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与硅酸盐母质相比,碳酸盐上欧洲山毛榉林的土壤磷状况及磷营养策略。

Soil phosphorus status and P nutrition strategies of European beech forests on carbonate compared to silicate parent material.

作者信息

Prietzel Jörg, Krüger Jaane, Kaiser Klaus, Amelung Wulf, Bauke Sara L, Dippold Michaela A, Kandeler Ellen, Klysubun Wantana, Lewandowski Hans, Löppmann Sebastian, Luster Jörg, Marhan Sven, Puhlmann Heike, Schmitt Marius, Siegenthaler Maja B, Siemens Jan, Spielvogel Sandra, Willbold Sabine, Wolff Jan, Lang Friederike

机构信息

Chair of Soil Science, School of Life Sciences Weihenstephan, Technical University Munich, Emil-Ramann-Str. 2, 85354 Freising, Germany.

Professur für Bodenökologie, Albert-Ludwigs-Universität Freiburg, Bertoldstr. 17, 79085 Freiburg, Germany.

出版信息

Biogeochemistry. 2022;158(1):39-72. doi: 10.1007/s10533-021-00884-7. Epub 2022 Feb 2.

DOI:10.1007/s10533-021-00884-7
PMID:
35221401
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8860963/
Abstract

UNLABELLED

Sustainable forest management requires understanding of ecosystem phosphorus (P) cycling. Lang et al. (2017) [ https://doi.org/10.1007/s10533-017-0375-0] introduced the concept of P-acquiring P-recycling nutrition strategies for European beech () forests on silicate parent material, and demonstrated a change from P-acquiring to P-recycling nutrition from P-rich to P-poor sites. The present study extends this silicate rock-based assessment to forest sites with soils formed from carbonate bedrock. For all sites, it presents a large set of general soil and bedrock chemistry data. It thoroughly describes the soil P status and generates a comprehensive concept on forest ecosystem P nutrition covering the majority of Central European forest soils. For this purpose, an Ecosystem P Nutrition Index ( ) was developed, which enabled the comparison of forest P nutrition strategies at the carbonate sites in our study among each other and also with those of the silicate sites investigated by Lang et al. (2017). The P status of forest soils on carbonate substrates was characterized by low soil P stocks and a large fraction of organic Ca-bound P (probably largely Ca phytate) during early stages of pedogenesis. Soil P stocks, particularly those in the mineral soil and of inorganic P forms, including Al- and Fe-bound P, became more abundant with progressing pedogenesis and accumulation of carbonate rock dissolution residue. Phosphorus-rich impure, silicate-enriched carbonate bedrock promoted the accumulation of dissolution residue and supported larger soil P stocks, mainly bound to Fe and Al minerals. In carbonate-derived soils, only low P amounts were bioavailable during early stages of pedogenesis, and, similar to P-poor silicate sites, P nutrition of beech forests depended on tight (re)cycling of P bound in forest floor soil organic matter (SOM). In contrast to P-poor silicate sites, where the ecosystem P nutrition strategy is direct biotic recycling of SOM-bound organic P, recycling during early stages of pedogenesis on carbonate substrates also involves the dissolution of stable Ca-P precipitates formed from phosphate released during SOM decomposition. In contrast to silicate sites, progressing pedogenesis and accumulation of P-enriched carbonate bedrock dissolution residue at the carbonate sites promote again P-acquiring mechanisms for ecosystem P nutrition.

SUPPLEMENTARY INFORMATION

The online version contains supplementary material available at 10.1007/s10533-021-00884-7.

摘要

未标注

可持续森林管理需要了解生态系统磷(P)循环。Lang等人(2017年)[https://doi.org/10.1007/s10533-017-0375-0]引入了在硅酸盐母质上的欧洲山毛榉()森林获取磷和循环利用磷营养策略的概念,并证明了从富磷到贫磷地点从获取磷到循环利用磷营养的转变。本研究将这种基于硅酸盐岩石的评估扩展到由碳酸盐基岩形成土壤的森林地点。对于所有地点,它提供了大量一般土壤和基岩化学数据。它全面描述了土壤磷状况,并生成了一个涵盖中欧大部分森林土壤的森林生态系统磷营养综合概念。为此,开发了一个生态系统磷营养指数(),该指数能够比较我们研究中碳酸盐地点之间以及与Lang等人(2017年)研究的硅酸盐地点的森林磷营养策略。碳酸盐基质上森林土壤的磷状况在成土早期的特征是土壤磷储量低,且有机钙结合磷(可能主要是植酸钙)占很大比例。随着成土作用的进行和碳酸盐岩溶解残余物的积累,土壤磷储量,特别是矿质土壤中的磷储量以及包括铝和铁结合磷在内的无机磷形态变得更加丰富。富含磷的不纯、富含硅酸盐的碳酸盐基岩促进了溶解残余物的积累,并支持了更大的土壤磷储量,主要与铁和铝矿物结合。在碳酸盐衍生的土壤中,在成土早期只有少量磷具有生物有效性,并且与贫磷硅酸盐地点类似,山毛榉森林的磷营养依赖于林地土壤有机质(SOM)中结合磷的紧密(再)循环。与贫磷硅酸盐地点不同,在贫磷硅酸盐地点生态系统磷营养策略是SOM结合有机磷的直接生物循环,而在碳酸盐基质上成土早期的循环还涉及到SOM分解过程中释放的磷酸盐形成的稳定钙磷沉淀物的溶解。与硅酸盐地点不同,碳酸盐地点成土作用的进行和富含磷的碳酸盐基岩溶解残余物的积累再次促进了生态系统磷营养的获取磷机制。

补充信息

在线版本包含可在10.1007/s10533-021-00884-7获取的补充材料。

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