs, i.e. for trees belonging to the Adansonia genus. The identification of growth stop was enabled by radiocarbon dating, which allows a complex investigation of samples collected from the trunk/stems of baobabs. In several cases, the outermost rings of baobabs, which were close to the bark, were found to be old, with ages of several hundreds of years, instead of being very young. Dating results of samples collected from six baobabs are presented. For multistemmed baobabs, the growth stop may occur only for one or several stems. We identified four factors that may induce the growth stop: (i) stress determined by severe climate conditions, (ii) old age, (iii) the need to keep a stable internal architecture, and (iv) the collapse of stems that survive this trauma. Baobabs and their stems affected by growth stop may survive for several centuries, by continuing to produce leaves, flowers, and fruits. This phenomenon was associated with the capacity of baobabs to store large amounts of water in their trunks/stems in the rainy season. This reservoir of water is used during the dry season and allows the trees to survive prolonged drought periods.}, keywords = {Age determination, AMS, growth stop, Radiocarbon dating, tropical trees}, issn = {0033-8222}, doi = {10.1017/RDC.2016.92}, url = {https://www.cambridge.org/core/product/identifier/S0033822216000928/type/journal_articlehttps://www.cambridge.org/core/services/aop-cambridge-core/content/view/S0033822216000928}, author = {Patrut, Adrian and Woodborne, Stephan and von Reden, Karl F and Hall, Grant and Patrut, Roxana T and Rakosy, Laszlo and Danthu, Pascal and Pock-Tsy, Jean-Michel Leong and Lowy, Daniel A and Margineanu, Dragos} } @article {549, title = {AMS radiocarbon dating of very large Grandidier{\textquoteright}s baobabs (Adansonia grandidieri)}, journal = {Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms}, volume = {361}, year = {2015}, note = {Cu2hzTimes Cited:2Cited References Count:20}, month = {Oct 15}, pages = {591-598}, abstract = {The article reports the AMS radiocarbon investigation of the two largest known Adansonia grandidieri specimens. The two baobabs, which are named Tsitakakoike and Pregnant baobab, are located in Southwestern Madagascar, near Andombiro. A third specimen from this area, the House baobab, was also investigated. According to measurements, Tsitakakoike is the biggest individual above ground level of all Adansonia species. The House baobab was selected for its exposed structure, which is identical to the closed ring-shaped structure with false cavities identified by us in large and old Adansonia digitata specimens. According to our research, Tsitakakoike and the Pregnant baobab have multi-stemmed cylindrical trunks which are mainly hollow; the two very large baobabs also possess a ring-shaped structure. The radiocarbon dates of the oldest wood samples collected from the large trunks were 1274 {\textpm} 20 bp for Tsitakakoike and 930 {\textpm} 20 bp for the Pregnant baobab. According to their original positions and to the architectures of the two A. grandidieri, the ages of Tsitakakoike and Pregnant baobab would be between 1300 and 1500 years. Therefore, A. grandidieri becomes the third Adansonia species with individuals that can live over 1000 years, according to accurate dating results.}, issn = {0168-583X}, doi = {10.1016/j.nimb.2015.04.044}, author = {Patrut, Adrian and von Reden, Karl F. and Danthu, Pascal and Leong Pock-Tsy, Jean-Michel and Rakosy, Laszlo and Patrut, Roxana T. and Lowy, Daniel A. and Margineanu, Dragos} } @article {89, title = {Old ages of two historical Romanian trees assessed by AMS radiocarbon dating}, journal = {Nuclear Instruments \& Methods in Physics Research Section B-Beam Interactions with Materials and Atoms}, volume = {294}, year = {2013}, note = {id: 2245; PT: J; CT: 12th International Conference on Accelerator Mass Spectrometry (AMS); CY: MAR 20-25, 2011; CL: Wellington, NEW ZEALAND; TC: 0; UT: WOS:000313234300119}, pages = {616-621}, abstract = {Two large Romanian poplars are considered to be associated with significant historical events of the past. In order to verify these claims, wood samples collected from the broken trunks of the two poplars were radiocarbon dated by AMS. The oldest radiocarbon dates were found to be 275 +/- 20 bp for the black poplar of Mocod and 316 +/- 22 bp for the gray poplar of Rafaila. These values correspond to calibrated ages of 365 +/- 10 and 465 +/- 25 years, respectively. The dating results indicate old ages for the two trees, i.e., 455 years for the Mocod poplar and 560 years for the Rafaila poplar. Such age values validate historical information on the two large Romanian trees. (C) 2012 Elsevier B.V. All rights reserved.}, issn = {0168-583X}, doi = {10.1016/j.nimb.2012.04.029}, author = {Patrut, Adrian and von Reden, Karl F. and Lowy, Daniel A. and Patrut, Roxana T. and Vaida, D. Lucian and Margineanu, Dragos} } @article { ISI:000294494900012, title = {Age determination of large live trees with inner cavities: radiocarbon dating of Platland tree, a giant African baobab}, journal = {ANNALS OF FOREST SCIENCE}, volume = {68}, number = {{5, SI}}, year = {2011}, month = {AUG}, pages = {993-1003}, type = {Article}, abstract = {Introduction For large trees without a continuous sequence of growth rings in their trunk, such as the African baobab (Adansonia digitata L.), the only accurate method for age determination is radiocarbon dating. As of today, this method was limited to dating samples collected from the remains of dead specimens. Methods Our research extends significantly the dating of such trees to large live specimens with inner cavities. The new approach is based on collecting samples from the cavities and their subsequent radiocarbon dating. Results The giant two-stemmed Platland tree, also known as Sunland baobab, was investigated by using this new approach. AMS radiocarbon dates of the oldest sample segments originating from the two inner cavities indicate that the large stem I (364.5 m(3)) is 750 +/- 75 years old, while the much smaller stem II (136.7 m(3)) has 1,060 +/- 75 years. Results also show that stem I is still growing very fast, while the older stem II slowed down consistently its growth over the past 250 years. The complete mapping of Platland tree determined an overall wood volume of 501.2 m(3). Conclusions Dating results demonstrate that the size-age relation cannot be used for estimating accurately the age of African baobabs.}, keywords = {Accelerator mass spectrometry, Adansonia digitata, Age determination, Growth rate, Radiocarbon dating}, issn = {1286-4560}, doi = {10.1007/s13595-011-0107-x}, author = {Patrut, Adrian and von Reden, Karl F. and Van Pelt, Robert and Mayne, Diana H. and Lowy, Daniel A. and Margineanu, Dragos} }