亚高山森林溪流镉储量与分配的动态变化特征

镉(Cd)是一种有害重金属元素,能够伴随溪流水体流动和物质沉积影响下游流域的生态环境安全,但缺乏必要关注。为了解森林溪流Cd储量及其分配的动态变化特征,以岷江上游亚高山森林集水区的溪流为研究对象,在长度10—50、50—150、150—260m区间内各选取5条典型溪流,研究Cd元素在亚高山森林-溪流-河流集合生态系统中的迁移过程。结果表明:亚高山森林溪流的Cd储量介于2.57—128.46mg/m²之间,主要储存于沉积物中;森林溪流上、中、下游的Cd储量没有显著差异;森林溪流的Cd储量以秋季凋落物高峰期最高,春季凋落物高峰期最低;森林溪流的上、中、下游Cd储量均在秋季凋落高峰最高,上、中游在春季凋落高峰最低,下游在非凋落高峰最低;凋落物的Cd储量与溪流水文特征密切相关。可见,亚高山森林溪流Cd储量动态具有季节性变化和一定的自净能力,这些结果为进一步了解Cd元素在水-陆生态系统的生物地球化学循环提供了新的角度。     

高山森林溪流冬季不同时期凋落物分解中水溶性氮和磷的动态特征

为了解高山森林溪流凋落物冬季分解过程中水溶性氮和磷的变化过程,采用凋落叶分解袋法,以川西高山森林典型乔木(四川红杉、方枝柏)和灌木(高山杜鹃、康定柳)凋落叶为研究对象,研究冬季不同时期(冻结初期、冻结期、融化期)溪流、河流、河岸带以及林下凋落叶水溶性氮和磷的动态特征.结果表明:经过一个冬季的分解,4种凋落物在不同生境下各时期的水溶性氮含量无显著变化.水溶性磷含量除林下外在其他生境均显著降低,表现出河流＜溪流＜河岸带＜林下的规律.高山森林凋落叶分解过程中水溶性磷含量与平均温度、正积温、负积温和流速呈显著负相关,水溶性氮含量与正积温呈显著正相关,物种显著影响凋落物分解过程中水溶性氮和磷的含量.高山森林凋落物冬季分解过程中水溶性磷更易随河流和溪流等水体的流动而流失,而水溶性氮受冬季水环境的影响相对较小.     

高寒森林溪流对凋落叶分解过程中木质素降解的影响

溪流广泛分布于高寒森林地表, 凋落于其中的林木凋落物的分解是整个森林生态系统物质循环的重要环节, 水体流动过程中的冲刷和淋洗作用及其他独特的环境条件可能显著影响凋落物中木质素的降解。该研究采用凋落袋法对比研究了岷江上游高寒森林4种典型且初始质量差异显著的凋落叶, 即康定柳(Salix paraplesia)、高山杜鹃(Rhododendron lapponicum)、方枝柏(Sabina saltuaria)和四川红杉(Larix mastersiana), 在不同生境(林下、溪流和河岸带)下分解过程中木质素残留质量和浓度(质量百分率)的动态变化特征。经过两年的分解, 发现溪流显著促进了凋落叶中木质素的降解; 同一物种凋落叶在不同生境下木质素残留质量差异显著(p < 0.05), 整体表现为溪流<河岸带<林下; 在凋落叶分解的初期木质素有明显的降解, 其浓度表现为先降低后升高, 但不同物种之间存在显著(p < 0.05)的差异; 在整个分解过程中, 木质素残留质量总体呈现出了降低的趋势。此外, 生境类型、分解时期和区域性环境因子(温度、pH值和营养元素的有效性)能显著影响木质素的降解率。这些结果表明, 传统上认为木质素在凋落叶分解初期相对稳定的观点可能并不准确, 其浓度很可能是先下降后升高, 这也与有关木质素动态的最新研究结果相一致。另一方面, 在不同分解时期和不同生境下, 凋落叶木质素降解率表现出了显著差异, 表明区域性环境因子在凋落叶分解和木质素降解过程中具有重要的作用。     

长白山地区溪流冻结初期凋落叶分解与底栖动物定殖的关系

长白山森林源头溪流每年11月至次年4月有约70%的河面被冰覆盖,季节性冻融过程特征明显.为了揭示溪流冻结初期凋落叶分解与底栖动物定殖的关系,在长白山地区1条源头溪流中,利用2种孔径(5和0.3 mm)的尼龙分解袋对色木槭、紫椴、蒙古栎的单一及混合凋落叶进行了为期35 d的分解研究.结果表明: 凋落叶质量损失率在单一树种间差异显著,表现为:色木槭＞紫椴＞蒙古栎,而在4种混合凋落叶间差异不显著;除紫椴和3树种混合凋落叶外,粗、细分解袋间凋落叶质量损失率差异不显著;凋落叶混合效应仅出现在紫椴-蒙古栎混合的粗分解袋内;定殖在不同凋落叶分解袋内的底栖动物群落结构差异较大,但撕食者密度在3种凋落叶间差异不显著,撕食者对凋落叶混合效应的响应也不显著.由结果可知,溪流冻结初期微生物是凋落叶的主要分解者,底栖动物的贡献率较低.虽然撕食者密度较低,但撕食者的活动是凋落叶混合效应出现的必要条件.底栖动物对食物和栖息地有一定的选择性,但由于定殖时间较短,凋落叶对撕食者定殖的影响不显著.本研究对源头溪流生态系统的冬季生态过程研究及生态系统管理具有一定的理论意义.     

底栖分解类群对金佛山森林溪流凋落物混合分解的影响

凋落物分解对于维持源头溪流生态系统碳和养分平衡有重要意义。以亚热带典型源头溪流金佛山溪流为代表,选取3种河岸带常见凋落叶为分解对象,设计3个单种和4个混合物种的凋落物组合,在原位放置3种孔径的分解袋（0.05mm、0.25mm和2mm）,探讨混合凋落物的性状与底栖分解类群对叶片质量损失和混合效应的影响。结果表明：（1）微生物在凋落物分解过程中相对贡献均大于50%,小型和大型底栖动物进一步加速了凋落物的分解过程。（2）单种凋落物分解速率存在显著差异：八角枫（Alangium chinense,质量损失率为53.05%）>缺萼枫香（Liquidambar acalycina,30.00%）>薄叶润楠（Machilus leptophylla,12.63%）。（3）混合凋落物中仅微生物参与的处理均表现为负的非加和效应,其中八角枫+缺萼枫香、八角枫+薄叶润楠、八角枫+缺萼枫香+薄叶润楠三个处理的效应显著;小型底栖动物加入后均表现为正的非加和效应,但不显著;在微生物、小型和大型底栖动物的共同作用下,缺萼枫香+薄叶润楠和八角枫+缺萼枫香+薄叶润楠的两个处理的正的非加和效应显著。亚热带源头溪流中凋落物分解功能与河岸植物和分解者类群的复杂性密切相关。     

重庆酸雨区马尾松林凋落物特征及对干旱胁迫的响应

气候变化导致干旱等极端气象事件增多,这将和酸雨等环境胁迫一起影响森林健康.在重庆铁山坪于2010年监测了酸雨区受害马尾松林的凋落物数量和组分特征及其对土壤水分的响应.结果表明:马尾松林月凋落物量呈“双峰”模式,第1高峰出现在8-9月份伏旱期,第2高峰出现在冬季休眠的12月份;枯死针叶占年凋落物总量的48.42％,凋落物组分比例为针叶＞树枝＞阔叶＞有机碎屑＞树皮及球果;除阔叶凋落物外,其它组分凋落物在伏旱期均明显增加,与土壤湿度显著负相关,特别是30-40 cm和40-50 cm土层;此外,马尾松林凋落物量还与表征气象干旱的气象指标显著相关.和健康森林相比,酸雨区受害林木的细根数量变少和分布变浅导致马尾松林针叶的年形成量与凋落量减少,但枝凋落量及其占总凋落量的比例增大;凋落发生对于旱胁迫更加敏感,年凋落物量的时间分布更集中在伏旱期;酸雨和干旱的双重胁迫将进一步恶化研究地区的森林健康状况.     

间歇性溪流米槠凋落叶分解过程胞外酶活性动态

以米槠(Castanopsis carlesii)凋落叶为研究对象,于2021年4—7月,对照森林地表和持续流水的溪流,研究间歇性溪流凋落叶分解过程中胞外酶活性变化规律。结果表明：(1)间歇性溪流凋落叶分解过程中酸性磷酸酶、β-葡萄糖苷酶、β-N-乙酰氨基葡萄糖苷酶和脲酶活性总体高于地表,低于溪流。(2)通过分析胞外酶化学计量比和矢量特征,发现三种生境凋落叶分解过程中微生物群落受碳和磷的共同限制。分解初期,间歇性溪流凋落叶分解过程中微生物群落相对碳限制程度高于其他两个生境,但相对磷限制低于地表,高于溪流;随着分解的进行,间歇性溪流凋落叶分解过程中微生物群落相对磷限制程度逐渐减弱,相对碳限制程度逐渐加强。(3)统计分析表明,间歇性溪流中大气温度是凋落叶分解过程中胞外酶活性的主控因子,而地表凋落叶分解过程中胞外酶活性与大气温度、地表温度和土壤含水量关系更为密切,溪流凋落叶分解过程中胞外酶活性主要受水体温度、溪流深度和气温等因子的影响。研究结果为全面认识亚热带森林生态系统物质迁移与循环过程提供了新思路和科学依据。     

北热带喀斯特季节性雨林凋落物组分构成及时空动态

森林凋落物是森林生态系统的重要组成部分,在森林生态系统的物质循环和养分平衡中起重要作用。自2012年5月开始,我们在弄岗北热带喀斯特季节性雨林15 ha森林动态监测样地中布设了90个凋落物收集器进行凋落物收集。本文选取2013–2014年期间相关数据,研究了凋落物的组分特征、物种组成、时间动态和空间分布特征等。结果表明,2013年和2014年凋落物总量分别为4,858.0 kg/ha和4,928.8 kg/ha;凋落物组分以凋落叶为主且高达85%以上,其他组分所占比例较小。凋落物总量和凋落叶均有两个高峰期,分别发生在每年的春季(3–4月)和秋冬季(8–11月),凋落果的高峰期在8月左右;其他组分由于凋落量较少,年际动态并不明显。不同生态因子对凋落物总量分布格局的影响差异显著,且存在年际变化,但总体表现出凋落物总量受凋落物收集器所在样方的坡向和样方内所有DBH≥1 cm个体的平均胸径影响最为显著。喀斯特季节性雨林凋落物的组分构成和时空动态特征反映了不同生物和非生物因素影响下的物质循环规律,为深入揭示喀斯特独特地质、地貌背景下物质循环和能量流动的特殊性提供了基础。     

森林凋落物养分空间变异及其影响因素

凋落物是衡量森林质量的关键特征之一,具有养分归还、水土保持、过滤有毒物质、提供动物和微生物的食物、影响种子萌发和维持地表温湿度等生态功能。凋落物养分空间变异是指在一定的区域内,因空间位置不同凋落物养分特征存在的差异性和多样性,其影响群落分布格局,是森林生态系统中普遍存在但极为重要的特性。本文综述了国内外森林凋落物养分空间变异及其与自然和人为因素关系的研究进展。目前,凋落物养分空间变异研究以经典统计学和地统计学两种定量描述方法为主,涉及森林群落、景观和区域及全球尺度,受到植物、土壤、地形、气候、森林结构和干扰等诸多因子的影响,因研究的方法、对象、目的、区域或尺度不同而存在差异。因此,需进一步加强定量描述凋落物空间变异方法的综合应用和标准化,针对性地选择适宜的方法来描述森林凋落物养分空间变异,广泛开展多重尺度上凋落物养分的空间变异及其与多因素的关系,确定研究尺度及相应的主控因子。     

核磁共振技术在森林凋落物分解研究中的应用

凋落物分解是连接森林生态系统地上和地下部分的关键过程,影响着森林生态系统的养分循环,对全球碳(C)循环和森林生态系统生产力具有重要的调控作用。特别是,在当前全球气候变化的背景下,研究森林凋落物不同有机C组分的分解动态对于了解土壤有机质的形成、稳定性及其对气候变化的反馈效应至关重要。核磁共振技术(NMR)具有无损和非侵入等特点,是研究有机化合物结构的有效手段,已在凋落物分解研究中得到广泛应用。本文概述了NMR技术应用于森林凋落物分解过程的最新研究进展,包括森林凋落物有机C基团的NMR特征,凋落物分解过程中不同C基团的变化特征及其机理、凋落物分解过程的NMR评价指标等,并分析了NMR技术在凋落物分解研究中存在的问题和未来研究方向。NMR技术将有助于了解凋落物有机C基团的分解特征及其对土壤有机质形成和稳定的影响机理。     

Across-reach consistency in macroinvertebrate distributions among litter patch types in Japanese headwater streams

Different types of litter patches with contrasting macroinvertebrate assemblages have been observed within a stream reach. This study examined whether distributions of macroinvertebrates among three litter patch types (riffle, middle, edge) were consistent between reaches with different channel characteristics in headwater streams in central Japan. Mass of leaves per unit area was significantly higher in riffle and edge patches than in middle patches, which was consistent between reaches, while no consistent pattern was evident between reaches for mass of either woody material or small litter fragments. Distribution among the patch types was consistent between reaches for 11 out of 13 dominant macroinvertebrate taxa; density was highest in riffle patches for 5 taxa and in middle patches for 5 taxa. Although we previously related densities of some taxa to mass of woody material or small litter fragments, hydraulic characteristics (water depth, current velocity), which were consistent between reaches, may be more important determinants of macroinvertebrate distributions among the patch types, even within pools (i.e. middle and edge patches) where current is uniformly low. The results of this study indicate that a reach-scale macroinvertebrate community structure associated with litter is likely to vary according to litter patch type composition, which would be affected by channel characteristics of the reaches.     

Impact of highway construction on leaf processing in aquatic habitats of eastern Tennessee

Rates of leaf litter processing at eight sites were used in conjunction with other methods to evaluate the impact of highway construction on aquatic habitats. Monthly processing of white oak leaves from four different mesh size bags at unimpacted reference sites indicated that the three larger mesh sizes were useful for comparing sites, as they did not restrict invertebrate colonization and provided similar rates of processing within sites. Small mesh size (0.12 mm) prevented leaf shredding macroinvertebrates from colonizing bags, and caused significantly slower leaf processing in a riffle.Leaf processing was fastest in a reference riffle above an area of highway construction but was significantly slower in the reference pool due to low current velocity and the absence of shredders. Leaf processing in a riffle below the highway was slower than the reference riffle, and the number of shredders was reduced. Removal of streamside vegetation during highway construction caused increased stream temperatures and reduced the amount of natural leaf accumulations, thereby reducing shredder habitat. At other sites highway construction caused less of an impact than preexisting environmental influences. Leaf processing in an riffle of a lower pH stream was significantly slower than in the reference riffle. Shredders were absent from the low pH stream, and rates of leaf processing in the acid impacted riffle and pool were similar to those of the reference pool. Comparisons of the low pH stream with the reference stream indicated that physical processes were less important than biological processes of leaf decay. Leaf processing in ponds was similar to that of stream pools. Processing was faster in a small versus large pond, and a high density of invertebrates was associated with leaf bags in the small pond after one year.     

Influence of urban tributaries on freshwater mussel populations in a biologically diverse piedmont (USA) stream

We investigated the distribution patterns of senescent and green leaf litter patches on a streambed to evaluate the hypothesis that the different immersion times of senescent leaves in long-term benthic storage and newly retained green leaves affect streambed distribution patterns in summer (June, July, and August). We counted all the leaf litter patches in the streambed of the study reach, comparing the physical condition of patches and classifying the trapping obstacles associated with each patch type. The distribution patterns of senescent and green leaf litter patches differed. Green leaf litter patches were more numerous at every sampling date, with most trapped by cobbles, whereas senescent leaf litter patches were retained by twig obstacles, backwaters, and cobbles. In June and July, senescent leaf litter patches were located in significantly deeper stream areas than were green leaf litter patches. The distribution of senescent leaves would be primarily determined during spring snowmelt-driven floods. We speculate that senescent leaves were originally located at the edges of pools in the main flow pathway of the channel, which overflowed in the floods. We conducted flume experiments to clarify the transport characteristics of senescent and green painted maple and manchurian alder leaves in the water column. Our hypothesis was that the transport characteristics of each leaf type differ when they first enter the water, because of differing leaf properties. The flume experiments showed that duration of surface flotation differed for senescent and green leaves and for the two tree species. These differences in the duration of leaves on the streambed and in the floating time of green leaves of different trees ensure varied food resources for macroinvertebrates in various physical conditions. Handling editor: B. Oertli     

Disappearance of overstorey and understorey litter in an open eucalypt forest

Litter accumulation dynamics and first year rates of disappearance were investigated for leaves of overstorey and understorey species in the mixed eucalypt forest in the Griffith University study area, Queensland, Australia. The average biomass of the litter layer, was 10.2 t/ha. The wood and overstorey leaf litter formed 62.7% of the accumulated litter biomass, and were spread continuously across the ground. The distribution of shrub litter was discontinuous, being concentrated in localized patches beneath individual plants. The litter bag and tethered leaf techniques were used to measure the rate of disappearance of overstorey and shrub leaves. The ‘pairedquadrat’ technique was used to measure the weight loss of the grasses. The small leaves of the dominant shrub, Pultenaea villosa Willd. disappeared most rapidly, followed by the overstorey leaves, grasses and Acacia leaves. Fragmentation by physical factors and litter fauna appeared to be the major factors responsible for the disappearance of the overstorey leaves during the first year of exposure. The data suggest that removal of leaf constituents by leaching and microbial decomposition were more important for the shrub litter than the overstorey leaves. Fractional disappearance rates (loss constants) obtained from the short term weight loss measurements, and calculated using the steady-state model of litter accumulation (k=L/X), overestimated the rate of litter disappearance and litter decomposition. For the overstorey leaves in particular, the loss constants also overestimated the rate of loss of material from the litter layer since the fragmented and consumed tissues accumulated in the fraction of comminuted fragments before moving into the humus/soil subsystem. A compartment model of the components of the litter layer in the mixed eucalypt forest is presented. It incorporates overstorey and understorey litter accession, accumulation and disappearance data. The adoption of a two dimensional decomposition/accumulation matrix is suggested as an appropriate framework within which to simulate the dynamics of the litter subsystem in mixed eucalypt forest ecosystems.     

Differences in patches of retention among leaves,woods and small litter particles in a headwater stream: the importance of particle morphology

The location of retention in the channel can influence invertebrate assemblage and breakdown processes associated with a litter particle in heterogeneous streams. We previously identified four types of litter patches that formed on riffles or different locations in pools (middle, edge, alcove), and demonstrated that middle patches had higher litter processing rates than the other patches. In this study, we examined differences in retention on the four patch types among leaves, woody materials and small litter particles, and among leaves of different sizes, by sampling natural and manipulated litter particles that were newly retained. Proportionally more woody materials, leaf pieces (16–50 mm) and particulate organic matter (1–16 mm) than leaves (>50 mm) were retained on middle patches, while proportionally more leaves than the other litter particles were retained on riffle and edge patches. The retention pattern of leaf species with different leaf sizes and a released experiment of leaf particles revealed that proportionally more leaf particles with smaller sizes were retained on middle patches. The flexibility, shape and dryness of litter particles also seem to affect the location of retention in the channel. These results suggest that the morphology of litter particles have the potential to affect the biological use and breakdown of litter particles through determining the location of retention within the channel. The size of leaves and processes that alter leaf size may have important roles on the breakdown and utilisation by invertebrates in these heterogeneous streams.     

Limited evidence that mixing leaf litter accelerates decomposition or increases diversity of decomposers in streams of eastern Canada

Most studies of terrestrial litter decomposition in streams and rivers have used leaves from a single tree species, but leaf packs in streams in eastern North America are usually mixtures of two or more species. Litter mixtures may decay more quickly than either of the component species. If so, estimates of stream energy and nutrient budgets may be inaccurate. In northern Nova Scotia, Canada, we measured mass loss from binary mixtures (1:1 mass ratio) of leaf litter in mesh bags, using freshly fallen or air-dried litter from five species of canopy trees. We repeated the experiment eight times, in summer and fall, in two streams and a small river, over 3 years. In some trials we enumerated benthic invertebrate and fungal colonization of decaying litter. Although there were marked differences in mass loss rates among litter types, decomposition was accelerated in mixtures relative to the mean of the component species in only three of eight trials, and only in mixtures containing N-rich speckled alder leaves. Mixing yellow birch and red maple leaves inhibited decomposition. Diversity (Shannon–Weaver Index), species richness, and abundance of aquatic hyphomycete fungi, as indexed by conidial production, were never greater (and sometimes less) on litter mixtures than on the component species. Total numbers, taxonomic richness and diversity of benthic invertebrates generally, and litter-feeding species in particular, were not augmented by mixing litter types. Litter mixtures appear to dilute a preferred substrate with patches of a less preferred substrate. Our results provide only weak support for the contention that combining two litter types leads to acceleration of decomposition rates. Handling editor: K. Martens     

Flow-substrate interactions create and mediate leaf litter resource patches in streams

1. The roles that streambed geometry, channel morphology, and water velocity play in the retention and subsequent breakdown of leaf litter in small streams were examined by conducting a series of field and laboratory experiments. 2. In the first experiment, conditioned red alder (Alnus rubra Bongard) leaves were released individually in three riffles and three pools in a second‐order stream. The transport distance of each leaf was measured. Several channel and streambed variables were measured at each leaf settlement location and compared with a similar number of measurements taken at regular intervals along streambed transects (‘reference locations’). Channel features (such as water depth) and substrate variables (including stone height, stone height‐to‐width ratio, and relative protrusion) were the most important factors in leaf retention. 3. In the second experiment, the role of settlement location and reach type in determining the rate of leaf litter breakdown was examined by placing individual conditioned red alder leaves in exposed and sheltered locations (on the upper and lower edges of the upstream face of streambed stones, respectively) in riffle and pool habitats. After 10 days, percent mass remaining of each leaf was measured. Generally, leaves broke down faster in pools than in riffles. However, the role of exposure in breakdown rate differed between reach types (exposed pool > sheltered pool > sheltered riffle > exposed riffle). 4. In the third experiment, the importance of substrate geometry on leaf litter retention was examined by individually releasing artificial leaves upstream of a series of substrate models of varying shape. Substrates with high‐angle upstream faces (were vertical or close to vertical), and that had high aspect ratios (were tall relative to their width), retained leaves more effectively. 5. These results show that streambed morphology is an important factor in leaf litter retention and breakdown. Interactions between substrate and flow characteristics lead to the creation of detrital resource patchiness, and may partition leaf litter inputs between riffles and pools in streams at baseflow conditions.     

Leaf litter patches in stream create overwintering habitats for Ezo brown frog (<Emphasis Type="Italic">Rana pirica</Emphasis>)

Only fragments are known about the functions of leaf litter patches in streams for terrestrial organisms. We investigated the movement patterns of Ezo brown frogs (Rana pirica) on two occasions, in autumn 2014 and summer 2015, and the occurrence of frogs in rivers and along riverbanks on three occasions from summer to autumn 2014 along a 1.5-km stream segment that flows through the Bekanbeushi wetland, northern Japan. Ezo brown frog movement was biased toward the river channel in late autumn and this movement pattern coincided with relatively abundant Ezo brown frogs on the riverbed from autumn to winter 2014. The distribution shift was also supported by decreasing abundance of Ezo brown frogs on riverbanks from autumn to winter (no sighting in winter) during daytime observations. The abundance of overwintering Ezo brown frogs in the channel was associated most positively with leaf litter dry mass and depth, with flow velocity being relatively less important at the quadrat scale (0.063 m²). Our results demonstrated that Ezo brown frogs overwinter in the stream and suggest that leaf litter patches positively affect the quality of the overwintering habitat.     

Decomposition of litter in sub-alpine forests of Eucalyptus delegatensis,E. pauciflora and E. dives

The rate of decomposition of summer leaf-fall (abscised leaves), winter leaf-fall (containing some green leaves) and mature green (picked) leaves was assessed in sub-alpine forests of E. delegatensis (R. T. Baker), E. pauciflora (Sieb. ex Spreng) and E. dives (Schau.) in the Brindabella Range, Australian Capital Territory, using litter bag and tethered leaf techniques. The relative contribution of leaching, microbial respiration and grazing by invertebrate macrofauna to loss of leaf weight was determined. The effect of leaching and microbial respiration was assessed in terms of weight loss per unit area of leaf (specific leaf weight), while losses due to macro-faunal grazing were assessed by measuring reductions in leaf area. Litter decomposition constants for litter components (leaf, bark, wood) and total litter were determined from long-term records of litterfall and accumulated litter. Weight losses of abscised leaves during the initial 12 months ranged from 25% for E. pauciflora to 39% for E. delegatensis and were almost entirely due to reduction in specific leaf weight. Losses in the weight of leaves falling in winter ranged from 38 to 49%, while green leaves lost 45 - 59%. Approximately 50% of the total weight loss of green leaves was due to a loss in leaf area caused by skeletonization by litter macrofauna. Thus abscised leaves rather than green leaves must be used for measuring litter decomposition rates since abscised leaves constitute most of the litterfall in eucalypt forests. Leaves placed in the field in autumn decomposed slowly during the first summer, while the rate increased during the second winter and summer. Low litter moisture content appears to limit decomposition in the initial summer period in all communities, after which litterfall provides a mulch which reduces the rate of desiccation of lower litter layers. A simple linear regression model relating decomposition rate to the number of days (D) when litter moisture content exceeded 60% ODW accounted for 63-83% of the variation in decomposition of leaves in the field. Inclusion of mean monthly air temperature (T) and the product of D and T (day degrees when litter was wet) in a multiple linear regression increased the variation in decomposition accounted for to 80 – 90%. The rate of weight loss showed a positive linear relationship with the initial concentration of nitrogen (N) or phosphorus (P) in the leaf. These concentrations are an index of the decomposability of leaf substrates (e.g. degree of sclerophylly or lignification). The rate of loss of specific weight was similar for tethered leaves and for leaves enclosed in mesh bags. Measured loss in specific leaf weight after 70 – 90 weeks was less than that predicted using decomposition constants (k).     

Hot spots of leaf breakdown within a headwater stream reach: comparing breakdown rates among litter patch types with different macroinvertebrate assemblages

1. Detecting hot spots of litter decomposition will promote understanding of litter processing in a heterogeneous system. To identify hot spots of leaf breakdown within a headwater stream reach, we examined the difference in leaf breakdown rate among four types of litter patches, one that formed in riffles and three that formed in pools (middle, alcove, edge), in different seasons. 2. Middle patches showed the highest breakdown rate in some seasons; the rate in middle patches was 1.5–4 times higher than in the other patches. Thus middle patches can be regarded as hot spots of leaf breakdown in the study reach. This result contrasted with other studies showing higher breakdown rate in riffles than in pools. 3. Significant relationships between abundance of caddisfly shredders and breakdown rate were observed in seasons when the rate differed among patch types. Greater abundance of Lepidostoma seems to be responsible for middle patches being hot spots of leaf breakdown. 4. It is expected that when the proportion of leaves retained in middle patches within a reach is higher, the breakdown rate of the entire reach will be increased. Clarifying how the proportion of leaves retained on middle patches within a reach varies temporally and spatially would improve our understanding of leaf breakdown in headwater streams.