首页|期刊导航|北京林业大学学报|杉木人工林阔叶化改造对土壤团聚体酶活性与化学计量比的影响

杉木人工林阔叶化改造对土壤团聚体酶活性与化学计量比的影响OA

Effects of broad-leaved transformation of Chinese fir(Cunninghamia lanceolata)plantations on soil aggregate enzyme activities and stoichiometric ratios

中文摘要英文摘要

[目的]揭示杉木人工林阔叶化改造背景下不同粒径土壤团聚体对酶活性及计量比的影响机制,为提升我国亚热带人工林生产力和可持续经营提供科学支撑.[方法]以杉木纯林(CL)、米老排纯林(PM)、红锥纯林(PC)和米老排/红锥混交林(MP)为研究对象,分析 0~10 cm土层原土及不同粒径土壤团聚体的碳(C)、氮(N)和磷(P)循环相关酶活性、土壤理化性质及微生物生物量,解析杉木人工林转变为乡土阔叶林后的土壤酶活性及计量比变异的主要驱动因子.[结果](1)与CL 相比,PM、PC及 MP土壤有机碳(SOC)分别提高了 42.00%、85.25%和 136.53%;土壤 C∶P 分别显著增加了 30.80%、49.77%和 73.13%;微生物生物量氮(MBN)分别显著增加了 25.98%、32.88%和 54.18%;微生物生物量磷(MBP)分别显著增加了 12.99%、28.31%和 49.62%;土壤 C、N 和 P 循环相关酶活性在原土和不同粒径团聚体中均显著提高,其中在MP 的 0.25~1 mm和<0.25 mm中最高,且 MP的 C、N循环相关的土壤酶活性均显著高于其他林分.(2)土壤酶C∶N∶P 约为 1∶1.06∶1.15,偏离全球荟萃平均水平(1∶1∶1),表明土壤微生物获取 N、P 的酶活性高于 C的酶活性,且获取P 的酶活性高于 N 的酶活性.(3)酶矢量分析显示,CL受 P 限制(VA>45°),而 PM、PC和 MP 均受 N限制(VA<45°);各林分 VL 均大于 1,但改造后呈下降趋势,表明 C 限制随阔叶化改造而缓解.(4)SOC、全磷、土壤 N∶P、土壤 C∶P 及全氮是影响土壤酶活性变化的主要因子,而 SOC、土壤 C∶N和微生物生物量碳(MBC)是影响酶化学计量比的主要因子.[结论]阔叶树种(尤其混交林)可有效提升土壤酶活性、改善土壤养分循环和质量,但改造后的林分仍存在 N限制,建议适当增施氮肥或引入固氮树种优化养分供给,维持系统高生产力.

[Objective]This study aims to reveal the mechanism underlying the effects of soil aggregate size differentiation on enzyme activities and stoichiometric ratios under the background of broadleaved transformation of Chinese fir(Cunninghamia lanceolata)plantations.It provides scientific support for enhancing the productivity and sustainable management of subtropical plantations in China.[Method]Four stand types,including pure Chinese fir plantation(CL),pure Mytilaria laosensis plantation(PM),pure Castanopsis hystrix plantation(PC),and Mytilaria laosensis/Castanopsis hystrix mixed plantation(MP),were selected as research objects.Soil physicochemical properties,microbial biomass and activities of carbon(C),nitrogen(N)and phosphorus(P)cycling-related enzymes in bulk soil and different aggregate fractions at 0~10 cm soil layer were determined.The main driving factors for variations in soil enzyme activities and stoichiometric ratios after the conversion from Chinese fir plantations to native broadleaved forests were analyzed.[Result](1)Compared with CL,SOC in PM,PC and MP increased by 42.00%,85.25%and 136.53%,soil C∶P increased significantly by 30.80%,49.77%and 73.13%,MBN increased significantly by 25.98%,32.88%and 54.18%,and MBP increased significantly by 12.99%,28.31%and 49.62%,respectively.Activities of C-,N-,and P-cycling enzymes were significantly enhanced in bulk soil and all aggregate sizes,with the highest values in 0.25-1 mm and<0.25 mm fractions in MP.In particular,C-and N-cycling enzyme activities in MP were significantly higher than those in other stands.(2)The soil enzyme C∶N∶P was about 1∶1.06∶1.15,deviating from the global meta-analysis average of 1∶1∶1,indicating higher microbial enzyme activities for N and P acquisition than for C acquisition,and higher P-acquiring enzyme activity than N-acquiring enzyme activity.(3)Enzyme vector analysis showed that CL was P-limited(VA>45°),while PM,PC,and MP were N-limited(VA<45°).Vector length(VL)was greater than 1 in all stands but decreased after broadleaved transformation,indicating that C limitation was gradually alleviated.(4)SOC,total phosphorus,soil N∶P,soil C∶P and total nitrogen were the dominant factors affecting soil enzyme activities,while SOC,soil C∶N and MBC mainly controlled the variation of enzyme stoichiometric ratios.[Conclusion]Broad-leaved tree species(especially mixed forests)can effectively improve soil enzyme activities and promote soil nutrient cycling and quality.Nevertheless,N limitation still exists in the converted stands.Therefore,appropriate nitrogen application or introduction of nitrogen-fixing tree species is recommended to optimize nutrient supply and maintain high ecosystem productivity.

覃佳佳;侯丹阳;李佳君;黄海梅;黄麒霏;罗舟宇;王庆灵;黄雪蔓;尤业明

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农业科技

杉木人工林阔叶林改造土壤团聚体土壤酶活性酶化学计量比矢量分析可持续经营

Chinese fir plantationbroadleaved transformationsoil aggregatessoil enzyme activityenzyme stoichiometric ratiovector analysissustainable management

《北京林业大学学报》 2026 (5)

60-71,12

国家自然科学基金项目(32560339、32171755),广西自然科学基金项目(2025GXNSFAA069288),崇左凭祥友谊关森林生态系统广西野外科学观测研究站科研能力建设项目(桂科AD 25069098).

10.12171/j.1000-1522.20250380

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