杉木,火力楠纯林及混交林细根周转的研究

系统研究了杉木、火力楠纯林及混交林细根生物量、生产力及年周转率。结果表明,杉木、火力楠纯林及混交林活细根生物量分别为８８０、３０３５和１５６０ｋｇ．ｈａ＾－１;死细根生物量为２３５、３９８和５６５ｋｇ．ｈａ＾－１;细根年周转率为１．２９、１．４２和１．４０;年生产量为１１３７、４３１８和２１７９ｋｇ．ｈａ＾－１;年死亡量为４９７．５９５和１１４９ｋｇ．ｈａ＾－１,分别相当于林分枯枝落叶年凋落量为３     

凋落物输入对中亚热带不同森林细根生物量及分布的影响

在全球变化背景下,植物凋落物输入的改变对森林生态系统地下生态过程具有重要的影响。中亚热带森林中,细根进入凋落物层生长是一种常见现象,然而凋落物量的改变对细根生长影响的研究较少。通过对中国中亚热带针叶林、针阔混交林及常绿阔叶林这3种典型森林进行地上凋落物添加和去除实验,研究不同凋落物处理水平下细根生物量、垂直分布及形态特征的变化。结果表明:与对照(CK)相比,地上凋落物去除(LR)分别导致针叶林和针阔混交林细根总生物量显著降低40.3%和37.5%,而凋落物添加(LA)使常绿阔叶林中的细根总生物量明显提高了19.4%。不同层次的细根生物量对凋落物处理的响应不同,从针叶林到常绿阔叶林,凋落物量的改变对细根的垂直分布的影响加剧。LA处理明显提高常绿阔叶林凋落物层的细根生物量百分比(相比对照提高了10.6%)以及降低7.5—15 cm土层的细根生物量百分比(相比对照降低了10.4%)。凋落物层中生长的细根生物量和凋落物层厚度呈高度线性相关(R~2=0.742,P0.01),并且和凋落物层生物量也呈显著线性相关(R~2=0.521,P0.01)。3种森林类型细根的根长密度(RLD)和比根长(SRL)变化趋势与细根所处的层次紧密相关,而不同凋落物处理对它们的影响均不明显,说明细根对养分的获取策略表现为在养分丰富的凋落物层和表土层投资更多的生物量和更活跃的代谢,而不是改变细根形态的表型可塑性。     

阔叶和杉木人工林对土壤碳氮库的影响比较

通过比较我国亚热带地区19年生阔叶人工林和杉木人工林土壤碳氮储量,探讨树种对土壤碳氮库的影响.结果表明:阔叶人工林0 ～40 cm土层碳储量平均为99.41Mg·hm-2,比杉木人工林增加33.1％;土壤氮储量为6.18 Mg·hm-2,比杉木人工林增加22.6％.阔叶人工林林地枯枝落叶层现存量、碳和氮储量分别是杉木人工林的1.60、1.49和1.52倍,两个树种的枯落叶生物量、碳和氮储量均有显著差异.枯枝落叶层碳氮比值与土壤碳、氮储量之间呈显著负相关.阔叶人工林细根生物量(0～80 cm)是杉木林的1.28倍,其中0～10 cm土壤层细根生物量占48.2％;阔叶人工林细根碳、氮储量均高于杉木人工林.在0～10 cm土层,细根碳储量与土壤碳储量具有显著正相关关系.阔叶树种比杉木的土壤有机碳储存能力更大.     

南亚热带格木和红椎凋落叶及细根分解特征

采用原位分解法对南亚热带格木(Erythrophleum fordii)和红椎(Castanopsis hystrix)人工纯林的凋落叶和细根分解动态及凋落叶和细根分解速率之间的相关关系进行了比较研究。结果显示,格木、红椎人工林凋落叶和细根分解系数分别为0.98a~(-1)、0.88a~(-1)和0.65a~(-1)、0.59a~(-1)。格木、红椎凋落物分解主要受凋落物自身化学性质的影响,而与林分内环境条件的关系不显著。分解初期,凋落叶和细根的质量损失均与氮含量显著正相关(R~2分别为0.525和0.549),与C/N比显著负相关(R~2分别为0.764和0.361);而分解后期,凋落叶和细根的质量损失均与氮含量显著正相关(R~2分别为0.565和0.511),与C/N比、木质素含量、木质素/N比显著负相关(R~2分别为0.482和0.574;0.525和0.519;0.523和0.486)。格木、红椎凋落叶分解速率和细根分解速率表现出明显的正相关性,这主要归因于凋落叶、细根基质质量对凋落叶分解速率和细根分解速率的影响具有明显的相似性。     

武夷山甜槠林细根生物量和生长量研究

对武夷山甜槠林细根生物量和生长量的季节动态及其在不同群落发育阶段下的变化进行了初步研究,并对细根在养分归还中的作用进行了分析．结果表明,甜槠成熟林细根生物量为１０．６４５ｔ·ｈｍ－２,生长量为７．３７１５ｔ·ｈｍ－２·ａ－１,分解量为４．６７７５ｔ·ｈｍ－２·ａ－１,年周转率０．６９次;细根生物量和生长量随林龄增长的变化模式为单峰型曲线,生物量至３４龄时达到最大值,生长量至群落郁闭阶段（５８龄）达到最大值;甜槠成熟林中,通过细根死亡的Ｎ素归还量占群落年归还总量的４９．５％,多于凋落物途径,Ｐ、Ｍｇ归还量所占比例为４２．３％和２８．９％,略低于凋落物途径;Ｋ、Ｃａ归还以降水淋溶为主,其次是凋落物途径,而细根途径仅占总归还量的１９．３％和９．２％．     

人工红松林土壤中蚯蚓的数量

蚯蚓是使植物凋落物和土壤本身相混合的主要动力,而有机质和土壤的混合有助于表土层保持疏松与通气良好的状态。另外,植物凋落物转化为腐殖质过程中,蚯蚓也起着重要作用。为研究人工红松林土壤条件变化,我们对其林下土壤中蚯蚓的数量进行了调查,现将调查结果整理如下,供参考。一、调查方法按红松林龄分别用50×50平方厘米的样方,挖土就地手拣的方法进行调查,共调查8处人工红松纯林(林龄10—50年),两处阔叶红松林,一处林间空地,计68个样方,另外调查了10年生红松纯林、两处阔叶红松林的枯枝落叶量,其方法是设两平方米样方收集全部枯枝落叶,就地称重后取样,在105℃条件下烘干,推算单位面积枯枝落叶量。     

海南岛北部木麻黄林凋落物与土壤养分、细根生物量的关系

通过对海口市桂林洋海岸木麻黄防护林地表凋落物进行持续清除处理,与保留凋落物层的对照样地进行比较实验,研究防护林凋落物-土壤养分-细根生物量三者之间的关系。结果表明:(1)处理样地与对照样地的年凋落物量分别是6.0162和5.9505t·hm-2,但无显著性差异。两种样地一年内凋落物量变化的时间格局较一致。凋落物组成均为小枝占比例最高,且小枝凋落物量月动态与凋落物总量月动态相似,杂物占比例次之,皮+枝占的比例最小;(2)N、P、K元素归还量的月动态变化在两样地中均较一致。两样地中小枝养分归还量的大小顺序为N>K>P;(3)处理样地在短时间无新鲜凋落物输入情况下,两样地的土壤养分含量无显著性差异;(4)两样地的细根生物量季节动态均呈现"单峰"特征,细根生物量在实验期间无显著性差异,但处理样地的细根生物量有随时间延长低于对照样地的趋势,清除凋落物的处理可能会引起细根生物量的减少。     

长白山几种主要森林群落木本植物细根生物量及其动态

2005年在长白山北坡选择5种垂直植被带典型植物群落类型阔叶红松林、白桦林、山杨林、云冷杉林和岳桦林,利用钻取土芯法对细根分布及细根生物量进行了研究.研究结果表明,不同森林群落细根现存生物量存在一定的差异,其中白桦林最高,月平均细根现存生物量为5.1340 t/hm^2、其次为云冷杉林（5.0530 t/hm^2）、岳桦林（4.9255 t/hm^2）、阔叶红松林（4.4919 t/hm^2）和山杨林（3.9372 t/hm^2）;不同群落细根现存量月动态变化也有较大差异,月均最高最低相差阔叶红松林约为72﹪、白桦林近73﹪、山杨林26﹪、云冷杉林56﹪、岳桦林144﹪.在生长季节内不同群落细根发生和死亡也是不均匀的,春季所有群落都会产生大量的细根,一些群落在初秋（9月份）出现另一个较高的峰值,同时发现每次细根大量发生后,都随之产生大量细根的死亡,生长季末群落死亡细根生物量往往是最高的.调查群落72.9﹪以上的细根集中于土壤表层0～10cm的范围内,不同群落略有差别,在所研究的5种森林群落中,不同月份0～10cm土层中细根生物量几乎都表现出白桦林＞阔叶红松林＞云冷杉林＞岳桦林＞山杨林.     

鼎湖山南亚热带森林细根生产力与周转

 报道了鼎湖山季风常绿阔叶林和针阔叶混交林群落0～40cm土层中细根(≤2mm和2～5mm)的现存量、死亡量、生产力和周转率,并比较了用“连续钻取土芯法”和“埋无根土柱法”来估算表层土(0～20cm)细根生产力的差异。结果表明：在0～40cm土层中,季风常绿阔叶林≤2mm和2～5mm细根现存量分别为6.59t·hm-2和4.81t·hm-2,死根比率各为29.9％和22.9％;针阔叶混交林≤2mm和2～5mm细根现存量分别为5.35t·hm-2和4.24t·hm-2,死根比率各为34.4％和24.0％。细根现存量的季节性变化不显著。季风常绿阔叶林细根年分解量、年死亡量和年净生产力分别为0.90,1.59,2.65t·hm-2·a-1 (≤2mm)和0.41,0.63,1.25t·hm-2·a-1(2～5mm),针阔叶混交林的相应数值各为0.80,1.4l,2.42t·hm-2·a-1(≤2mm)和0.37,0.62,1.21t·hm-2·a-1(2～5mm)。季风常绿阔叶林细根年周转率为0.57 (≤2mm)和0.34次·a-1(2～5mm),针阔叶混交林分别为0.69(≤2mm)和0.38次·a-1(2～5mm)。     

帽儿山温带落叶阔叶林细根生物量、生产力和周转率

细根在森林生态系统能量流动与物质循环中占有重要地位,但其生物量、生产和周转测定尚存在很大的不确定性,而且局域尺度空间变异机制尚不清楚。本研究分析了帽儿山温带天然次生林活细根生物量和死细根生物量在0～100 cm剖面的垂直分布与0～20 cm细根的季节动态、生产力和周转率,对比了采用连续根钻法(包括决策矩阵法和极差法)和内生长袋(直径3和5 cm)估测细根生产力和细根周转率,并探讨了可能影响细根的林分因子。结果表明: 76.8%的活细根生物量和62.9%的死细根生物量均集中在0～20 cm土层,随着深度增加,二者均呈指数形式减少。活细根生物量和死细根生物量的季节变化不显著,可能与冬季几乎无降雪而夏季降雨异常多有关。2种直径内生长袋估计的细根生产力无显著差异;对数转换后决策矩阵、极差法和内生长法估计的细根生产力和细根周转率差异显著。随着土壤养分增加,活细根生物量和死细根生物量比值显著增加,死细根生物量显著减少,但活细根生物量、细根生产力和细根周转率均无显著变化;细根周转率与前一年地上木质生物量增长量呈显著正相关,但与当年地上木质生物量增长量无显著相关关系。     

伪潜育土季节性滞水条件下大冷杉毫根动态的研究(Abies grandis Lindl.)

本文对一个25年生大冷杉林在伪潜育土至45cm矿质土壤里,从1987年晚秋滞水期至1988年生长旺盛期的毫根量动态及化学组成变化进行了研究。 滞水期土壤中死根量(5558kg DS/ha)显著高于活根量(3594kg DS/ha)。生长旺盛期初,活根量增加约50％,死根量降低约27％。经过夏季至生长旺盛期末,活根量仍略有增加,死根量继续降低。毫根化学组成分析显示,滞水期活根中K、Mg及Zn离子含量显著低于生长旺盛期,Mn离子含量则明显高于生长旺盛期。这一结果表明,除了与季节性相关的生长节奏因素外,大冷杉毫根生物量的变化主要是由滞水状况所致。     

伪潜育土季节性滞水条件下大冷杉(Abies grandis Lindl.)毫根动态的研究

本文对一个25年生大冷杉林在伪潜育土至45cm矿质土壤里,从1987年晚秋滞水期至1988年生长旺盛期的毫根量动态及化学组成变化进行了研究。滞水期土壤中死根量(5558kg Ds／ha)显著高于活根量(3594kg DS／ha)。生长旺盛期初,括根量增加约50％,死根量降低约27％。经过夏季至生长旺盛期末,活根量仍略有增加,死根量继续降低。毫根化学组成分析显示,滞水期活根中K、Mg及Zn九离子含量显著低于生长旺盛期,Mn离子含量则明显高于生长旺盛期。这一结果表明,除了与季节性相关的生长节奏因素外,大冷杉毫根生物量的变化主要是由滞水状况所致。     

Relationships among root branch order, carbon, and nitrogen in four temperate species

The objective of this study was to examine how root length, diameter, specific root length, and root carbon and nitrogen concentrations were related to root branching patterns. The branching root systems of two temperate tree species, Acer saccharum Marsh. and Fraxinus americana L., and two perennial herbs from horizontal rhizomes, Hydrophyllum canadense L. and Viola pubescens Ait., were quantified by dissecting entire root systems collected from the understory of an A. saccharum-Fagus grandifolia Ehrh. forest. The root systems of each species grew according to a simple branching process, with laterals emerging from the main roots some distance behind the tip. Root systems normally consisted of only 4–6 branches (orders). Root diameter, length, and number of branches declined with increasing order and there were significant differences among species. Specific root length increased with order in all species. Nitrogen concentration increased with order in the trees, but remained constant in the perennial herbs. More than 75% of the cumulative root length of tree seedling root systems was accounted for by short (2–10 mm) lateral roots almost always <0.3 mm in diameter. Simple assumptions suggest that many tree roots normally considered part of the dynamic fine-root pool (e.g., all roots <2.0 mm in diameter) are too large to exhibit rapid rates of production and mortality. The smallest tree roots may be the least expensive to construct but the most expensive to maintain based on an increase in N concentration with order. Received: 25 November 1996 / Accepted: 27 March 1997     

Mycorrhizae and forest ecosystems

Summary Mycorrhizae play an important role in regulating patterns of energy and nutrient flux in terrestrial ecosystems. To conceptualize this role I develop the theory behind a simple index of the efficiency of soil resource acquisition by plant root systems (E). The morphological, physiological and demographic characteristics of mycorrhizae that define E appear to vary with environment and with plant community composition. This theory is elaborated with examples drawn from forest ecology literature. Some inconsistencies among observations of fine root dynamics are particularly revealing: (1) belowground carbon allocation vs soil fertility; (2) causes of root mortality; (3) root longevity vs decomposition rates. A comprehensive theory of mycorrhizal and ecosystem dynamics must await resolution of these inconsistencies and better quantitative information on mycorrhizal features affecting E.     

Fine root production of astringent phenolics

Summary Chemical quality of fine roots (<1 mm diameter) was determined over a gradient of species composition in the Mixed Mesophytic Forest Region. Ash-free nitrogen, calcium, and phosphorus concentrations of roots declined by 49, 41, and 72%, respectively, over a gradient of increasing soil acidity (pH 5.3 to 4.7). Lignin concentration was unrelated to either the vegetation gradient or any of the soil changes it encompassed; however, astringent phenolics increased by 275% over the same gradient. Trends in the chemical constituency of fine roots suggest that the production of phenolics in below-ground plant parts is increased on nutrient-poor sites. This response is best related to changes in species composition, especially increasing importancy of Quercus spp.This investigation (No. 88-8-36) is connected with a project of the Kentucky Agricultural Experiment Station and is published with the approval of the Director     

Biomass and production of fine and coarse roots during regrowth of a disturbed subtropical humid forest in north-east India

Seasonal variation and depthwise distribution of dry matter in roots of different diameter classes and their annual production were studied using sequential core sampling. The investigations were carried out in three stands of a subtropical humid forest of north-east India representing different stages of regrowth after tree cutting. The mean annual standing crop of fine (<2 mm in diameter) and coarse (2–15 mm diameter) roots increased gradually from 5.4 Mg ha^-1 and 0.7 Mg ha^-1 in 7-yr old regrowth to 9.4 Mg ha^-1 and 2.8 Mg ha^-1 in 16-yr old regrowth, respectively. The contribution of fine roots to the total root mass declined from 88% in 7-yr old regrowth to 77% in both 13 and 16-yr old regrowths, while that of coarse roots increased from 12 to 23%. A major portion of fine roots (59–62%) was present in 0–10 cm soil layer, but the coarse roots were concentrated in 10–20 cm soil depth (38–48%). In all the three stands, biomass of both fine and coarse roots followed a unimodal growth curve by showing a gradual increase from spring/pre-rainy season to autumn/post-rainy season. Biomass to necromass ratio increased from 2.5 in the 7-yr old to 3.2 in the 16-yr old stand. The annual fine root production increased from 5.9 Mg ha^-1 to 7.7 Mg ha^-1 and total root production from 7.6 Mg ha^-1 to 14.7 Mg ha^-1 from 7-yr to 16-yr old regrowth.     

A 15N tracer technique for assessing fine root production and mortality

We tested a ¹⁵N tracer technique to assess fine root production and mortality based on temporal measurements of the ¹⁵N mass in fine root structural tissues and the ¹⁵N concentration of the plant-available soil N pool. The results of a pilot study indicated that this technique is based on sound methods and reasonable assumptions. The ¹⁵N tracer technique avoids most of the major limitations which hinder existing methods and may provide valuable insight into the rates and controls of fine root production and mortality in terrestrial ecosystems. Received: 23 September 1996 / Accepted: 10 June 1997     

Quantitative determination of callose in tree roots

The formation of callose in tree roots has been suggested as a physiological indicator of aluminum (Al) toxicity. Quantifying callose in the roots in forest soils, however, is hampered by the presence of autofluorescent materials in the roots that disturb the measurement of callose by fluorescence spectrophotometry. Tannins in the roots cause these measurement problems. Here we report on the measurement of callose in the root apices of European chestnut (Castanea sativa) seedlings collected in an acidified forest soil. The callose was quantified with a modified protocol which included three washing steps with polyvinylpolypyrrolidone (PVPP) before the callose was extracted. This procedure reduced the autofluorescence by about 50%. With the use of water or ethanol alone, callose could be measured in only about 15% of the root samples, whereas with the use of PVPP callose could be determined in 95% of the samples. This improved method could help to evaluate the effects of Al toxicity on tree roots grown in forest soils, where callose is detected as a physiological indicator.     

Production of fine roots and the seasonality of their growth in a Mexican deciduous dry forest

Very limited information regarding fine-root growth and production of tropical dry forests is available. Fine roots and small roots are defined as rootlets with diameters < 1 mm and 1.1 to 5 mm, respectively. Live and dead fine-and small-root mass fluctuations were studied over one year by means of soil core analyses in the deciduous dry forest of Chamela, Mexico, at 19° 30, 2 km inland from the Pacific Ocean. By means of systematically varying the distance of soil core extraction points from tree stems, it was shown that random core collection is justified. A difference between fine-root biomass on south and north facing slopes was documented, although this difference was significant only during the rainy season. The live/dead ratio of fine roots was highest during the rainy period. The annual fine-root production for 1989 was estimated at 4.23 Mg ha^-1 by summing significant fine-root biomass changes between sampling dates. This value is higher than most of the comparable data from other ecosystems.     

Litterfall and fine root biomass contribution to nutrient dynamics in second- and old-growth Douglas-fir ecosystems

Litterfall and fine root production were measured for three years as part of a carbon balance study of three forest stands in the Pacific Northwest of the United States. A young second-growth Douglas-fir [Pseudotsuga menziesii (Mirb.) Franco] stand, a second-growth Douglas-fir with red alder (Alnus rubra Bong.) stand, and an old-growth (∼550 years) Douglas-fir stand were monitored for inputs of carbon and nitrogen into the soil from litterfall and fine root production, as well as changes in soil C and N. Fine root production and soil nutrient changes were measured through the use of soil ingrowth bags containing homogenized soil from the respective stands. Litterfall biomass was greatest in the Douglas-fir-alder stand (527 g m⁻² yr⁻¹) that annually returned nearly three times the amount of N as the other stands. Mean residence time for forest floor material was also shortest at this site averaging 4.6 years and 5.5 years for C an N, respectively. Fine root production in the upper 20 cm ranged from 584 g m⁻² in the N rich Douglas-fir-alder stand to 836 g m⁻² in the old-growth stand. Fine root production (down to one meter) was always greater than litterfall with a below:above ratio ranging from 3.73 for the young Douglas-fir stand to 1.62 for the Douglas-fir-alder stand. The below:above N ratios for all three stands closely approximate those for biomass. Soil changes in both C and N differed by site, but the soil C changes in the old-growth stand mirrored those obtained in an ongoing CO₂ flux study. Results from the soil ingrowth bags strongly suggest that this method provides a simple, but sufficient device for measuring potential fine root biomass production as well as soil chemical changes.