毛乌素沙地杨柴灌木林恢复演替过程中土壤活性有机碳组分变化特征

土壤活性有机碳是土壤有机碳(SOC)的活性部分,是衡量土壤质量和健康状况的重要指标,能够反映植被恢复演替过程中土壤环境的早期变化。但在SOC贫瘠的沙地,长期恢复演替如何影响土壤活性有机碳组分尚不清楚。本研究以毛乌素沙地杨柴人工灌木林为研究对象,分别选取未造林(CK)与造林年限9 a、18 a和30 a的杨柴人工灌木林,探究毛乌素沙地杨柴人工灌木林恢复演替过程中土壤可溶性有机碳(DOC)、微生物量碳(MBC)、易氧化有机碳(ROC)和SOC变化规律。结果表明：(1)毛乌素沙地杨柴灌木林随恢复演替年限增加土壤固碳能力增强,但在恢复演替18 a时出现转折点,恢复演替18—30 a时土壤固碳速率相对减缓;(2)表层0—10 cm土壤DOC、MBC和ROC对恢复演替响应较为敏感,恢复演替过程中表层土壤活性有机碳各组分含量逐渐升高;(3)恢复演替年限并未对土壤活性有机碳占SOC比例产生显著影响,同时也未显著改变碳库活度。综上所述,毛乌素沙地杨柴灌木林恢复演替有助于土壤活性有机碳和SOC积累,但长期恢复演替是否持续对土壤活性有机碳固持产生积极作用仍需进一步研究。     

气候、植被及土壤因素交互作用对宁夏土壤有机碳的影响机制

基于宁夏全区121个土壤剖面样点,研究不同深度(0—30、30—80、80—120cm)土壤有机碳的空间分布特征,通过相关性、方差分解和构建结构方程模型,分析气候、植被和土壤因素对宁夏不同深度土壤有机碳的影响及其作用途径。结果表明：(1)宁夏不同深度土壤有机碳含量均呈现中间低南北高的空间分布趋势,0—120cm剖面土壤有机碳含量随着土壤深度的增加而降低,土壤有机碳含量均值为5.49g/kg,变异系数达90.71%,含量偏低且空间异质性强。(2)各土层土壤有机碳与年均气温、干燥度、碳酸钙、pH均呈现极显著的负相关性(P<0.01),与年均降水量、相对湿度、植被净初级生产力、全氮、全磷、全钾、钙离子、阳离子交换量、粘粒含量均呈现极显著的正相关性(P<0.01)。(3)各因素对不同土层土壤有机碳的作用方式和影响程度有差异。土壤全氮、全磷、碳酸钙、阳离子交换量均能直接影响土壤有机碳,年均气温和植被净初级生产力对土壤有机碳的直接影响效应不显著,主要通过土壤属性间接影响土壤有机碳含量。随着土层深度的增加,气候和植被因素作用明显减弱,土壤因素作用增强并成为主要影响因素。该结果有助于宁夏土...     

基于IBIS模型的1960-2006年中国陆地生态系统碳收支格局研究

定量评估区域陆地生态系统碳收支是生态系统与全球变化科学研究的重要科学问题之一。利用集成生物圈模型（IBIS）对中国陆地生态系统历史时期（1960-2006年）气候及CO₂浓度变化条件下碳收支时空变异特征和发展趋势进行了模拟分析。结果表明,1960-2006年间,中国陆地生态系统净初级生产力（NPP）总量水平约为2.46 GtC/a,总体呈上升趋势,在东南及西南地区最高,其次是长白山及大小兴安岭地区,西北内陆地区的净初级生产力水平最低;1960-2006年间,中国陆地生态系统净生态系统生产力（NEP）总量水平约为0.11 GtC/a,总体呈上升趋势,绝大部分区域表现为碳汇效应,大兴安岭、小兴安岭、长白山、东南地区及西南部分地区碳汇效应较强,西北内陆区表现出弱碳源效应,温带湿润区、高原温带区和高原寒带区碳汇效应呈显著上升趋势;中国11个气候区,NPP与降水均为正相关,除了中温带湿润区、寒温带湿润区、高原温带和高原寒带外,降水是限制植被生长的主要因子。除了高原寒带外,NEP同样表现出与降水的更强相关性,与气温的相关性较弱。经验证,IBIS模型对于中国陆地生态系统碳收支的模拟结果合理,可以为科学预测生态系统的固碳潜力和制定区域碳管理政策提供科学依据。     

Influence of temperature on the δ13C values and distribution of methanotroph‐related hopanoids in Sphagnum‐dominated peat bogs

Methane emissions from peat bogs are mitigated by methanotrophs, which live in symbiosis with peat moss (e.g. Sphagnum). Here, we investigate the influence of temperature and resultant changes in methane fluxes on Sphagnum and methanotroph‐related biomarkers, evaluating their potential as proxies in ancient bogs. A pulse‐chase experiment using ¹³C‐labelled methane in the field clearly showed label uptake in diploptene, a biomarker for methanotrophs, demonstrating in situ methanotrophic activity in Sphagnum under natural conditions. Peat cores containing live Sphagnum were incubated at 5, 10, 15, 20 and 25°C for two months, causing differences in net methane fluxes. The natural δ¹³C values of diploptene extracted from Sphagnum showed a strong correlation with temperature and methane production. The δ¹³C values ranged from ?34‰ at 5°C to ?41‰ at 25°C. These results are best explained by enhanced expression of the methanotrophic enzymatic isotope effect at higher methane concentrations. Hence, δ¹³C values of diploptene, or its diagenetic products, potentially provide a useful tool to assess methanotrophic activity in past environments. Increased methane fluxes towards Sphagnum did not affect δ¹³C values of bulk Sphagnum and its specific marker, the C₂₃ n‐alkane. The concentration of methanotroph‐specific bacteriohopanepolyols (BHPs), aminobacteriohopanetetrol (aminotetrol, characteristic for type II and to a lesser extent type I methanotrophs) and aminobacteriohopanepentol (aminopentol, a marker for type I methanotrophs) showed a non‐linear response to increased methane fluxes, with relatively high abundances at 25°C compared to those at 20°C or below. Aminotetrol was more abundant than aminopentol, in contrast to similar abundances of aminotetrol and aminopentol in fresh Sphagnum. This probably indicates that type II methanotrophs became prevalent under the experimental conditions relative to type I methanotrophs. Even though BHP concentrations may not directly reflect bacterial activity, they may provide insight into the presence of different types of methanotrophs.     

Growth,Net Production,Litter Decomposition,and Net Nitrogen Accumulation by Epiphytic Bryophytes in a Tropical Montane Forest1

To understand the ecological roles of epiphytic bryophytes in the carbon (C) and nitrogen (N) cycles of a tropical montane forest, we used samples in enclosures to estimate rates of growth, net production, and N accumulation by shoots in the canopy, and litterbags, to estimate rates of decomposition and N dynamics of epiphytic bryophyte litter in the canopy and on the forest floor in Monteverde, Costa Rica. Growth of epiphytic bryophytes was estimated at 30.0–49.9 percent/yr, net production at 122–203 g/m²/yr, and N accumulation at 1.8–3.0 g N/m²/yr. Cumulative mass loss from litterbags after one and two years in the canopy was 17 ± 2 and 19 ± 2 percent (mean ± 1 SE) of initial sample mass, respectively, and mass loss from litter and green shoots in litterbags after one year on the forest floor was 29 ± 2 and 45 ± 3 percent, respectively. Approximately 30 percent of the initial N mass was released rapidly from litter in both locations. Nitrogen loss from green shoots on the forest floor was greater; about 47 percent of the initial N mass was lost within the first three months. There was no evidence for net N immobilization by litter or green shoots, but the remaining N in litter was apparently recalcitrant. Annual net accumulation of C and N by epiphytic bryophytes was estimated at 37–64 g C/m²/yr and 0.8–1.3 g N/m²/yr, respectively. Previous research at this site indicated that epiphytic bryophytes retain inorganic N from atmospheric deposition to the canopy. Therefore, they play a major role in transforming N from mobile to highly recalcitrant forms in this ecosystem.     

Effects of elevated CO2, nitrogen deposition, and decreased species diversity on foliar fungal plant disease

Three components of global change, elevated CO₂, nitrogen addition, and decreased plant species richness (‘diversity’), increased the percent leaf area infected by fungi (pathogen load) for much to all of the plant community in one year of a factorial grassland experiment. Decreased plant diversity had the broadest effect, increasing pathogen load across the plant community. Decreased diversity increased pathogen load primarily by allowing remaining plant species to increase in abundance, facilitating spread of foliar fungal pathogens specific to each plant species. Changes in plant species composition also strongly influenced community pathogen load, with communities that lost less disease prone plant species increasing more in pathogen load. Elevated CO₂ increased pathogen load of C₃ grasses, perhaps by decreasing water stress, increasing leaf longevity, and increasing photosynthetic rate, all of which can promote foliar fungal disease. Decreased plant diversity further magnified the increase in C₃ grass pathogen load under elevated CO₂. Nitrogen addition increased pathogen load of C₄ grasses by increasing foliar nitrogen concentration, which can enhance pathogen infection, growth, and reproduction. Because changes in foliar fungal pathogen load can strongly influence grassland ecosystem processes, our study suggests that increased pathogen load can be an important mechanism by which global change affects grassland ecosystems.     

Soil carbon dynamics in a Pinus massoniana plantation following clear-cutting and slash removal

Aims Slash removal is a common practice to prepare recently harvested sites for replanting. However, little is known about its impact on soil carbon (C) dynamics in subtropical plantations. This study evaluates the effects of burning versus manual slash removal site preparation treatments on soil organic carbon (SOC), soil respiration and soil microbial community structure in a Pinus massoniana plantation in southern China.Methods Three areas within a mature P. massoniana plantation were clearcut. Two months following harvesting, slash on one-half of each area was burned (BURN), whereas slash was manually removed (MANR) on the other portion. Slash removal treatments were also compared with adjacent uncut plantation areas (UNCUT). Soil samples, and soil respiration measurements were used to characterize soil properties and microbial communities following slash removal treatments. Important findings Mean soil respiration rates from the MANR and BURN treatments were 26% and 17% lower, respectively, than the UNCUT treatment over 1 year. The MANR and BURN treatment resulted in soils with 27% and 9% reduction in total phospholipid fatty acids (PLFAs) and 18% and 10% reduction in bacterial PLFAs, respectively, compared with the UNCUT treatment. However, no significant differences existed between slash removal treatments with respect to soil chemical properties, SOC chemical compositions, soil respiration and microbial communities; although PLFA patterns were notably different for the burned plots. Most factors affecting C dynamics and microbial communities were not sensitive to the differences imparted to the ecosystem due to manual slash removal or burning. Our results suggested that low-intensity burning after clear-cutting might have no significant effect on soil C pool and its dynamics compared with manual slash removal in subtropical plantations.     

Global change and root function

Global change includes land-use change, elevated CO₂ concentrations, increased temperature and increased rainfall variability. All four aspects by themselves and in combination will influence the role of roots in linking below- and above-ground ecosystem function via organic and inorganic resource flows. Root-mediated ecosystem functions which may be modified by global change include below-ground resource (water, nutrients) capture, creation and exploitation of spatial heterogeneity, buffering of temporal variations in above-ground factors, supply and storage of C and nutrients to the below-ground ecosystem, mobilization of nutrients and C from stored soil reserves, and gas exchange between soil and atmosphere including the emission from soil of greenhouse gases. The theory of a functional equilibrium between root and shoot allocation is used to explore predicted responses to elevated CO₂ in relation to water or nutrient supply as limiting root function. The theory predicts no change in root:shoot allocation where water uptake is the limiting root function, but substantial shifts where nutrient uptake is (or becomes) the limiting function. Root turnover will not likely be influenced by elevated CO₂, but by changes in regularity of water supply. A number of possible mechanisms for root-mediated N mineralization is discussed in the light of climate change factors. Rhizovory (root consumption) may increase under global change as the balance between plant chemical defense and adapted root consuming organisms may be modified during biome shifts in response to climate change. Root-mediated gas exchange allows oxygen to penetrate into soils and methane (CH₄) to escape from wetland soils of tundra ecosystems as well as tropical rice production systems. The effect on net greenhouse gas emissions of biome shifts (fens replacing bogs) as well as of agricultural land management will depend partly on aerenchyma in roots.     

Relationships between carbon and nitrogen contents and enzyme activities in soil of three typical subtropical forests in China

森林类型更替是影响生态系统有机质循环的重要因素, 它对森林生态系统的生产力、碳吸存和养分保持功能有影响。然而关于中亚热带不同森林类型对土壤碳氮含量和酶活性的影响及土壤碳氮含量和酶活性之间的关系鲜有报道。该文研究了福建省三明市3种典型亚热带森林——米槠(Castanopsis carlesii)天然次生林(SF)、米槠人工促进天然更新林(AR)、马尾松(Pinus massoniana)人工林(PM)的淋溶层(A层)土壤碳氮含量和土壤微生物酶活性的关系。结果表明: 在3种森林类型表层土壤中, 可溶性有机质中可溶性有机碳、可溶性有机氮(DON)、荧光发射光谱腐殖化指数的趋势均为SF > AR > PM, 芳香化指数大小为PM > AR > SF; SF和AR的NH₄ ⁺-N显著高于PM, NO₃ ^--N在3种林分中的含量低且差异不明显, 造成这种差异的原因是树种差异和人为干扰程度不同。PM的β-葡萄糖苷酶活性显著低于SF和AR; 纤维素水解酶活性大小为AR > SF > PM; PM多酚氧化酶显著高于SF和AR, 3种林分过氧化物酶无显著差异。AR的β-N-乙酰氨基葡萄糖苷酶(NAG)显著高于其他两种林分。冗余分析显示土壤总氮和DON是驱动淋溶层土壤酶活性的主要环境因子。总之, 土壤总氮含量与NAG活性呈正相关关系, 并且可溶性有机氮可能是氮循环中的重要一环; 土壤微生物优先利用易分解碳; 且碳氮养分循环之间存在一定的耦合关系。氮提高了与土壤碳相关的水解酶活性, 从而可促进碳周转。