中西伯利亚永久冻土层上原始落叶松森林Zn同位素分馏

IF 0.9 4区 地球科学 Q4 GEOCHEMISTRY & GEOPHYSICS Geochemical Transactions Pub Date : 2015-04-16 DOI:10.1186/s12932-015-0018-0
Jerome Viers, Anatoly S Prokushkin, Oleg S Pokrovsky, Alexander V Kirdyanov, Cyril Zouiten, Jerome Chmeleff, Merlin Meheut, Francois Chabaux, Priscia Oliva, Bernard Dupré
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引用次数: 36

摘要

在西伯利亚中部连续多年冻土玄武岩上发育的原始落叶松森林的主要生物地球化学区室中研究了稳定Zn同位素分馏。以植被生物量和活动层深度明显不同的两个南北向流域坡面作为预测该地区未来可能发生的气候变化的自然代理。此外,还研究了具有完全不同植被、水文和土壤温度的泥炭沼泽带。中西伯利亚土壤剖面的同位素组成比较稳定,δ66Zn值在0.2‰左右,与各种玄武岩的值接近。苔藓(Sphagnum fuscum和Pleurozium schreberi)的锌同位素组成在表层之间存在差异,其值为0.14 ~ 0.2‰,而底层的锌同位素组成值显著高于下垫矿物表面(0.5 ~ 0.7‰)。枯死苔藓和落叶松针叶的腐殖化导致Zn结合最强烈的部分被保留,从而在溶液中释放出较轻的同位素,而在腐殖化产物中保留了重同位素,这与先前的实验和建模工作基本一致[GCA 75:7632-7643, 2011]。南北向斜坡落叶松(Larix gmelinii)与土壤储层相比富集重同位素,而泥炭沼泽落叶松则富集轻同位素。这种差异可能是由于泥炭沼泽中有机配体和腐殖化产物对锌的络合作用强于朝北和朝南斜坡的矿物表面。在生育期,锌遵循常量营养元素的变化规律,6 ~ 9月锌浓度呈下降趋势。在此期间,在不同的生境中观察到较重的Zn同位素对落叶松针叶的富集。我们认为,随着土壤逐渐融化,生根区深度的增加,根系吸收区土壤溶液中DOC和Zn浓度的降低,会促使落叶松根系在营养季结束时比在营养季开始时更有效地吸收重同位素,因为DOC的减少会促进重同位素的吸收,而重同位素在强有机络合物中的保留量会减少。
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Zn isotope fractionation in a pristine larch forest on permafrost-dominated soils in Central Siberia

Stable Zn isotopes fractionation was studied in main biogeochemical compartments of a pristine larch forest of Central Siberia developed over continuous permafrost basalt rocks. Two north- and south-oriented watershed slopes having distinctly different vegetation biomass and active layer depth were used as natural proxy for predicting possible future climate changes occurring in this region. In addition, peat bog zone exhibiting totally different vegetation, hydrology and soil temperature regime has been studied.

The isotopic composition of soil profile from Central Siberia is rather constant with a δ66Zn value around 0.2‰ close to the value of various basalts. Zn isotopic composition in mosses (Sphagnum fuscum and Pleurozium schreberi) exhibits differences between surface layers presenting values from 0.14 to 0.2‰ and bottom layers presenting significantly higher values (0.5 – 0.7‰) than the underlain mineral surface. The humification of both dead moss and larch needles leads to retain the fraction where Zn bound most strongly thus releasing the lighter isotopes in solution and preserving the heavy isotopes in the humification products, in general accord with previous experimental and modeling works [GCA 75:7632–7643, 2011].

The larch (Larix gmelinii) from North and South-facing slopes is enriched in heavy isotopes compared to soil reservoir while larch from Sphagnum peatbog is enriched in light isotopes. This difference may result from stronger complexation of Zn by organic ligands and humification products in the peat bog compared to mineral surfaces in North- and South-facing slope.

During the course of the growing period, Zn followed the behavior of macronutrients with a decrease of concentration from June to September. During this period, an enrichment of larch needles by heavier Zn isotopes is observed in the various habitats. We suggest that the increase of the depth of rooting zone, and the decrease of DOC and Zn concentration in soil solution from the root uptake zone with progressively thawing soil could provoke heavy isotopes to become more available for the larch roots at the end of the vegetative season compared to the beginning of the season, because the decrease of DOC will facilitate the uptake of heavy isotope as it will be less retained in strong organic complexes.

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来源期刊
Geochemical Transactions
Geochemical Transactions 地学-地球化学与地球物理
CiteScore
3.70
自引率
4.30%
发文量
2
审稿时长
>12 weeks
期刊介绍: Geochemical Transactions publishes high-quality research in all areas of chemistry as it relates to materials and processes occurring in terrestrial and extraterrestrial systems.
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