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1.
杨树细根及草根的生产力与周转的研究   总被引:25,自引:4,他引:21  
对北方杨树人工林0-40cm土层中杨树细根和草根(≤2mm)年生物量、分解量、死亡量、生长量和周转率进行观察研究。结果表明,杨树细根的年生物量为2.062t.hm^-2,死根生物量为0.746t.hm^-2,分解量为0.158t.hm^2,生长量为2.351t.hm^-2,周转率为每年1.14次,活草根的年生物量、死根生物量、分解量、生长量和周转率分别0.501、0.035、0.023、0.691t.hm^-2和1.38,同时给出了杨树细根干重损失随分解时间变化的方程:1nx/x0=0.9515e^-0.0014t。  相似文献   

2.
研究杨树人工林1~5级根序细根内碳、氮及非结构性碳水化合物含量的季节动态,对比了杨树细根碳氮分配格局的代际差异,以期建立细根生长和功能变化与连作人工林生产力衰退的联系.结果表明: 杨树细根非结构性碳水化合物(NSC)随根序显著增加,而氮含量显著减少.细根中全C和NSC含量与全N存在显著相关性.细根碳氮含量的变化在根序间的解释量占98.2%,而在代际间仅为1.7%.杨树不同根序细根均在生长季具有较高的碳含量和较低的氮含量,且碳、氮及NSC含量在代际间随季节差异显著,但C∶N差异不显著,根序与季节对细根碳氮含量存在显著交互效应.杨树低级细根C∶N约为20∶1,高级根则大于30∶1.细根C∶N在生长季(7和9月)显著低于其他季节,NSC含量在11月最高.连作人工林杨树细根的碳氮分配格局与细根根序具有较强的耦合性,NSC和C∶N在指示细根周转和调控细根季节性生长中具有重要生态学意义.  相似文献   

3.
连作杨树人工林细根寿命的代际差异及其影响因素   总被引:1,自引:0,他引:1  
细根寿命是调控森林生产力形成的关键。通过在连作Ⅰ、Ⅱ代杨树人工林固定样地内埋设微根管,对杨树不同根序细根年度生长动态开展连续观测并进行生存分析。结果表明,杨树不同根序细根累积生存率存在显著差异,高级根(3—5级)寿命较长,其累积生存率显著高于1级和2级细根。杨树细根寿命存在显著的代际差异,连作Ⅱ代人工林活根量、死根量和细根总量均高于Ⅰ代林。连作Ⅱ代人工林细根中位值寿命为(90±16)d,显著低于Ⅰ代人工林((102±22)d)。连作Ⅱ代林各根序细根数量、分布比例均高于Ⅰ代林,低级细根累积生存率低于Ⅰ代林而高级细根累积生存率显著高于Ⅰ代林。连作杨树人工林细根寿命显著受制于土壤环境,1级细根寿命与土壤速效氮相关性极显著(r=-0.861),2级细根寿命与土壤物理性状相关性较强且与土壤酚酸含量呈现极显著相关(r=0.870),高级根序细根寿命与土壤物理性质和养分状况等也具有一定相关性。连作杨树人工林土壤酚酸累积和养分有效性下降影响了细根寿命和周转,并进而造成净初级生产力损耗,相关结论为连作杨树人工林生产力衰退机理模型的建立提供了科学依据。  相似文献   

4.
采集欧美杨107Ⅰ代和Ⅱ代人工林细根样品,分析杨树不同根序细根数量特征(根长度、表面积和生物量)和形态特征(比根长、根长密度、根组织密度)对季节波动的响应及其代际差异.结果表明: 杨树各根序细根数量特征(根长度、表面积和生物量)均呈明显的季节变化,且具有明显的根序差异性.低级根序细根数量特征季节差异显著,细根生物量在生长季显著增加而生长季后显著下降.高级根序细根比根长季节波动显著,而根长密度和根组织密度等形态特征波动较小.连作导致人工林杨树1~2级细根长度、生物量、比根长和根长密度在生长季显著增大.1级细根数量特征与土壤温湿度呈显著正相关,与土壤有机质和速效氮含量呈显著负相关;而2级细根数量特征仅与土壤养分显著相关.杨树人工林细根特征的季节动态及代际差异体现了杨树对细根的碳投入变化,因连作引发的土壤养分匮乏可能引发植株对根系的碳投入增加,这种碳分配格局与人工林地上部分生产力形成密切相关.  相似文献   

5.
水曲柳根系生物量、比根长和根长密度的分布格局   总被引:42,自引:3,他引:39  
采用连续钻取土芯法在生长季内对东北林业大学帽儿山实验林场17年生水曲柳人工林根系取样,研究水曲柳不同直径根系现存生物量、比根长和根长密度及垂直分布状况.结果表明,水曲柳人工林根系总生物量为1 637.6 g·m-2,其中活根生物量占85%,死根占15%.在活根生物量当中,粗根(直径5~30 mm)占的比例最高(69.95%),其次为活细根(直径<1 mm,13.53%),小根(1~2 mm)和中等直径的根(2~5 mm)比例较小(分别为7.21%和9.31%).直径<1 mm活细根的比根长为32.20 m·g-1,直径5~30 mm粗根的比根长为0.08 m·g-1.单位面积上活根的总长度为6 602.54 m·m-2,其中直径<1 mm的细根占92.43%,其它直径等级则不到活根总长度的8%.直径<1 mm的细根生物量与根长密度具显著线性关系(R2=0.923),但与比根长无显著相关关系(R2=0.134).  相似文献   

6.
拉萨河谷杨树人工林细根的生产力及其周转   总被引:6,自引:0,他引:6  
通过土钻取样和分解袋法对拉萨河谷杨树人工林细根的生长和周转进行了测定.结果表明,在该地区杨树人工林生态系统中,约80%的细根集中分布在0~30cm土壤表层中;接近树木一侧的活(死)细根生物量均高于外侧,但二者未达到显著的差异;在生长季期间,活细根生物量平均为2.576 t · hm-2,死细根生物量平均为1.566 t · hm-2,生长高峰出现在生长季初期.经估算,拉萨河谷杨树人工林细根年生长量为3.030 t · hm-2,年周转率为1.18次;但受高原低温的影响,细根分解缓慢,分解系数k平均为0.0007~0.0008.细根的这种生长特征是杨树对高原地区短暂生长季节和雨热同季气候条件的一种适应性表现.  相似文献   

7.
长白山高山冻原植被生物量的分布规律   总被引:7,自引:1,他引:6  
魏晶  吴钢  邓红兵 《应用生态学报》2004,15(11):1999-2004
从物种生物量、优势种器官生物量和植被生物量角度,探讨了长白山高山冻原生态系统生物量的空间变化规律.结果表明,在调查的43种长白山高山冻原植物中,单物种生物量排序前5种植物分别是牛皮杜鹃(Rhododendron chrysanthum)(159.01kg·hm^-2)、笃斯越桔(Vaccinium jiliginosum var.alpinum)(137.52kg·hm^-2)、高山笃斯(Vaccinium uliginosum)(134.7kg·hm^-2)、宽叶仙女木(Dryas octopetala var.asiatica)(131.5kg·hm^-2)圆叶柳(Salix rotundifolia)(128.4kg·hm^-2).它们是长白山高山冻原生态系统的优势种.地下与地上生物量和地下与总生物量之比随海拔升高逐渐增加.植被生物量随海拔升高。总体呈逐渐减小的趋势。植被生物量与海拔高度呈显著负相关.长白山高山冻原生态系统平均生物量为2.21t·hm^-2,对调节长白山小气候、涵养水源、水土保持等生态服务功能的发挥有着重要的作用。同时对固定大气CO2起着汇的作用。  相似文献   

8.
树木细根生长与根际过程的关系十分密切。该研究仿生欧美杨107(Populus×euramericana‘Neva’)人工林根际土壤酚酸沉降与氮素有效性变化,通过设置3种酚酸梯度(0X、0.5X、1.0X,X为田间土壤酚酸含量)与3种氮素水平(缺氮0 mmol·L~(–1)、正常氮10 mmol·L~(–1)、高氮20 mmol·L~(–1)),探究酚酸和氮素对欧美杨107细根形态的影响,以期为阐明树木根系生长对根-土界面过程的响应奠定基础。结果表明:(1)在无酚酸(0X)环境中,缺氮和高氮均可抑制欧美杨107细根生长,尤其对1–3级细根的影响更为显著。比根长随氮素水平升高逐渐减小,但其他细根特征并未呈现与氮素水平的线性关系。(2)0.5X和1.0X酚酸梯度相比,欧美杨107的1–2级细根直径和体积随酚酸浓度增加而显著增大(p0.05)。酚酸和氮素对杨树细根的影响存在交互作用,1–2级细根直径、体积受酚酸的影响显著,而4–5级细根长度、表面积受氮素影响显著。双因素方差分析结果表明,酚酸和氮素对细根形态建成具有协同或拮抗效应。(3)主成分分析(PCA)和冗余分析(RDA)结果表明,在酚酸和氮素交互效应下,杨树1–3级、4级、5级细根之间具有显著的形态差异。第一主成分主要体现细根觅食性状特征,可解释细根形态变异的60.9%的信息;第二主成分主要体现细根形态构建特征,可解释25.3%的信息。杨树细根形态变化与根序高度相关,N素影响杨树细根形态的主效应较酚酸更强。因此,根际环境中酚酸累积和氮素有效性变化会影响杨树细根的形态构建和细根对水分、养分的吸收,而氮素有效性是影响杨树细根生长的重要因素,开展杨树人工林土壤养分管理是林分生产力长期维持的关键。  相似文献   

9.
黄土高原地区紫花苜蓿生长过程中土壤养分的变化规律   总被引:18,自引:0,他引:18  
以不同生长年限的苜蓿地为材料,研究了苜蓿在生长过程中土壤养分的变化趋势。结果表明:在苜蓿生长年限10~23a内,随着种植时间延长苜蓿生物量和体内养分累积量呈下降趋势。23a生苜蓿已进入衰败期,土壤肥力逐渐得到恢复,苜蓿根系养分含量随种植年限延长呈明显的增加趋势。不同生长年限苜蓿地土壤NO3ˉN的含量变化趋势相同,2m以内土层生长年限越短。NO3ˉ-N含量越少,2m以下变化趋势相反。NH4^ -N含量变化规律不明显,表层高于下层,生长年限长的含量较低。  相似文献   

10.
韩畅  宋敏  杜虎  曾馥平  彭晚霞  王华  陈莉  苏樑 《生态学报》2017,37(7):2282-2289
为了解不同林龄杉木、马尾松人工林地地下根系生物量及碳储量特征,以广西杉木、马尾松主产区5个不同林龄阶段(幼龄林、中龄林、近熟林、成熟林、过熟林)的人工林为研究对象,采用全根挖掘法和土钻法获取标准木根系生物量、灌草根系生物量和林分细根生物量,并测定其碳含量,分析其不同林龄阶段地下根系生物量和碳储量分配特征。结果表明:杉木、马尾松林地下根系总生物量分别在9.06—31.40Mg/hm~2和7.91—53.40Mg/hm~2之间,各林龄阶段根系总生物量总体上呈现随林龄增加而增加的趋势,杉木林细根生物量随林龄的增加呈现出先减后增的趋势,马尾松呈现出逐渐减小的趋势;林分各层次根系碳含量表现为乔木灌木草本、细根;杉木、马尾松地下根系碳储量变化趋势与生物量变化趋势相同,杉木、马尾松林不同林龄阶段各层次根系和土壤细根总碳储量分别在7.56—21.97Mg/hm~2和8.86—29.95Mg/hm~2之间;地下根系碳储量总体上以乔木根系占优势,且随林龄的增大其比例呈增加的趋势。  相似文献   

11.
2010年11月-2011年12月, 研究了华西雨屏区31年生香樟人工林土壤表层(0~30 cm)细根生物量及碳储量.结果表明: 香樟人工林土壤0~30 cm层细根总生物量(活根+死根)和碳储量的平均值分别为1592.29 kg·hm-2和660.68 kg C·hm-2,其中活细根贡献率分别为91.1%和91.8%.随着土壤深度的增加,香樟1~5级活细根和死细根的生物量及碳储量均显著减少;随着根序等级的升高,香樟活细根生物量及碳储量显著增加.香樟细根总生物量及碳储量均在秋季最高、冬季最低,死细根生物量及碳储量为冬季最高、夏季最低;1级根和2级根生物量及碳储量均在夏季最高、冬季最低,而3~5级根则为秋季最高、冬季最低.土壤养分和水分的空间异质性是导致细根生物量和碳储量变化的主要原因.  相似文献   

12.
Both resource and disturbance controls have been invoked to explain tree persistence among grasses in savannas. Here we determine the extent to which competition for available resources restricts the rooting depth of both grasses and trees, and how this may influence nutrient cycling under an infrequently burned savanna near Darwin, Australia. We sampled fine roots <2 mm in diameter from 24 soil pits under perennial as well as annual grasses and three levels of canopy cover. The relative proportion of C3 (trees) and C4 (grasses) derived carbon in a sample was determined using mass balance calculations. Our results show that regardless of the type of grass both tree and grass roots are concentrated in the top 20 cm of the soil. While trees have greater root production and contribute more fine root biomass grass roots contribute a disproportional amount of nitrogen and carbon to the soil relative to total root biomass. We postulate that grasses maintain soil nutrient pools and provide biomass for regular fires that prevent forest trees from establishing while savanna trees, are important for increasing soil N content, cycling and mineralization rates. We put forward our ideas as a hypothesis of resource‐regulated tree–grass coexistence in tropical savannas.  相似文献   

13.
细根能敏感地感知土壤环境变化,对植物生长发育具有重要影响.以6年生翅荚木人工林为对象,对其不同径阶的细根主要功能性状与根际土壤养分特征及两者间关系进行分析.结果表明:细根生物量、根长密度与根体积密度均随径阶增加而增加,比根长与比根面积则随径阶增加呈先升高再下降后升高的趋势,根组织密度则与径阶大小不相关.不同径阶翅荚木根际土壤的pH值及含水率、全碳、全磷、铵态氮、硝态氮和总有效氮含量均存在显著差异,大径阶林木的根际土壤全碳、全氮、硝态氮、总有效氮含量相对较高,小径阶林木的根际土壤含水率、土壤全磷、铵态氮含量相对较高.土壤全氮、全碳、硝态氮和总有效氮含量与林木细根的生物量、根长密度、根体积密度呈显著正相关;土壤全磷与林木细根的根组织密度呈显著正相关,与比根长、比根面积呈显著负相关;土壤含水率与林木细根的生物量和根体积密度均呈显著正相关;根际土壤pH和林木细根的比根长、比根面积呈显著正相关,与根组织密度则呈显著负相关.研究结果可为翅荚木优良种质资源选育提供科学依据.  相似文献   

14.
《植物生态学报》2015,39(8):825
Aims Irrigation and fertilization have great potentials to enhance yield in forest plantations. The integrated effect of water and nitrogen management on fine roots morphology and distribution of Populus × euramericana ‘Guariento’, however, remains unclear. The objective of this study was to evaluate the effect of water and nitrogen addition on fine root morphology and distribution in poplar plantations for developing the best water and nitrogen strategy for promoting fine root. Methods The soil core method was used to quantify the morphology and distribution of fine roots in the 0–60 cm in a poplar plantation with surface dripping irrigation and fertilization technologies. The experiment included nine treatments, which were a combination of three irrigation treatments where dripping irrigation was applied when soil water potential (ψsoil) reached –75, –50, or –25 kPa, and three fertilization treatments at nitrogen additions of 150, 300, or 450 g·tree–1·a–1, respectively). A control plot with non-irrigation and non-fertilizationtreatment in growing season (CK) was also included in the study. Important findings The fine roots biomass density, fine root surface area density, average root diameter in all treatments were mainly found at 0–10 cm and 10–20 cm depths, with root biomass density in the 10–20 cm of 1.03 to 1.21 times of that in the 0–10 cm, 1.25 to 1.80 times of that in the 20–30 cm, 1.62 to 22.10 times of that in the 30–40 cm, 2.77 to 54.35 times of that in the 40–50 cm, and 6.48 to 293.09 times of that in the 50–60 cm. The root biomass density in the 10–20 cm accounted for 27%–37% of the total biomass density in the top 60 cm. For root biomass density and average diameter, there were no significant differences between 0–10 cm and 10–20 cm depths, and between 40–50 cm and 50–60 cm depths. Fine roots in the irrigation and fertilization treatments were significantly higher than that of the CK, except the D1F1 treatment (i.e., with low water and low nitrogen level). Additionally, fine roots in the D2F3 treatment (i.e., with intermedia irrigation and high nitrogen level) and the D3F3 treatment (i.e., with high water and high nitrogen level) were significantly higher than those in other treatments, but not significantly different between D2F3 and D3F3. Compared with the CK, the fine roots biomass density in six soil layers were significantly enhanced at 359%, 388%, 328%, 3823%, 4774% and 2866%, respectively, for the treatment with high water and high nitrogen levels. The vertical distributions of fine roots appeared not affected by the interaction of irrigation and nitrogen addition. However, the surface dripping irrigation and fertilization treatments increased fine roots significantly. Finally, we found that the response of fine root growth and distribution was stronger to fertilization than to the irrigation in this poplar plantation.  相似文献   

15.
《植物生态学报》2015,39(12):1198
Aims The relationship between rhizosphere process and fine root growth is very close but still obscure. In poplar plantation, phenolic acid rhizodeposition and soil nutrient availability were considered as two dominant factors of forest productivity decline. It is very hard to separate them in the field and they might show an interactive effect on fine root growth. The objective of this study is to examine the influence of phenolic acids and nitrogen on branch orders of poplar fine roots and to give a deeper insight into how the ecological process on root-soil interface affected fine root growth as well as plantation productivity. Methods The cuttings of health annual poplar seedlings (I-107, Populus × euramericana ‘Neva’) serve as experiment materials, and were cultivated under nine conditions, including three concentration of phenolic acids at 0X, 0.5X, 1.0X (here, X represented the contents of phenolic acids in the soil of poplar plantation) and three concentration of nitrogen at 0 mmol·L-1, 10 mmol·L-1, 20 mmol·L-1, based on Hoagland solution. The roots were all separated from poplar seedlings after 35 days, and 30 percent of total fine roots of every treatment were taken as fine root samples. These fine roots were grouped according to 1 to 5 branch orders, and then the morphological traits of each group of fine roots were scanned via root analyzer system (WinRHIZO, Regent Instruments Company, Quebec, Canada) including total length, surface area, volume and average diameter. Meanwhile, the dry mass of fine root samples of every order was measured to calculate specific root length (SRL), root tissue density (RTD). All data were analyzed via SPSS 17.0 software, and interactive effect of phenolic acids and nitrogen on roots was analyzed through univariate process module. Principal component analysis (PCA) and redundancy analysis (RDA) were conducted via Canoco 4.5 software. Important findings Under the conditions without phenolic acids application, the fine roots growth was significantly inhibited in deficiency and higher nitrogen treatments, especially for 1-3 order roots. Only specific root length appeared decreased with nitrogen level, and other traits of fine roots did not demonstrate linear relationship with nitrogen concentrations. Compared to 0.5X phenolic acids treatment, 1.0X phenolic acids significantly promoted the diameter and volume of 1-2 order roots (p < 0.05). Both phenolic acids and nitrogen demonstrated influence on poplar fine root traits. However, the diameter and volume of 1-2 order roots were significantly affected by phenolic acids, while the total length and surface area of 4-5 order roots was affected by nitrogen. Two way ANOVA showed that phenolic acids and nitrogen made a synergistic or antagonistic effect on morphological building of fine roots. Furthermore, PCA and RDA indicated that the interactive effects of phenolic acids and nitrogen led to significant differences among 1-3 order, 4th order and 5th order of poplar fine roots. The PC1 explained about 60.9 percent of root morphological variance, which was related to foraging traits of roots. The PC2 explained 25.3 percent of variance, which was related to root building properties. The response of poplar roots to phenolic acids and nitrogen was closely related to root order, and nitrogen played more influence on poplar roots than phenolic acids. Thus, phenolic acids and nitrogen level would affect many properties of root morphology and foraging in rhizosphere soil of poplar plantation. But nitrogen availability would serve as a dominant factor influencing root growth, and soil nutrient management should be critical to productivity maintenance of poplar plantation.  相似文献   

16.
Summary Nitrogen cycling was studied during the third growing season in pure and mixed plantings (33×33 cm spacing) of hybrid poplar and black alder in southeastern Canada. After 3 years, hybrid poplar growth and N content of living tissues in a plot and of individual hybrid poplar plants increased with the proportion of black alder in a planting. No differences were detected among N contents of individual alder plants regardless of plot treatment. Black alder allocated a larger portion of its N to roots than hybrid poplar. Symbiotic nitrogen fixation was estimated to account for 80% of the nitrogen in aboveground alder tissues in the pure treatment using natural15N dilution. N return in leaf litter was estimated to be 70kg ha–1 in the pure alder treatment and decreased to a minimum of 20 kg ha–1 in the pure hybrid poplar plots. No difference was detected among treatments for throughfall N content. Nitrogen concentration in roots and leaf litterfall of black alder was higher than hybrid poplar. Significant soil N accretion occurred in mixed plantings containing two alders to one poplar and pure black alder plantings. Nitrogen availability (NO3–N) increased with the amount of black alder in a plot. Results suggest that the early increase in nitrogen accumulation of hybrid poplar in mixed treatments can be attributed to an increase of total soil N availability resulting from the input of large amounts of N from easily mineralizable alder tissue.  相似文献   

17.
To study the responses of forests to global change, model ecosystems consisting of beech and spruce trees were maintained in open top chambers for 4 years under four conditions, namely with normal and elevated CO2 and with low and high nitrogen input, each replicated four times. Each open top chamber (height 3 m, diameter 3 m, soil depth 1.5 m) contained two separate soil compartments containing nutrient-poor siliceous and nutrient-rich calcareous soil. Here, we focus on the fine roots and the soil microbial community in these model ecosystems. At the time of planting, the fine roots were cut back according to forestry practice, and the newly formed roots were colonized by the indigenous soil microflora. After 4 years, the total biomass of fine roots, when averaged over all treatments, was almost the same in each of the two soil types; it was highest in the top 100 mm of soil (60%) and decreased sharply in deeper soil layers. Fungal biomass associated with the fine roots, consisting mainly of ectomycorrhizal fungi, was estimated using the ergosterol content as a marker. It was much higher in fine roots in the siliceous than in the calcareous soil, indicating considerably enhanced ectomycorrhiza formation in the nutrient-poor siliceous soil. Elevated atmospheric CO2 stimulated fine root production by ca. 85% and 43% in the top 100 mm of calcareous and siliceous soils respectively. Increased nitrogen input caused a slightly reduced production of fine root biomass in the calcareous soil but increased it by 33% in the siliceous soil. Marker substances for microorganisms were analyzed in the root-free soil. The amounts of carbon released by fumigation/extraction (a general marker for microbial biomass) and chitin (a marker for fungal biomass) were significantly higher in the top layer of the siliceous than of the calcareous soil, but they did not respond significantly to the treatments with elevated CO2 or the nitrogen fertilizer. The total concentration of the phospholipid fatty acids (PLFAs) and the number of the PLFAs did not differ between the two soil types. However, four of the eight most abundant PLFAs differed significantly between the two soil types. Principal component analysis revealed clearly separated clusters for the two soil types. Although analysis did not reveal any significant changes in response to the treatments, the concentration of the PLFA typical for ectomycorrhizal fungi was significantly higher under conditions of elevated CO2 in the nutrient-rich calcareous soil.  相似文献   

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