亚热带地区阔叶林与杉木林土壤活性有机质比较

通过对亚热带3个地区地带性阔叶林和杉木林土壤活性有机质的比较,分析森林类型变化及杉木连栽对土壤有机碳和养分含量的影响.结果表明：地带性阔叶林转变为杉木林后,土壤总有机碳含量下降27.8%～52.1%、腐殖酸碳下降32.2%～52.8%、胡敏酸下降36.4%～59.0%、富里酸下降29.7%～50.0%;杉木连栽也使土壤总有机碳和腐殖质含量下降.森林类型改变和杉木连栽对土壤活性有机质的影响更明显.杉木林取代阔叶林后,土壤微生物生物量碳、微生物生物量氮、可溶性有机碳和可溶性有机氮含量的最大降幅分别为61.8%、38.2%、43.3%和69.0%;与第1代杉木林相比,第2代杉木林土壤微生物生物量碳、微生物生物量氮、可溶性有机碳和可溶性有机氮含量的最大降幅分别为34.7%、29.3%、30.4%、18.4%.经相关性分析,除冷水浸提有机氮外,土壤活性有机质与养分含量之间具有密切的相关关系.     

黄土高原区不同植物凋落物搭配对土壤微生物量碳、氮的影响

黄土高原丘陵沟壑区进行的以退耕还林还草为主的生态建设,使得进入土壤生态系统有机物的种类和数量发生变化,不同种类凋落物混合对土壤微生物量碳、氮的影响是值得关注的问题。本文采用室内培养试验方法研究了采自黄土高原地区6种不同植物凋落物及等比例混合后对土壤微生物量碳、氮及矿质态氮含量的影响。结果表明,加入不同植物凋落物均显著提高了培养期间土壤微生物量碳、氮含量。总体平均,添加三种等量混合后植物凋落物的土壤微生物量碳、氮含量高于两种凋落物等量混合处理,而两种凋落物混合高于单种凋落物处理;土壤矿质态氮含量的变化则相反,即单种＞两种混合＞三种混合。单种和两种混合后土壤微生物量碳、氮含量与其碳氮显著相关,而三种凋落物混合后土壤微生物量碳、氮含量与其碳氮比无相关性,说明多种凋落物混合后土壤微生物量碳、氮含量受多种因素共同影响。因此,在黄土高原植被恢复重建中,有必要采用不同种类植物搭配,利用生物多样性促进生态系统健康持续发展。     

凋落物的树种多样性与杉木人工林土壤生态功能

通过模拟试验和野外调查对凋落物的树种多样性与杉木人工林土壤生态功能之间关系进行了研究。林分取样调查的结果表明 ,有两个树种凋落物覆盖的几个杉阔混交林土壤脲酶和蔗糖酶活性均明显高于只有杉木凋落物覆盖的杉木纯林土壤 ,酸性磷酸酶活性也呈现相同的变化趋势 ,这 3种土壤酶活性均以具有凋落物种类最多的次生常绿阔叶林土壤最高。除了土壤酶活性升高之外 ,杉阔混交林的土壤有机质和全氮含量也明显高于仅有一种杉木凋落物覆盖的杉木纯林土壤。采用杉木叶凋落物与不同阔叶树种凋落物处理土壤的模拟试验结果表明 ,在凋落物投放量和 (1 5NH4 ) 2 SO4 施用量相同的控制条件下 ,随着投放的凋落物树种组成的增加 ,土壤中 1 5N的残留量也随之增加 ,而其损失量却随之减少 ;土壤中杉木幼树对于 1 5N的吸收量以及杉木幼树的单株鲜重也随着处理凋落物组成树种的增加而增加 ,具有不同树种数量的凋落物处理之间差异显著 (p<0 .0 5 )。可见随着凋落物树种多样性的增加 ,不仅土壤有机质和全氮含量这两个基本的质量指标得到明显改善 ,而且土壤酶活性、土壤养分保蓄功能以及保证幼树良好生长等的生态功能明显改善     

冀北辽河源自然保护区土壤微生物碳代谢对阔叶林叶凋落物组成的响应

利用凋落物袋法研究了冀北辽河源地区阔叶混交林内山杨、白桦、蒙古栎叶凋落物单一分解及混合分解对0~5、5~10和10~20 cm表层土壤微生物生物量碳、微生物呼吸和微生物代谢熵的影响.结果表明:0~20 cm土层对照、白桦、山杨和蒙古栎处理的土壤微生物生物量碳平均含量分别为124.84、325.29、349.79和319.02 mg·kg-1;微生物呼吸平均速率分别为0.66、1.12、1.16和1.10μg·g-1·h-1.0~20 cm土层单一凋落物处理、两种叶凋落物混合处理、3种叶凋落物混合处理的土壤微生物生物量碳平均含量分别为331.37、418.52和529.34mg·kg-1;微生物呼吸平均速率分别为1.13、1.30和1.46μg·g-1·h-1.土壤微生物代谢熵则呈现出与微生物生物量碳、微生物呼吸相反的变化趋势.说明凋落物质量不同,其土壤微生物碳代谢特征不同,表现为高质量凋落物土壤微生物生物量碳、微生物呼吸速率以及微生物对土壤中有机质的利用效率较高,低质量凋落物则与之相反.植物叶凋落物混合能够增强土壤微生物活性,增加土壤微生物对土壤碳的利用效率,促进土壤微生物代谢途径的多样化,有利于林地土壤质量的维护和提高.     

油松-辽东栎混交林地表凋落物与氮添加对土壤微生物生物量碳、氮及其活性的影响

2010年9月-2011年10月,在山西省灵空山油松和辽东栎混交林样地采取随机区组设计,研究了地表凋落物和氮添加处理对土壤微生物生物量碳、氮和微生物活性的影响.凋落物处理包括:剔除凋落物(N)、叶凋落物加倍(L)、枝果凋落物加倍(B)和混合凋落物加倍(LB);氮添加量分别为0(N0)、5 g· m-2·a-1(N1)和10 g·m-2·a-1(N2).结果表明:剔除地表凋落物且无氮添加时,油松和辽东栎混交林地的土壤有机碳(SOC)含量显著降低,其他试验处理间对SOC的影响无显著差异.土壤微生物生物量碳(MBC)、氮(MBN)及其活性(MR)的变化范围依次为:262.42 ～ 873.16 mg·kg-1、73.55 ～ 173.85 mg·kg-1和2.38～3.68mg·kg-1·d-1.MBC、MBN和MR两两间呈极显著正相关.氮添加对MBC、MBN和MR均无显著影响;凋落物处理对MR影响显著,表现为混合凋落物加倍处理的MR最高,叶凋落物加倍处理次之,剔除凋落物处理最低,而对MBC和MBN无显著影响.凋落物和氮添加处理在整个试验过程中未表现出交互作用.短期的氮添加处理和森林地表凋落物变化对土壤微生物过程的影响有限.     

中亚热带几种针、阔叶树种凋落物混合分解对土壤微生物群落碳代谢多样性的影响

土壤微生物群落功能如何响应凋落物物种组成的改变,对于指导我国的人工林种植具有重要意义。通过小盆模拟试验,用BIOLOG微平板培养的方法研究了南方红壤丘陵区典型物种马尾松和湿地松的凋落物分别与白栎和青冈的凋落物混合,与单一针叶凋落物分解时相比,针阔混合凋落物分解过程中土壤微生物群落功能多样性的差异。结果表明：(1)针叶和阔叶混合分解提高了土壤微生物群落碳代谢的强度、丰富度以及多样性,针阔混合凋落物分解时土壤微生物群落的碳源代谢方式与单一针叶分解时差异显著;(2)凋落物分解前期土壤微生物群落碳代谢强度、丰富度和多样性与凋落物初始C/N呈显著负相关,分解后期土壤微生物群落碳代谢强度与凋落物初始木质素/N比呈显著负相关,碳代谢多样性与初始P含量呈显著正相关;(3)通过改变凋落物物种组成,进而改变凋落物元素组成(C/N、木质素/N和P),能显著影响土壤微生物群落的碳代谢强度和代谢多样性。在南方红壤丘陵区,针-阔叶混合的凋落物比单一针叶凋落物更有利于提高土壤微生物群落的功能。     

不同退化沙地土壤碳的矿化潜力

通过实验室土壤培养试验 ,研究了科尔沁退化沙质草地不同生境 (流动沙地 ,半固定沙地 ,固定沙地和丘间低地 )下土壤碳的矿化潜力及不同凋落物在沙地土壤中的分解。经 33d的室内培养 ,不同生境土壤 CO2 - C的释放有极显著的差异 ,与生境植被盖度 ,凋落物积累 ,土壤沙化程度 ,土壤有机碳和全氮含量的分布有显著相关。流动沙地土壤有极低的土壤有机碳和氮的含量及其微弱的土壤微生物呼吸 ,表明土地沙漠化不仅导致土壤有机碳库衰竭 ,也使土壤微生物活性丧失。在有机质含量很低的流动沙地和半固定沙地土壤中 ,含氮量高的小叶锦鸡儿 (Caragana microphylla)凋落物比含氮量低、C/N比高的差巴嘎蒿(Artemisia halodendron)和 1年生植物凋落物有较快的分解。在沙漠化的演变中 ,土壤的粗粒化 ,有机物质和养分及微生物活性的丧失制约着凋落物在土壤中的矿化潜力。灌木的存在使更多的有机物质和养分积聚在灌丛下 ,形成灌丛肥岛 ,因而显著贡献于碳的固存。     

杉木和米槠凋落叶DOM对土壤碳矿化的影响

DOM(Dissolved organic matter)是土壤微生物呼吸的重要底物,凋落物淋溶的DOM对土壤碳矿化具有重要影响。选择中亚热带地区具有代表性的杉木(Cunninghamia lanceolata)和米槠(Castanopsis carlesii)凋落叶作为研究对象,通过两个月的短期室内培养,把不同凋落叶浸提出的DOM添加到培养瓶中,定期测定土壤碳矿化速率,计算土壤碳累积矿化量,探讨两种等浓度等量DOM添加对土壤碳矿化的影响,并分析DOM化学性质在土壤碳矿化过程中的重要性。结果表明:米槠凋落叶浸提得到的DOC(Dissolved organic carbon)和DON(Dissolved organic nitrogen)浓度均显著高于杉木凋落叶的(P0.05),而杉木凋落叶浸提得到的DOM的UV吸收值(SUVA_(254))和HIX(Humification index)均显著低于米槠凋落叶的(P0.01)。添加等浓度等量杉木和米槠凋落叶DOM到土壤中均显著增加了土壤碳矿化速率,在第1天内分别比对照高198%和168%,3d后下降到61.8%和44.1%,14d后基本处于平稳状态,表明外源有机物添加对土壤碳矿化的前期影响较大。培养过程中,添加杉木和米槠凋落叶DOM的土壤碳矿化累积量均能采用双因素指数模型进行拟合(r~2=0.99),但添加两者凋落叶DOM后土壤碳矿化累积量没有显著差异。     

杉木根系和凋落物对土壤微生物学性质的影响

通过模拟试验,研究了杉木根系和凋落物及其交互作用对土壤微生物学性质的影响.结果表明：杉木根系和凋落物在土壤生态过程中发挥的作用有所不同.与对照相比,杉木根系处理的土壤微生物生物量碳（MBC）、土壤基础呼吸、土壤有机碳（TOC）和微生物熵显著增加,土壤呼吸熵（qCO₂）显著降低（P<0.05）;凋落物处理中,仅土壤基础呼吸和qCO₂显著降低（P<0.05）,而MBC、TOC和微生物熵没有显著变化（P>0.05）.杉木根系和凋落物对土壤基础呼吸和qCO₂的影响具有显著的交互作用.qCO₂与土壤可溶性碳（R²=0.325）及TOC（R²=0.209）含量呈显著正相关,说明微生物对碳的利用效率随土壤有机碳数量的增加而降低.与凋落物相比,杉木根系在土壤生态过程中发挥着更重要的作用.     

土壤及凋落物源氮对中亚热带森林土壤SON的影响

土壤可溶性有机氮(SON)含量虽低,却是土壤氮库中最活跃的组分之一;主要来源于凋落物分解和土壤氮素转化。但是它们各自对土壤的影响还不清楚。通过添加杉木和~(15)N标记的阔叶凋落物于土壤表面,研究针阔叶凋落物分解对土壤SON的影响,及与土壤氮的关系。结果表明:由于没有降水的淋溶影响,培养期间,凋落物SON的显著降低,并没有直接增加土壤SON。与对照比较,杉木凋落物添加显著增加了土壤无机氮的含量,而较高C/N比的阔叶凋落物在其分解初期首先需要吸收更多的土壤氨态氮。添加~(15)N标记的阔叶凋落物提高了土壤SON在培养90—210天来自凋落物的比例,在第210天高达74.8%;来自凋落物的氨态氮比例在实验30天开始增加,到第210天高达39.8%;但是对硝态氮的影响不大。结果表明,土壤SON在培养初期因受凋落物的影响,主要来自土壤有机质的分解,而来自凋落物的SON更容易矿化;且土壤源的氮更容易发生硝化作用。可见,土壤中的SON是与凋落物分解动态、以及对土壤的影响有关。     

Effects of Single Chinese Fir and Mixed Leaf Litters on Soil Chemical, Microbial Properties and Soil Enzyme Activities

The quality of leaf litter can control decomposition processes and affect the nutrient availability for plant uptake. In this study, we investigated the effect of single leaf litter (Chinese fir – Cunninghamia lamcealata (Lamb.) Hook) and mixed leaf litters (C. lamcealata, Liquidamba formosana Hance and Alnus cremastogyne Burk) on soil chemical properties, soil microbial properties and soil enzyme activities during 2 years decomposition. The results showed that soil microbial biomass C, the ratio of soil microbial biomass C to total soil organic C (soil microbial quotient, Cmic/Corg) and soil enzymes (urease, invertase, dehydrogenase) activities increased significantly in mixed leaf litters treatments whereas soil chemical properties remained unchanged. However, soil microbial metabolic quotient (qCO₂) values and soil polyphenol oxidase activity were higher in the single Chinese fir leaf litter treatment that had a higher C:N (carbon:nitrogen) ratio (79.53) compared with the mixed leaf litter (C:N ratios of 76.32, 56.90, 61.20, respectively). Our results demonstrated that the mixed leaf litter can improve forest soil quality, and that soil microbial properties and soil enzyme activities are more sensitive in response to litter quality change than soil chemical properties.     

不同温度条件下杉木、桤木和火力楠细根分解对土壤活性有机碳的影响

通过室内培养试验,研究了不同温度(9 ℃、14 ℃、24 ℃和28 ℃)条件下桤木、杉木和火力楠细根分解对土壤活性有机碳的影响.结果表明,不同树种细根的分解率不同,树种间差异显著,大小依次为火力楠>桤木>杉木.细根分解率随着培养温度的增加而增大,随着培养时间的延长而降低.添加细根的种类、培养温度和培养时间均对实验系统中土壤微生物碳和水溶性有机碳的含量产生影响.3个树种细根分解使土壤微生物碳和水溶性有机碳含量显著高于对照,大小依次为火力楠>桤木>杉木>对照; 培养中期以及中等培养温度条件下细根分解对应着较高的土壤微生物碳和水溶性有机碳含量.细根分解对土壤易氧化碳含量无显著影响.     

秦岭山区人工林地枯落叶客置对土壤生物、化学性质的影响

通过对秦岭山区日本落叶松、油松、灰楸和锐齿栎4种典型人工纯林2年的枯落叶客置试验,探讨了枯落叶客置对土壤生物、化学性质的影响,以及不同树种的种间关系.结果表明：阔叶林枯落叶的年分解速率高出针叶林33.70%.当针叶林枯落叶被客置到阔叶林地后,年分解速率提高8.35%～12.15%,而当阔叶林枯落叶被客置到针叶林地后,年分解速率下降5.38%～9.49%.针阔树种间的枯落叶客置均能不同程度地提高土壤有机碳、速效氮、速效磷和速效钾的含量,且针叶林地的增幅(8.70%～35.84%)明显大于阔叶林地(3.73%～10.44%),其中针叶林地客置灰楸枯落叶后的增幅(24.63%～35.84%)大于客置锐齿栎枯落叶(8.70%～28.15%). 客置阔叶林枯落叶使针叶林地土壤由偏酸向中性方向发展, 土壤酶活性、微生物量C、N含量及其微生物数量提高,其中,客置灰楸枯落叶的增幅大于客置锐齿栎枯落叶;客置针叶林枯落叶后阔叶林地土壤酶活性、微生物量C、N含量及其微生物数量变化因树种而异,其中锐齿栎林地土壤酶活性和微生物量C、N含量有所提高,而灰楸林地却有所下降.客置阔叶林地枯落叶可改善针叶林地的土壤性质,而客置针叶林枯落叶后阔叶林地的效应则因树种而异.说明在人工纯林土壤退化的防治过程中,引入其他树种形成混交林或进行枯落叶客置都应注意种间关系的方向性.     

杨树和桤木落叶混合分解对土壤微生物生物量的影响

通过室内培养,研究了杨树和江南桤木落叶混合分解过程中两种落叶的混合比例及落叶添加方式对土壤微生物生物量的影响.结果表明:落叶混合比例对土壤微生物生物量碳(MBC)、氮(MBN)均有显著的影响.培养30 d,江南桤木落叶比例为50％以上的土壤MBC和MBN显著高于纯杨树落叶处理及对照;75 d时,江南桤木落叶比例≥40％的土壤MBC和≥30％的土壤MBN均显著高于纯杨树落叶处理及对照;135 d后,江南桤木落叶比例≥20％的土壤MBC和≥40％的土壤MBN均显著高于纯杨树落叶处理及对照.不同混合比例的土壤MBC/MBN无显著差异,总体呈前期增长后期下降的变化趋势.杨树和江南桤木落叶混合分解对土壤MBC和MBN有显著的协同促进作用.在整个培养过程中,落叶添加方式对土壤MBC、MBN和MBC/MBN无显著影响.     

The relationships between microbiological attributes and soil and litter quality in pure and mixed stands of native tree species in southeastern Bahia, Brazil

This study was conducted to link soil and litter microbial biomass and activity with soil and litter quality in the surface layer for different pure and mixed stands of native tree species in southeastern Bahia, Brazil. The purpose of the study was to see how strongly the differences among species and stands affect the microbiological attributes of the soil and to identify how microbial processes can be influenced by soil and litter quality. Soil and litter samples were collected from six pure and mixed stands of six hardwood species (Peltogyne angustifolia, Centrolobium robustum, Arapatiella psilophylla, Sclerolobium chrysophyllum, Cordia trichotoma, Macrolobium latifolium) native to the southeastern region of Bahia, Brazil. In plantations of native tree species in humid tropical regions, the immobilization efficiency of C and N by soil microbial biomass was strongly related to the chemical quality of the litter and to the organic matter quality of the soil. According to the variables analyzed, the mixed stand was similar to the natural forest and dissimilar to the pure stands. Litter microbial biomass represented a greater sink of C and N than soil microbial biomass and is an important contributor of resources to tropical soils having low C and N availability.     

杉木凋落物对土壤有机碳分解及微生物生物量碳的影响

利用¹³C稳定同位素示踪技术,研究了杉木凋落物对杉木人工林表层(0～5 cm)和深层(40～45 cm)土壤有机碳分解、微生物生物量碳和可溶性碳动态的影响.结果表明: 杉木人工林中深层土壤有机碳分解速率显著低于表层土壤,但其激发效应却显著高于表层土壤.杉木凋落物添加使土壤总微生物生物量碳和源于原有土壤的微生物生物量碳均显著增加,但对土壤可溶性碳没有显著影响.深层土壤被翻到林地表层,可能加速杉木人工林土壤中碳的损失.     

Litter fingerprint on microbial biomass,activity, and community structure in the underlying soil

Aims

Little is known about how plant leaf litter decomposing on the soil surface is affecting microbial communities in the underlying soil. Here we examined the effects of decomposing leaf litter of different initial chemistry on biomass, stoichiometry, community structure and activity of microorganisms in the soil underneath the decaying litter layer.

Methods

Leaf litter from six different neotropical tree species with contrasted quality decomposed on top of a common tropical soil in a laboratory microcosm experiment over 98 days. At the end of the experiment we determined microbial biomass C, N, and P, microbial community structure (PLFA), and community level physiological profiles (CLPP) from the top soil.

Results

Despite growing in a common soil substrate, soil microorganisms were strongly affected by litter species, especially by the soluble litter fraction. While litters with low soluble C content did not affect the soil microbial community, litters with high soluble C content led to an increase of microbial biomass and to a structural shift to relatively more Gram-negative bacteria. Changing community structure resulted in changes of catabolic capacity of microorganisms to metabolize a range of different C substrates. The large differences in leachate N and P among litter species, in contrast, had no effect on soil microbial parameters.

Conclusions

Our data suggest that plant litter decomposing on the soil surface exhibit a strong and predictable leachate C-control over microbial community biomass, structure and function in the underlying soil.

     

Effects of mixing pine and broadleaved tree/shrub litter on decomposition and N dynamics in laboratory microcosms

This study was carried out to compare the ecological function of exotic pine (Pinus radiata—Pr) and native pine (Pinus tabulaeformis—Pt) in terms of litter decomposition and its related N dynamics and to evaluate if the presence of broad-leaved tree species (Cercidiphyllum japonicum—Cj) or shrub species (Ostryopsis davidiana—Od) litter would promote the decomposition of pine needles and N cycling. Mass remaining, N release of the four single-species litters and mixed-species (Pt + Cj; Pr + Cj; Pt + Od; Pr + Od) litters and soil N dynamics were measured at microcosm scale during an 84-day incubation period. The Pt and Pr litter, with poorer substrate quality, indicated slower decomposition rates than did the Cj and Od litter. Due to their high C/N ratios, the N mass of Pt and Pr litter continuously increased during the early stage of decomposition, which showed that Pt and Pr litter immobilized exogenous N by microbes. No significant differences of soil inorganic, dissolved organic and microbial biomass N were found between the Pt and Pr microcosm at each sampling. The results showed that the exotic Pr performed similar ecological function to the native Pt in terms of litter decomposition and N dynamics during the early stage. The presence of Cj or Od litter increased the decomposition rates of pine needle litter and also dramatically increased soil N availability. So it is feasible for plantation managers to consider the use of Cj as an ameliorative species or to retain Od in pine plantations to promote the decomposition of pine litter and increase nutrient circulation. The results also suggested that different species litters induced different soil dissolved organic nitrogen (DON). As a major soluble N pool in soil, DON developed a different changing tendency over time compared with inorganic N, and should be included into soil N dynamic under the condition of our study.     

Species-dependent responses of soil microbial properties to fresh leaf inputs in a subtropical forest soil in South China

Aims Forest disturbance from extreme weather events due to climate change could increase the contribution of fresh green leaves to the litter layer of soil and subsequently alter the composition and activity of the soil microbial properties and soil carbon cycling. The objective of this study was to compare the effect of naturally fallen litter and fresh leaves on the soil microbial community composition and their activities.Methods Fresh leaves and normal fallen litter were collected from four tree species (Pinus elliottii, Schima superba, Acacia mangium, A. auriculaeformis) in subtropical China and mixed with soil. Soil microbial community composition was determined using PLFAs, and its activity was quantified by soil respiration. During a 12-month period, the decomposition rate of litter was measured bimonthly using a litterbag method. Soil microbial samples were collected after 6 and 12 months. Soil respiration was measured monthly.Important findings We found that fresh leaves decomposed faster than their conspecific fallen litter. Although total microbial biomass and bacterial biomass were similar among treatments, soil fungal biomass was higher in fresh leaf than fallen litter treatments, resulting in greater values of the Fungal phospholipid fatty acids (PLFAs)/Bacterial PLFAs ratio. Fungal PLFA values were greater for Schima superba than the other species. The effect of litter type on soil respiration was species-dependent. Specifically, fallen litter released 35% more CO₂ than fresh leaves of the conifer P. elliottii. The opposite pattern was observed in the broadleaf species whose fresh leaf treatments emitted 17%–32% more CO₂ than fallen litter. Given future predictions that global climate change will cause more disturbances to forests, these results indicate that conifer and broadleaf forests in subtropical China may respond differently to increased fresh litter inputs, with net soil microbial respiration decreasing in conifer forests and increasing in broadleaf forests.     

不同化学性质叶凋落物添加对土壤有机碳矿化及激发效应的影响

凋落物输入可显著影响土壤有机碳(SOC)矿化速率,但添加不同化学性质叶凋落物对土壤有机碳矿化释放CO₂及激发效应的影响及其机理仍不清楚。本研究将亚热带6种树种¹³C标记的叶凋落物添加至天然次生林0～10 cm原位土柱中,比较不同树种叶凋落物添加对土壤总CO₂、外源凋落物和土壤来源CO₂释放速率和累积量以及激发效应的影响,并量化叶凋落物化学性质与土壤CO₂释放累积量、激发效应的相关关系。结果表明: 添加叶凋落物能够显著提高土壤总CO₂和土壤来源CO₂释放量,存在显著正激发效应,激发效应值为68%～128%。不同树种叶凋落物添加对土壤有机碳矿化和激发效应的影响存在显著差异。Pearson相关分析和逐步多元线性回归分析发现,凋落物来源CO₂释放累积量与叶凋落物C、P和纤维素含量呈显著负相关,而土壤来源CO₂释放量与叶凋落物C:N和木质素:N呈显著正相关。综上,不同化学性质的叶凋落物对土壤有机碳矿化和激发效应的影响存在异质性,在亚热带地区森林类型转变过程中营造具有高质量叶凋落物的人工林将有助于减少森林土壤碳损失。