Seasonally resolved stable isotope chronologies from northern Thailand deciduous trees

Poussart, P. F.; Schrag, Daniel P.

doi:10.1016/j.epsl.2005.05.012

Cited by 73 publications

(84 citation statements)

References 32 publications

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“…The relative humidity is ~90 % during the rainy season (generally, December-May) and drops by only 5-10 % during the moderate dry season (which lasts for about 3 months, around August). The reduction in relative humidity causes a reduction in the stomatal conductance of trees (Mooney et al 1983;Roberts et al 1990), increasing the δ 18 O of leaf water (Barbour 2007 and in seasonally dry forests in Thailand and Indonesia (Poussart et al 2004;Poussart and Schrag 2005). A similar relationship was also reported for a fast-growing species (Tachigali myrmecophila) in Amazonian terra firme forest near Manaus (Ballantyne et al 2011).…”

supporting

confidence: 52%

“…In addition, some ring boundaries seemed to have formed at the beginning of the moderate dry season, because many boundaries appeared with the sharp increase in δ 18 O wc variations. Similarly, the δ 18 O wc analysis suggested that the ring boundary formed at the end of the peak of the wet season for one species of deciduous dipterocarp tree in Thailand (Poussart et al 2005). Even in our limited study of three species, it was unclear how ring boundary formation was associated with the stable isotopic ring patterns.…”

Section: Efficacy Of Each Annual-ring Indicatormentioning

confidence: 92%

“…The small range in the δ 13 C wc cyclic variation found for all examined species indicates that these trees do not experience serious drought stress or may not change their photosynthetic rate to a large extent throughout the year in the study regions. Much larger seasonal δ 13 C wc variations were reported for trees growing in seasonally dry forests in the tropics of Southeast Asia (Poussart et al 2004;Poussart and Schrag 2005;Ohashi et al 2009). However, the distinct δ 13 C wc peaks that coincided fairly well with the δ 18 O ring boundary in EC trees (e.g., Fig.…”

Section: Efficacy Of Each Annual-ring Indicatormentioning

confidence: 99%

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Seasonal variations in the stable oxygen isotope ratio of wood cellulose reveal annual rings of trees in a Central Amazon terra firme forest

et al. 2015

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in Manaus. However, the δ 18 O wc patterns of E. coriacea differed by region. The ages of some samples estimated from the δ 18O wc cycles were offset from the ages estimated by 14 C dating. In the case of E. coriacea, this phenomenon suggested that missing or wedging rings may occur frequently even in well-grown individuals. Successful cross-dating may be facilitated by establishing δ 18 O wc master chronologies at both seasonal and inter-annual scales for tree species with distinct annual rings in each region.

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supporting

confidence: 52%

Section: Efficacy Of Each Annual-ring Indicatormentioning

confidence: 92%

Section: Efficacy Of Each Annual-ring Indicatormentioning

confidence: 99%

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Seasonal variations in the stable oxygen isotope ratio of wood cellulose reveal annual rings of trees in a Central Amazon terra firme forest

et al. 2015

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“…Such seasonal cycles of precipitation δ 18 O and relative humidity may generate seasonal cycles of tree ring cellulose δ 18 O, which can be used to identify annual growth (Anchukaitis et al, 2008;Anchukaitis and Evans, 2010;Evans and Schrag, 2004;Poussart and Schrag, 2005). To date, however, no such study has been performed in northern Southeast Asia.…”

mentioning

confidence: 99%

Oxygen isotopes as a valuable tool for measuring annual growth in tropical trees that lack distinct annual rings

Xu¹,

Sano²,

Yoshimura³

et al. 2014

Geochem. J.

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Some trees from tropical areas lack visually detectable and consistent annual growth rings. As such, we have measured the radial variation of cellulose oxygen isotopes in trees that grow in seasonally dry forests of Northern Laos to explore the possibility if this method can be used for the identification of annual rings. One disk from a 7-year-old Styrax tonkinensis (S. tonkinensis) in plantation and two cores from two Ficus semicordata var. semicordata (F. semicordata) in forests were examined. High-resolution cellulose oxygen isotopes of S. tonkinensis and F. semicordata show clear cycles with amplitudes of 5‰ and 9‰, respectively. To further test if the oxygen isotope cycles that we observed are annual or not, a tree ring cellulose oxygen isotope model is employed. Input data of the model are relative humidity and modeled precipitation δ 18 O. The modeling results independently support our detection of oxygen isotope annual cycles. Therefore, we conclude that tree ring cellulose oxygen isotopes have great potential to identify annual rings in tropical trees, which typically lack distinct annual rings in the context of seasonal climate.Keywords: tropical tree with non-distinct annual rings, cellulose oxygen isotopes, fractionation model, Styrax tonkinensis, Ficus semicordata var. semicordata INTRODUCTIONTropical forests contain roughly 25% of the carbon in the terrestrial biosphere, therefore, research on the responses of tropical forests to global change is critical in predicting future global carbon cycling (Bonan, 2008). To date, such research has primarily been focused at the leaf and community level, and studies on long-term changes at the individual tree and population levels are needed (Zuidema et al., 2013). However, tropical trees often fail to develop reliable annual rings, because many species lack visible tree rings or have only indistinct ring patterns. As such, it is difficult to estimate the age and growth rate of tropical trees. This information is essential for understanding the forest development process and forest response to global change, and is also useful for reconstructing past climate. Therefore, developing a method for estimating the annual growth pattern of such trees with non-distinct rings is important. Dendrometer can measure the radial growth rate of tropical trees by continuous measurements of diameter growth (da Silva et al., 2002;Ohashi et al., 2005). However, the dendrometer method cannot provide tree's growth rate 372 C. Xu et al. TREE RING CELLULOSE OXYGEN ISOTOPE MODELDuring the process of taking soil water by tree roots there is no isotopic fractionation (White et al., 1985). The xylem water is then transported to the leaves, where leaf water is subject to evaporation that results in isotopic enrichment, which is controlled by the relative humidity of the ambient environment (Barbour et al., 2004;Roden et al., 2000). This process is described by the equation of Craig and Gordon (1965):where the subscripts l, s, x, and a refer to leaf water, source water, xylem water and ...

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“…In addition, the application of bomb 14 C in various other research disciplines has grown significantly in the last 2 decades. In particular, atmospheric bomb 14 C has been used in forensic studies (Wild et al 1998;Zoppi et al 2004;Nakamura et al 2007;Buchholz and Spalding 2010;Alkass et al 2011;Ubelaker and Parra 2011;Ehleringer et al 2012), in biomedical research (Spalding et al 2005(Spalding et al , 2008Bhardwaj et al 2006;Lynnerup et al 2008), and in soil carbon studies (Quideau et al 2000;Bruun et al 2005;Koarashi et al 2009;Trumbore 2009;Rabbi et al 2013), to build reliable chronologies for recent terrestrial archives and materials (Hua 2009;English et al 2010;Hodge et al 2011;Clarke et al 2012;Hua et al 2012a), to validate tree-ring ages (Fichtler et al 2003;Vieira et al 2005;Bowman et al 2011;Pearson et al 2011), to date recent trees having no annual growth rings (Worbes and Junk 1989;Poussart and Schrag 2005;Lovelock et al 2010), and to determine biogenic and fossil fractions of industrial CO 2 emissions (Mohn et al 2008(Mohn et al , 2012Felner and Rechberger 2009;Palstra and Meijer 2010). This paper presents a new compilation of tropospheric 14 CO 2 (or tropospheric 14 C in short) for the last 60 yr , covering a short interval before the onset of bomb 14 C in the mid-1950s, the bomb-peak period during the 1960s, and the post-bomb era up to very recent time.…”

Section: Introductionmentioning

confidence: 99%

Atmospheric Radiocarbon for the Period 1950–2010

Hua

Barbetti

Rakowski³

2013

Radiocarbon

889

808

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ABSTRACT. We present a compilation of tropospheric 14 CO 2 for the period 1950-2010, based on published radiocarbon data from selected records of atmospheric CO 2 sampling and tree-ring series. This compilation is a new version of the compilation by and consists of yearly summer data sets for zonal, hemispheric, and global levels of atmospheric 14 C. In addition, compiled (and extended) monthly data sets for 5 atmospheric zones (3 in the Northern Hemisphere and 2 in the Southern Hemisphere) are reported. The annual data sets are for use in regional and global carbon model calculations, while the extended monthly data sets serve as calibration curves for 14 C dating of recent, short-lived terrestrial organic materials.

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Seasonally resolved stable isotope chronologies from northern Thailand deciduous trees

Cited by 73 publications

References 32 publications

Seasonal variations in the stable oxygen isotope ratio of wood cellulose reveal annual rings of trees in a Central Amazon terra firme forest

Seasonal variations in the stable oxygen isotope ratio of wood cellulose reveal annual rings of trees in a Central Amazon terra firme forest

Oxygen isotopes as a valuable tool for measuring annual growth in tropical trees that lack distinct annual rings

Atmospheric Radiocarbon for the Period 1950–2010

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