麻栎纯林及混交林土壤团聚体磷组分特征及其影响因素

doi:10.13287/j.1001-9332.202508.016

摘要/Abstract

摘要： 明晰麻栎纯林及混交林不同粒径土壤团聚体中磷组分特征,可为北亚热带区域土壤磷的有效性研究提供科学依据。本研究以南京市溧水区林场的麻栎纯林及麻栎马尾松混交林为对象,测定了0～20和20～40 cm两个土层团聚体的稳定性、各粒径团聚体的磷组分含量和酸性磷酸酶活性,以及凋落物和细根的生物量,解析不同林分类型下环境因素对土壤团聚体活性磷组分的影响。结果表明: 2种林分类型不同土层中的大团聚体(粒径>2 mm)含量均高于其他粒径,混交林中大团聚体占比为48.4%,纯林为43.7%。在0～20 cm土层中,混交林的团聚体稳定性均显著高于纯林。2种林分的团聚体全磷含量在0～20 cm土层为181.82～273.34 mg·kg^-1,林分间无显著差异;在20～40 cm土层为172.51～251.49 mg·kg^-1,混交林>2 mm粒径团聚体的全磷含量显著高于纯林。两种林分团聚体活性磷含量在0～20 cm土层为18.29～33.10 mg·kg^-1,林分间无显著差异;在20～40 cm土层为11.78～25.22 mg·kg^-1,混交林各粒径团聚体该含量均显著高于纯林。不同土层中,混交林各粒径团聚体的酸性磷酸酶活性均显著高于纯林,混交林在不同土层的细根生物量均显著高于纯林,凋落物生物量在林分之间无显著差异。广义线性混合模型分析表明,在0～20 cm土层,土壤pH、团聚体酸性磷酸酶和林分类型对团聚体活性磷含量的影响达显著水平,相对贡献度分别为32.0%、15.7%和9.0%;在20～40 cm土层,林分类型、团聚体酸性磷酸酶、细根生物量和凋落物生物量对团聚体活性磷含量的影响均达显著水平,相对贡献度分别为22.0%、16.5%、16.2%和10.6%。相比于纯林,混交林通过影响多种环境因素提升了土壤活性磷含量。

关键词: 林分类型, 土壤团聚体, 土壤磷组分, 细根生物量, 凋落物生物量

Abstract: Phosphorus components in the soil aggregates of different particle sizes is critical for improving phosphorus availability in north subtropical regions. We investigated two representative stand types, pure Q. acutissima stands and the mixed stands of Q. acutissima and Pinus massoniana in Lishui District, Nanjing. We measured soil aggregates from two soil layers (0-20 cm and 20-40 cm) to determine the stability of soil aggregates, labile phosphorus fraction content and the acid phosphatase activity of each particle size, as well as litter biomass and fine root biomass, to analyze the differences of active phosphorus fractions of soil aggregates between different stand types. The results showed that the content of macroaggregates (>2 mm) was higher than those of other particle sizes in different soil layers of both stand types. The proportion of macroaggregates was 48.4% in mixed stands and 43.7% in pure stands. In the 0-20 cm soil layer, the stability of soil aggregates was significantly greater in mixed stands than in pure stands. In the 0-20 cm soil layer, the total phosphorus (TP) content in aggregates of both stands ranged from 181.82 to 273.34 mg·kg^-1, without significant difference between the two stands, while that in the 20-40 cm layer ranged from 172.51 to 251.49 mg·kg^-1, with the mixed stands exhibiting significantly higher TP in macro-aggregates (>2 mm) than the pure stands. In the 0-20 cm soil layer, available phosphorus (AP) content in aggregates ranged from 18.29 to 33.10 mg·kg^-1, without difference between the two stands, while that in the 20-40 cm layer ranged from 11.78 to 25.22 mg·kg^-1, with the mixed stands having higher AP across all aggregate particle sizes than the pure stands. Acid phosphatase activity in mixed stands was significantly higher than in pure stands across all soil aggregate sizes and depth layers. Fine root biomass in the mixed stands was significantly greater than in the pure stands in both soil layers. In contrast, litter biomass did not differ between stands. Generalized linear mixed models revealed that soil pH, acid phosphatase activity of soil aggregates, and stand types exerted significant effects on labile phosphorus content of soil aggregates in the 0-20 cm soil layer, explaining 32.0%, 15.7%, and 9.0% of the variance, respectively. In the 20-40 cm layer, stand type, acid phosphatase activity of soil aggregates, fine root biomass, and litter biomass all showed significant influences, accounting for 22.0%, 16.5%, 16.2%, and 10.6% of the variance. Compared to pure stands, mixed stands enhanced soil labile phosphorus content by influencing multiple environmental factors.

Key words: stand type, soil aggregate, soil phosphorus fraction, fine root biomass, litter biomass

刘大源, 孟董悦, 于晨一, 李俊杰, 关庆伟. 麻栎纯林及混交林土壤团聚体磷组分特征及其影响因素[J]. 应用生态学报, 2025, 36(8): 2344-2352.

LIU Dayuan, MENG Dongyue, YU Chenyi, LI Junjie, GUAN Qingwei. Phosphorus fraction characteristics and influencing factors of soil aggregates in Quercus acutissima pure and mixed forests[J]. Chinese Journal of Applied Ecology, 2025, 36(8): 2344-2352.

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