羊草草原枯枝落叶分解的研究——主要优势植物的分解速率和损失率

分解速率和损失率从不同侧面反映了枯枝落叶分解动态,羊草草原主要优势植物,羊草（Leymus chinensis),拂子茅（Calamagrostis epigejos),减蓬（Suaeda glauca),碱茅（Puccinellia tenuiflora),五脉山黎豆（Lathyrus quinqueneruivs),碱蒿（Artemisia anethifolia)分解速率的季节变化动态近似倒“V”字型,损失率的季节变化呈S型,反了枯枝落叶的失重情况,枯枝落叶的化学组成成分是造成不同种植物间分解差异的主要原因,特别是C／N比与分解快慢有密切关系,分解初期,枯枝落叶的损失符合指数衰减模型,枯枝落叶损失95％所需时间,羊草群落约为8．8a,杂类草群落约为9．7a,碱茅群落约为7．1a,碱蓬群落约为4．7a。     

森林枯枝落叶分解过程的微生物学特性

森林枯枝落叶是补亢森林土壤有机质的主要来源。枯枝落叶的分解过程,对于恢复和增进土壤肥力、改善林木营养和提高森林生产力,有着极为密切的关系。 在文献中,对森林枯枝落叶分解过程的研究有过不少的报道。其中不仅有关于枯枝落叶的特性、土壤有机质的积累、矿化过程中元素循环等研究资料(等,1954,1959;等,1961;Fcnton,1958)而且有某些关于森林枯枝落叶分解过程中氮的转化与微生     

农田土壤枯枝落叶分解代谢的灰色分析

研究了农田土壤枯枝落叶分解代谢过程的影响因素。结果表明 ,农田土壤枯枝落叶分解速率有明显的季节变化 ;分解速率的高峰值主要是在 7,8月份。通过灰色关联分析表明 ,影响土壤枯枝落叶分解速率的主要因素是弹尾类动物、线虫类动物、无机磷转化作用和土壤含水量。建立了灰色数学模型     

森林枯叶分解过程中真菌的特性

枯枝落叶是森林土壤有机质的主要来源,枯枝落叶的分解对提高土壤肥力,增加树木的生产力是极其重要的。关于枯枝落叶的特性,有机质的积累和元素循环,枯枝落叶分解过程中的微生物学特性,死地被物和土壤中微生物的分布和活动,土壤中的生物化学动态与物质转化的关系,近年来很多学者对此有过报道。     

羊草草原枯枝落叶分解的研究——枯枝落叶分解与生态环境的关系

枯枝落叶的分解受生态环境的影响,枯枝落叶置于不同的生态环境下,其分解速率不同。例如,羊草(Leymus chinensis)在6种不同生境中的分解存在着明显差异。枯枝落叶位于地表和地下,其分解速率则不同,埋入地下的分解比位于地表的迅速。分解速率与土壤水分、地表温度和土壤pH呈指数正相关,与相对湿度呈线性正相关,它们对分解有积极的促进作用。通过生态因子对分解影响的综合分析表明,在羊草草原上,诸生态因子对枯枝落叶分解的重要性依次为:土壤水分、土壤pH、地表温度、相对湿度。     

阔叶林红松内枯枝落叶层的生态作用

阔叶红松林的枯枝落叶层重平均12.7吨/公顷(干物重),年变化在8.10—12.70吨/公顷。未分解层3.6吨/公顷,半分解层9.1吨/公顷。 枯枝落叶层中含有大量的营养元素,含量为(公斤/公顷):Ca 185.45,N 124.65。Mg 26.00,P 15.18,K 14.35,Mn 4.86,Fe 4.50,Zn 0.84,Cu 0.22,其主要的生态意义是为生态系统提供营养。 枯枝落叶层对森林更新有一定意义,能为红松种子萌发提供良好条件,但在枯枝落叶层厚度较大时,使萌发幼苗得不到必要的生长条件,过分延伸幼茎钻出枯落层时因过量消耗养分于茎生长而抑制了根的发育。根发育不良的幼苗当年多死亡。 枯技落叶层还有截持降水减少迳流的意义。 一个有效的生态系统应该是枯枝落叶迅速分解而不是大量积累,经营管理应于注意。     

东北松嫩平原羊草群落的土壤呼吸与枯枝落叶分解释放CO2贡献量

根据静态气室法的测量结果 ,分析了羊草群落土壤呼吸量和枯枝落叶分解释放 CO2 量的季节动态 ,及其与地上生物量 ,枯枝落叶分解量及环境因子的关系。结果表明 :( 1 )在整个观测期内 ,羊草群落土壤呼吸的季节动态呈现单峰曲线 ,8月中旬达到最大值 1 3.2 7g C/( m2 · d)。 ( 2 )羊草群落土壤呼吸的季节变化规律与地上绿色体生物量的季节动态同步。( 3)羊草群落土壤呼吸的季节动态与枯枝落叶分解量的季节动态同步。 ( 4 )羊草群落土壤呼吸量与土壤 0～ 1 0 cm土壤含水量显著正相关。( 5 )地表枯枝落叶层直接排放 CO2 量的季节动态呈现逐渐递减的趋势 ,释放量平均为 -0 .87g C/( m2·d)。有减缓土壤向大气排放 CO2 的作用。 ( 6 )枯枝落叶分解释放 CO2 量同地表枯枝落叶量显著正相关。     

羊草草甸枯枝落叶的分解、积累与营养物质含量动态

通过数理统计,建立了枯枝落叶的分解和积累模型。枯枝落叶的消失率为0.4065g／g·a,消失量比率的季节变化符合于logisitic曲线,分解活动在5—9月份最活跃,这段时间的消失量约占全年消失量的90%。 分解作用冬季基本停止。羊草草甸在现有情况下,积累量达95%稳定状态大约需要8年。最大积累量约为572g／m2,在分解过程中,枯枝落叶中化学成分的含量和分解初期相比不断下降。氮、磷、钾较其它化学元素损失得快。纤维素分解较慢。各种化学成份损失的顺序是：K>P>N>Na>Ca>Mg>Fe>纤维素。     

羊草草原枯枝落叶积累的研究──自然状态下枯枝落叶的积累及放牧、割草对积累量的影响

在自然状态下,羊草草原枯枝落叶积累季节动态是积累量从５月出现,随着时间推移呈指数形式递增,１０月末出现最大值。当枯枝落叶输入量和分解速率保持恒定时,积累量的年变化,随着时间的进展不断增加,最后达到稳定状态,量大积累量为５７２ｇ／ｍ￣２,达９５％稳定状态时间约为７─８ａ。放牧对枯枝落叶积累有明显的抑制作用,当放牧强度达７．５８羊（只）／ｈｍ￣２时,积累量比非放牧区减少近７４％。割草对枯枝落叶积累的影响也是显著的,随着割草频度增加,积累量明显减少,当一年内刈割３次,积累量减少８３％。刈割时间对积累量的影响表现在割草期的早晚,伴随刈割时间推迟,积累量逐渐减少。     

小良热带人工混交林的凋落物及其生态效益研究

对小良热带人工混交林１０年凋落量及其季节和年际动态研究表明,小凋落物总量年均５．５３９ｔ·ｈｍ－２;凋落量的季节变化明显,一般以湿季的７月为凋落高峰;随着人工林的发育,其凋落物量的年际变化逐渐稳定;森林枯枝落叶层贮量为４．９ｔ·ｈｍ－２,少于其年均凋落量,处于分解大于积聚的周转过程中;森林枯枝落叶层的存在可降低温度,提高湿度,显著减少径流量和泥沙流失量,并可提高土壤肥力和增加土壤动物的多样性．     

土壤湿度对东北3种主要树种凋落物分解的影响

结合丰林国家自然保护区原始阔叶红松林1998-2017年表层(0～10 cm)土壤湿度监测数据,评估了全球变化背景下土壤湿度变化对东北主要森林树种红松、臭冷杉和白桦凋落物分解的影响.结果表明: 在同一土壤湿度水平下,凋落物分解速率随着凋落物质量的增加而增大,即表现为白桦>臭冷杉>红松.凋落物的分解速率随着土壤湿度的降低而减小.白桦、臭冷杉和红松3种凋落物的土壤湿度敏感性指数(M₁₀)分别为0.782、0.789和0.827,土壤湿度水平每降低10%,初始分解速率分别减小21.8%、21.1%和17.3%.高质量凋落物(高氮含量、低碳氮比、低木质素含量)的分解速率对土壤湿度变化的响应更敏感.凋落物分解速率在不同凋落物类型间的差异随着土壤湿度的降低而缩小.近20年间,原始阔叶红松林土壤湿度呈显著减少趋势,对凋落物分解表现为抑制作用.在全球变化背景下,随着气温的升高,土壤湿度将继续降低,对凋落物的抑制作用会进一步增强,并将部分抵消因温度升高所带来的凋落物分解速率增大的压力.     

原始阔叶红松林下红松、蒙古栎混合凋落叶分解特征及相互作用研究

采用凋落物网袋（litter bag）分解法,模拟红松（Pinus koraiensis）(以下用P表示)和蒙古栎（Quercus mongolica）（以下用M表示）在不同演替阶段可能的组成比例(P、M/P1∶3、M/P1∶1、M/P3∶1、M）进行野外分解实验。分析不同比例的两种凋落叶混合的分解特征、相互作用及机理。结果表明：1.从质量损失率来看,与单种凋落叶分解情况相比,蒙古栎和红松凋落叶混合对凋落物分解具有促进作用,其中蒙古栎和红松（M/P）按1∶3混合分解最快,且随着蒙古栎凋落叶在混合比例中的增加,混合分解速率先减小后增大。2.从C、N元素动态看,C素在各处理的凋落叶主要表现为净释放,而N素在各处理中变现比较复杂,在各处理的红松凋落叶中表现为富集,而在各处理蒙古栎凋落叶中则表现为释放。蒙古栎凋落叶可以促进红松凋落叶C元素释放和N元素的富集,降低红松凋落叶的C/N比,促进红松凋落叶的分解。红松凋落叶能促进蒙古栎凋落物C元素释放,但对蒙古栎凋落叶N元素的释放作用不明显,对蒙古栎凋落叶的C/N比影响也并不一致。     

Effects of nitrogen addition on litter decomposition, soil microbial biomass, and enzyme activities between leguminous and non-leguminous forests

Anthropogenic nitrogen (N) deposition is an expanding problem that affects the functioning and composition of forest ecosystems, particularly the decomposition of forest litters. Legumes play an important role in the nitrogen cycle of forest ecosystems. Two litter types were chosen from Zijin Mountain in China: Robinia pseudoacacia leaves from a leguminous forest (LF) and Liquidambar formosana leaves from a non-leguminous forest (NF). The litter samples were mixed into original forest soils and incubated in microcosms. Then, they were treated by five forms of N addition: NH₄ ⁺, NO₃ ^?, urea, glycine, and a mixture of all four. During a 6-month incubation period, litter mass losses, soil microbial biomass, soil pH, and enzyme activities were investigated. Results showed that mixed N and NO₃ ^?-N addition significantly accelerated the litter decomposition rates of LF leaves, while mixed N, glycine-N, and urea-N addition significantly accelerated the litter decomposition rates of NF leaves. Litter decomposition rates and soil enzyme activities under mixed N addition were higher than those under single form of N additions in the two forest types. Nitrogen addition had no significant effects on soil pH and soil microbial biomass. The results indicate that nitrogen addition may alter microbial allocation to extracellular enzyme production without affecting soil microbial biomass, and then affected litter decomposition process. The results further reveal that mixed N is a more important factor in controlling litter decomposition process than single form of N, and may seriously affect soil N cycle and the release of carbon stored belowground.     

Insight into the temperature sensitivity of forest litter decomposition and soil enzymes in subtropical forest in China

Aims With the continuing increase in the impact of human activities on ecosystems, ecologists are increasingly interested in understanding the effects of high temperature on litter decomposition since litter decomposition and the accompanying release of nutrients and carbon dioxide are key processes in ecosystem nutrient cycling and carbon flux. This study was conducted to evaluate the temperature sensitivity of forest litter decomposition and soil enzymes during litter decomposition in subtropical forest in China.Methods Two dominant litter types were chosen from Zijin Mountain in China: Quercus acutissima leaves from a broadleaf forest (BF) and Pinus massoniana needles from a coniferous forest (CF). The litter samples were incubated in soil microcosms at ambient control temperature (20°C) and 10°C warmer. During a 5-month incubation, chemical composition of litter samples, litter mass losses, and related soil enzyme activities were determined.Important findings Three main results were found: (i) high temperature accelerated decomposition rates of both litter types, and the temperature sensitivities of litter decomposition for BF leaves and that for CF needles are equivalent basically, (ii) high temperature enhanced soil enzyme activities in the two forest types, and the temperature sensitivities of polyphenol oxidase were significantly higher than those of the other soil enzymes and (iii) the temperature sensitivities of nitrate reductase were significantly higher in the CF soil than in the BF soil, while there was no significant difference in the temperature sensitivities of the other soil enzymes between BF and CF. As a long-term consequence, the high-temperature-induced acceleration of litter decomposition rates in these subtropical forests may cause carbon stored belowground to be transferred in the atmosphere, which may alter the balance between carbon uptake and release, and then alter the global carbon cycle in the coming decades.     

温带红松阔叶混交林凋落叶与主要大型土壤动物热值的季节变化

对温带红松阔叶混交林不同种类凋落叶、混合凋落叶和主要大型土壤动物的干质量热值及季节变化规律进行了研究.结果表明：不同种类凋落叶和3种大型土壤动物的干质量热值不同,且其季节变化规律存在一定的差异.红松凋落叶的干质量热值平均值最高(19.71 kJ·g^-1),枫桦(18.22 kJ·g^-1)、紫椴(18.13 kJ·g^-1)、混合凋落叶(17.91 kJ·g^-1)居中,水曲柳(16.94 kJ·g^-1)和色木槭(16.25 kJ·g^-1)最低.红松和色木槭凋落叶干质量热值随凋落叶分解进行呈逐渐降低趋势,水曲柳凋落叶干质量热值季节变化较小,而紫椴、枫桦和混合凋落叶干质量热值次年有上升的趋势.大型土壤动物中,蜈蚣(22.07 kJ·g^-1)的干质量热值最高,蚯蚓(16.72 kJ·g^-1) 次之,马陆(13.28 kJ·g^-1)最低.蚯蚓和马陆干质量热值的季节变化规律一致,蜈蚣干质量热值的季节变化规律则有所不同.凋落叶和3种大型土壤动物干质量热值的季节变化之间没有明显的相关性.     

Response of litter decomposition and related soil enzyme activities to different forms of nitrogen fertilization in a subtropical forest

With the continuing increase in the impact of human activities on ecosystems, ecologists are increasingly becoming interested in understanding the effects of nitrogen deposition on litter decomposition. At present, numerous studies have investigated the effects of single form of nitrogen fertilization on litter decomposition in forest ecosystems. However, forms of N deposition vary, and changes in the relative importance of different forms of N deposition are expected in the future. Thus, identifying the effects of different forms of N deposition on litter decomposition in forest ecosystems is a pressing task. In this study, two dominant litter types were chosen from Zijin Mountain in China: Quercus acutissima leaves from a late succession broad-leaved forest and Pinus massoniana needles from an early succession coniferous forest. The litter samples were incubated in microcosms with original forest soil and treated with four different forms of nitrogen fertilization [NH₄ ⁺, NO₃ ⁻, CO(NH₂)₂, and a mix of all three]. During a 5-month incubation period, litter mass losses, soil pH values, and soil enzyme activities were determined. Results show that all four forms of nitrogen fertilization significantly accelerate litter decomposition rates in the broadleaf forest, while only two forms of nitrogen fertilization [i.e., mixed nitrogen and CO(NH₂)₂] significantly accelerate litter decomposition rates in the coniferous forest. Litter decomposition rates with the mixed nitrogen fertilization were higher than those in any single form of nitrogen fertilization. All forms of nitrogen fertilization enhanced soil enzyme activities (i.e., catalase, cellulase, invertase, polyphenol oxidase, nitrate reductase, urease, and acid phosphatase) during the litter decomposition process for the two forest types. Soil enzyme activities under the mixed nitrogen fertilization were higher than those under any single form of nitrogen fertilization. These results suggest that the type and activity of the major degradative enzymes involved in litter decomposition vary in different forest types under different forms of nitrogen fertilization. They also indicate that a long-term consequence of N deposition-induced acceleration of litter decomposition rates in subtropical forests may be the release of carbon stored belowground to the atmosphere.     

西双版纳热带季节雨林凋落叶分解与土壤动物群落：两种网孔分解袋的分解实验比较

 以西双版纳热带湿性季节沟谷雨林混合凋落叶作为分解基质,在不同位置季节雨林样地,采用不同网孔（ 2和0.15 mm）分解袋,开展大中型土壤动物对雨林凋落叶分解影响的实验,测定了不同网孔分解袋土壤动 物多样性、凋落叶分解速率和主要养分元素释放状况。结果显示：2 mm网孔分解袋土壤动物类群相对密度 年均值为2.67～2.83目•g－1凋落物干重,个体相对密度年均值为22.3～21.77个•g－1凋落物干重,显著 高于0.15 mm网孔分解袋的类群相对密度0.27～0.28目•g－1凋落物干重和个体相对密度2.88～2.77个•g－ 1凋落物干重（p<0.01）,并且0.15 mm网孔分解袋中极少量的动物个体主要为小型类群弹尾目和蜱螨目（ 原生动物、湿生土壤动物线虫不计）,由此我们视2 mm网孔分解袋凋落叶分解由绝大多数土壤动物和其它 土壤生物共同作用,而0.15 mm网孔分解袋基本排除了大中型土壤动物对袋内凋落叶分解的影响。2 mm网 孔分解袋凋落叶物质失重率（71%左右）、分解率指数（1.88～2.44）和主要养分元素释放率明显高于 0.15 mm分解袋（34%～35%,0.48～0.58）。通过比较两种不同网孔分解袋凋落叶失重率和元素释放率的 差异,显示出季节雨林大中型土壤动物群落对凋落叶物质损失的贡献率为年均值46%左右,并使凋落叶C/N 和C/P明显降低,而对不同元素释放率的影响不同,其中对N、S和Ca元素释放率的影响较大,而对K素释放 的影响作用最小。相关分析显示,2 mm网孔分解袋内土壤动物群落类群和个体的相对密度与凋落叶物质残 留率有较好的负相关关系,而群落香农多样性指数与凋落叶分解率指数表现出一定的正相关关系。     

Influence of habitat,litter type,and soil invertebrates on leaf-litter decomposition in a fragmented Amazonian landscape

Amazonian forest fragments and second-growth forests often differ substantially from undisturbed forests in their microclimate, plant-species composition, and soil fauna. To determine if these changes could affect litter decomposition, we quantified the mass loss of two contrasting leaf-litter mixtures, in the presence or absence of soil macroinvertebrates, and in three forest habitats. Leaf-litter decomposition rates in second-growth forests (>10 years old) and in fragment edges (<100 m from the edge) did not differ from that in the forest interior (>250 m from the edges of primary forests). In all three habitats, experimental exclusion of soil invertebrates resulted in slower decomposition rates. Faunal-exclosure effects were stronger for litter of the primary forest, composed mostly of leaves of old-growth trees, than for litter of second-growth forests, which was dominated by leaves of successional species. The latter had a significantly lower initial concentration of N, higher C:N and lignin:N ratios, and decomposed at a slower rate than did litter from forest interiors. Our results indicate that land-cover changes in Amazonia affect decomposition mainly through changes in plant species composition, which in turn affect litter quality. Similar effects may occur on fragment edges, particularly on very disturbed edges, where successional trees become dominant. The drier microclimatic conditions in fragment edges and second-growth forests (>10 years old) did not appear to inhibit decomposition. Finally, although soil invertebrates play a key role in leaf-litter decomposition, we found no evidence that differences in the abundance, species richness, or species composition of invertebrates between disturbed and undisturbed forests significantly altered decomposition rates.     

海南岛中部丘陵地区植被恢复过程中凋落物动态及土壤碳氮含量变化

为探究海南岛中部丘陵地区植被恢复过程中凋落物分解动态和土壤碳氮含量变化,采用时空互代法,在琼中湾岭地区同时具有经自然恢复的草丛、灌丛、次生林和人工恢复的马占相思林4种植物群落的两个山坡采用凋落物袋法进行凋落物交互分解实验。结果表明:4类型凋落物在同一样地中分解时,灌丛凋落物肖梵天花分解速率最高;同一种类凋落物在4个样地中分解时,在灌丛样地的分解率较高,而在3个自然植被样地中,分解速率为灌丛>草丛>次生林,显示随着植物群落进展演替的进程,凋落物分解速率呈现先增加后降低的趋势;马占相思凋落物和在马占相思林样地分解凋落物的分解率均低于次生林。土壤碳氮含量变化不显著,但有随植被恢复进程而增加的趋势。