鼎湖山主要森林生态系统地表N2O通量

利用静态箱-气相色谱法对鼎湖山3种处于演替不同阶段的森林类型(季风常绿阔叶林、针阔叶混交林和马尾松林)的地表N2O通量进行了1年的原位观测和研究.结果表明,3种林型地表N2O通量按从大到小的顺序为季风林>混交林>松林;不同林型间的N2O通量差异与森林土壤的性质有密切关系,C/N比值较低的季风林凋落叶对土壤中产生N2O的微生物过程有较为明显的促进作用;从全年来看,松林地表N2O通量的季节变化不明显,而季风林和混交林的地表N2O通量在雨季存在明显的降雨驱动效应,统计分析显示在该地区影响森林地表N2O通量的主要因子是土壤湿度.     

森林类型对土壤表层有机碳空间异质性的影响

对西南山地阔叶林区的天然阔叶混交林、天然次生林和人工柳杉林的土壤表层有机碳（SSOC）进行了测定,并用地统计学理论构建了3种亚热带森林生态系统在小尺度上的SSOC半方差理论模型。结果表明,不同森林生态系统间SSOC含量差异性显著,表现为天然阔叶混交林>天然次生林>人工柳杉林,SSOC含量与土壤含水率、容重、孔隙度和有机质相关性显著;天然阔叶混交林的SSOC空间相关性最强,次生林次之,人工林较弱;天然阔叶混交林SSOC在45°方向上空间变异最明显,天然次生林和人工林在各个方向上的变异均较弱;天然阔叶混交林SSOC的等值线较密,梯度变化急剧,天然次生林次之,人工林等值线稀疏,梯度变化不明显。总之,不同森林类型对SSOC含量和分布有着重要影响。     

长白山原始森林土壤养分及其对土柱置换试验响应

自然垂直带典型温带原始森林土壤养分状况及其对温度升高的响应,对碳估算及森林生态系统管理具有重要意义。研究对比长白山北坡垂直小样带3种典型原始森林土壤养分状况,并将岳桦林(海拔1996 m)采集土柱分别置换到云冷杉林(海拔1350m)和阔叶红松林(海拔740m)样地,将云冷杉林采集土柱置换到阔叶红松林样地中进行1年野外模拟增温培养。结果发现,土壤碳、氮、磷含量表现为岳桦林>阔叶红松林>云冷杉林,并且0～10cm>10～20cm土层。0～20cm土壤碳、氮、磷密度表现为阔叶红松林>岳桦林>云冷杉林,分别为5.64～12.75、0.24～0.89、0.04～0.14 kg·m^-2。3种林型土壤溶解性有机碳(DOC)差异不显著,经过1年野外土柱置换模拟增温培养后,DOC有增加趋势,土壤溶解性氮明显增加。     

松果采摘对小兴安岭主要林型红松土壤种子库和幼苗库的影响

为了探讨人为采摘松果对小兴安岭主要林型红松(Pinus koraiensis)土壤种子库和幼苗库的影响,选择阔叶红松林以及与阔叶红松林相邻的红松人工林、落叶松(Larix gmelini)人工林、白桦(Betula platyphylla)林和云冷杉林,各设置10 m×240 m的样带,调查了红松土壤种子库和幼苗库。主要结果如下:①主要林型间红松土壤种子库数量具有明显的差异,阔叶红松林最多,落叶松人工林次之,白桦林最少;②鼠类取食过或被破坏等动物侵害的种子占81.9%～90.4%,完好种子只有在阔叶红松林和落叶松人工林中发现,分别为4.3%和4.9%;③红松种子主要分布在0～10 cm层中(71.4%～91.3%);④红松幼苗库的密度云冷杉林最高(1 613株.hm-2),红松人工林最低(167株.hm-2),其中阔叶红松林(296株.hm-2)和白桦林(854株.hm-2)的幼苗密度分别为采摘前的1/68～1/9和1/9～1/4.5;⑤从龄级分布上看,松果采摘前阔叶红松林低龄级幼苗的数量较多,随着龄级的增大明显减少,呈倒J型分布;白桦林各龄级幼苗密度相差不大。人为采摘松果后,阔叶红松林各龄级间密度相差不大;白桦林呈倒J型分布。     

中国草地N2O通量日变化观测对比研究

研究分析了我国20世纪90年代以来科学工作者利用静态箱-气相色谱法对内蒙古呼伦贝尔草原和锡林郭勒草原、青藏高寒草原等不同草原类型所开展的日变化通量观测数据并进行了对比分析研究.结果表明:我国草地N2O通量的日变化规律明显,日变化形式呈多峰型,我国草地均表现为N2O排放源,日均通量的对比顺序是:贝加尔针茅草甸草原>羊草草甸草原>羊草典型草原>高寒草甸[(42.82±15.96)>(29.17±13.03)>(4.91±2.12)>(0.89±0.67)μg/(m2?h)];10:00~14:00和夜间0:00左右所观测的N2O通量均可代表当日平均通量;夜间N2O的排放对整个日通量有重要贡献,其排放量占到全日排放总量的46%以上,草地夜间N2O的排放通量应该受到重视.另外,本文讨论了水分和温度作为主要环境因子对N2O通量日变化的影响,以及不同植被类型和人类活动(放牧和刈割)对N2O通量的日变化的影响.     

森林生态系统水源涵养服务流量过程研究

基于多年的定位监测数据,研究了亚热带5种森林生态系统水源涵养服务的流量过程。结果表明,里骆杉木林、西江坪常绿阔叶林的年内林冠截留量曲线呈现单峰型,而宜山龙桥的3种森林生态系统的林冠截留量曲线则呈双峰型。5种森林生态系统累积林冠截留价值的过程曲线基本一致。里骆杉木林和西江坪常绿阔叶林的水文调节量变幅较大,而龙桥3种类型的年内水文调节量变幅较小。5种森林生态系统的月平均水文调节量依次为西江坪常绿阔叶林里骆杉木林龙桥柠檬桉马尾松混交林龙桥马尾松林龙桥杉木林。5种森林生态系统水资源供给功能过程曲线呈现与水文调节功能曲线相似的规律,对应的月平均水资源供给量分别是751.92、486.92、332.08、210.50、65.92 m3/(hm2.月)。运用影子价格法计算了累积林冠截留价值、累积水文调节价值和累积水资源供给价值。根据计算结果,建立了月水文调节量和月水资源供给量与月降水量的回归方程。     

华西雨屏区典型人工林对降雨过程中NH_4~+-N和NO_3~--N的过滤作用

氮沉降已成为河流、湖泊及城市等生态系统的主要污染威胁因素之一,森林生态系统能从林冠、地被和土壤自上而下截留过滤大气降雨中的NH+4-N和NO-3-N,是区域大气环境污染生态防治的重要途径.选取华西雨屏区几种典型人工林森林生态系统为研究对象,采用定位监测与室内分析相结合的研究方法,于2011年4—12月对大气降水、穿透雨、树干茎流、地表径流和地下渗滤NH+4-N和NO-3-N的含量与分配进行了研究.结果表明:观测期内40次降雨总雨量为492.72 mm,NH+4-N和NO-3-N的总沉降量分别为13.248 kg·hm-2和16.320 kg·hm-2;3种人工林林冠层对NH+4-N和NO-3-N的过滤能力表现为香樟林混交林柳杉林,而地表和土壤层均表现为混交林香樟林柳杉林;无林地、香樟林、柳杉林和混交林生态系统无机氮截留过滤净输入量分别为19.557、44.079、42.331、64.896 kg·hm-2,对无机氮的综合过滤作用表现为混交林香樟林柳杉林无林地.这些结果说明华西雨屏区合理配置混交林能更加有效地降低大气氮沉降对生态系统的影响.     

井冈山重要森林生态系统碳密度对比

采用生物量模型与实际测量相结合的方法,从植被层(包括乔木与林下植被)、枯落层和土壤层(表层1 m)比较了井冈山5种重要森林生态系统碳密度. 结果表明:①森林生态系统平均碳密度为29.047 kg/m2,常绿阔叶林>针阔混交林>人工杉木林>落叶阔叶林>毛竹林;②土壤碳密度平均值为22.453 kg/m2,占森林总碳密度的77.3%,5种森林类型土壤碳密度排序与总碳密度相同,且差异较小;③植被层碳密度差异最大,针阔混交林碳密度最大(12.039 kg/m2),是碳密度最小的落叶阔叶林(1.322 kg/m2)的9.1倍;④乔木层碳密度排序为针阔混交林>常绿阔叶林>人工杉木林>毛竹林>落叶阔叶林,乔木地上碳密度占乔木总碳密度的61.4%(人工杉木林)～75.8%(落叶阔叶林);⑤灌木层总碳密度差异大,常绿阔叶林和落叶阔叶林的灌木总碳密度分别为最大(0.153 kg/m2)和最小(0.027 kg/m2),前者是后者的5.6倍,灌木地上碳密度占灌木总碳密度的78.3%(针阔混交林)～81.0%(常绿阔叶林);⑥草本层总碳密度差异较小,在0.074 kg/m2(人工杉木林)～0.108 kg/m2(毛竹林)之间,地下碳密度略高于地上;⑦枯落层碳密度最低,不同森林类型间枯落层碳密度差异不大,在0.064～0.084 kg/m2之间.      

施用畜禽粪便堆肥品的蔬菜地CH4、N2O和NH3排放特征

农田是重要的温室气体排放来源之一,其中蔬菜地的温室气体排放日益受到人们关注.以北京市郊某温室种植的油麦菜地为研究对象,通过大棚试验,考察和比较了油麦菜地施用不同类型畜禽粪便堆肥产品的CH4、N2O和NH3排放特征及其影响因素.结果表明,油麦菜地NRM、RM、CF处理的CH4排放系数分别为0.2%、0.027%、0.004%;N2O排放系数分别为0.18%、0.63%、0.74%;NH3排放系数分别为2.00%、3.98%、2.53%.CH4排放通量与土壤温度和地表湿度相关,N2O排放通量与土壤温度、地表温度和湿度相关,CH4、N2O和NH3排放通量均受土壤含水率影响,而温室中的气温不是影响CH4、N2O和NH3排放的主要因素.     

天然林土壤有机碳及矿化特征研究

通过野外调查和室内分析培养,研究了马尾松林、常绿阔叶林、落叶阔叶林、针阔混交林、红松林和油松林这6种天然林林下土壤有机碳含量及有机碳矿化特征.结果表明,林下土壤有机碳含量都表现出随土壤深度增加而逐渐降低的趋势;双指数方程可以很好拟合出天然林土壤有机碳的矿化过程,准确反映出各天然林土壤的矿化反应特征.天然林各层土壤矿化反应趋势相同,但强度各异.其中,红松林0~10 cm土壤反应强度最为强烈,其下各层土壤的矿化反应强度也显著高于其他天然林的同层土壤;对落叶阔叶林和针阔混交林土壤矿化特征比较发现,凋落物种类差异对土壤活性有机碳含量产生较强烈影响,因此呈现出不同的矿化反应特征.     

Effects of temperature change and tree species composition on N2O and NO emissions in acidic forest soils of subtropical China

Tree species and temperature change arising from seasonal variation or global warming are two important factors influencing N2O and NO emissions from forest soils. However, few studies have examined the effects of temperatures(5–35℃) on the emissions of forest soil N2O and NO in typical subtropical region. A short-term laboratory experiment was carried out to investigate the influence of temperature changes(5–35℃) on soil N2O and NO emissions under aerobic conditions in two contrasting(broad-leaved and coniferous) subtropical acidic forest types in China. The results showed that the temporal pattern of N2O and NO emissions between the three lower temperatures(5℃, 15℃, and 25℃) and 35℃ was significantly different for both broad-leaved and coniferous forest soils. The effects of temperature on soil N2O and NO emission rates varied between broad-leaved and coniferous forest soils. Both N2O and NO emissions increased exponentially with an increase in temperature in the broad-leaved forest soil. However, N2O and NO emissions in the coniferous forest soil were not sensitive to temperature change between 5℃ and 25℃. N2O and NO emission rates were significantly higher in the broad-leaved forest soil as compared with the coniferous forest soil at all incubation temperatures except 5℃. These results suggest that the broad-leaved forest could contribute more N2O and NO emissions than the coniferous forest for most of the year in the subtropical region of China.     

Dynamics of soil inorganic nitrogen and their responses to nitrogen additions in three subtropical forests, south China

Three forests with different historical land-use, forest age, and species assemblages in subtropical China were selected to evaluate current soil N status and investigate the responses of soil inorganic N dynamics to monthly ammonium nitrate additions. Results showed that the mature monsoon evergreen broadleaved forest that has been protected for more than 400 years exhibited an advanced soil N status than the pine （Pinus massoniana） and pine-broadleaf mixed forests, both originated from the 1930＇s clear-cut and pine plantation. Mature forests had greater extractable inorganic N pool, lower N retention capacity, higher inorganic N leaching, and higher soil C/N ratios. Mineral soil extractable NH4^＋-N and NO3-N concentrations were significantly increased by experimental N additions on several sampling dates, but repeated ANOVA showed that the effect was not significant over the whole year except NH4^＋-N in the mature forest. In contrast, inorganic N （both NH4^＋-N and NO3^--N） in soil 20-cm below the surface was significantly elevated by the N additions. From 42% to 74% of N added was retained by the upper 20 cm soils in the pine and mixed forests, while 0%-70% was retained in the mature forest. Our results suggest that land-use history, forest age and species composition were likely to be some of the important factors that determine differing forest N retention responses to elevated N deposition in the study region.     

Nitrous oxide fluxes from upland soils in central Hokkaido, Japan

Nitrous oxide (N2O) fluxes from soils were measured using the closed chamber method during the snow-free seasons (middle April to early November),for three years,in a total of 11 upland crop fields in central Hokkaido,Japan.The annual mean N2O fluxes ranged from 2.95 to 164.17 μgN/(m2·h),with the lowest observed in a grassland and the highest in an onion field.The instantaneous N2O fluxes showed a large temporal variation with peak emissions generally occurring following fertilization and heavy rainfall eve...     

Effect of N and P addition on soil organic C potential mineralization in forest soils in South China

Atmospheric nitrogen deposition is at a high level in some forests of South China. The effects of addition of exogenous N and P on soil organic carbon mineralization were studied to address: (1) if the atmospheric N deposition promotes soil C storage through decreasing mineralization; (2) if the soil available P is a limitation to organic carbon mineralization. Soils (0-10 cm) was sampled from monsoon evergreen broad-leaved forest (MEBF), coniferous and broad-leaved mixed forest (CBMF), and Pinus massoniana...     

中亚热带5种类型森林土壤微生物群落特征

采用PLFA(phospholipid fatty acids,磷脂脂肪酸)分析法研究江西省九连山国家级自然保护区杉木纯林、马尾松纯林、杉木阔叶混交林、马尾松阔叶混交林与天然常绿阔叶林的土壤微生物群落结构特征,探讨植被特征和土壤理化特征对土壤微生物群落的影响. 结果表明:①杉木阔叶混交林土壤细菌、放线菌和总微生物生物量最高,分别为7.77、1.74和18.21 nmol/g,而马尾松纯林均最低. ②针阔混交显著提高了土壤微生物生物量及其丰富度. 土壤微生物生物量及其丰富度均与土壤含水率、w(AN)(AN为有效氮)、w(TC)、w(TN)呈显著正相关(R为0.426~0.701),而与C/N〔w(TC)/w(TN)〕呈显著负相关(R分别为-0.447、-0.518). ③w(AN)对土壤微生物群落结构的解释率达55.8%. 尽管林下灌木、草本层生物量对土壤微生物生物量影响不大,但对微生物群落结构有一定影响,解释率分别为5.5%和6.3%. 灌草层丰富度与土壤微生物生物量及其丰富度呈显著正相关(R为0.369~0.452). 可见,阔叶树种和林下灌草层能够显著影响土壤微生物群落组成.      

Preliminary studies on nitrous oxide emissions from the ornithogenic soils on Xi-sha atoll, South China Sea

IntroductionNitrousoxide (N2 O)isoneofthemostimportantgreenhousegases ,anditplaysanimportantroleinthedepletionofstratosphericozone (Crutzen ,1977;Zhu ,2 0 0 4 ) .TheatmosphericN2 Oconcentrationshavebeenincreasingattherateof 0 2 %— 0 3%peryearandthegl…     

北京地区暖温带森林土壤温室气体排放规律

本研究利用静态箱法在北京市东灵山暖温带森林生长期选择3种不同类型的森林(阔叶混交林、辽东栎林和油松林)的土壤进行了温室气体(CH₄、CO₂和N₂O)排放规律的野外原位观测.研究结果表明:暖温带主要代表森林类型的土壤作为CH₄的汇吸收大气中的CH₄,同时作为CO₂和N₂O的源向大气排放.观测结果显示:不同的森林土壤类型其温室气体排放通量、范围各不相同,阔叶混交林土壤CH₄、CO₂和N₂O通量范围分别是:42～103μg/(m²·h),15～344mg/(m²·h)和-61～101μg/(m²·h);辽东栎林土壤3种气体通量范围分别是:13～182 μg/(m²·h),23～380mg/(m²·h)和-15～183 μg/(m²·h);油松林土壤3种气体通量范围分别是:12～128 μg/(m²·h),15～292mg/(m²·h) 和 -94～153 μg/(m²·h).观测期内阔叶混交林土壤CH₄、CO₂和N₂O平均通量分别是:-66 μg/(m²·h),145mg/(m²·h)和22 μg/(m²·h);辽东栎林土壤3种气体平均通量分别是:-67 μg/(m²·h),146mg/(m²·h)和45μg/(m²·h);油松林土壤3种气体平均通量分别是:-79 μg/(m²·h),150mg/(m²·h)和31μg/(m²·h).本研究估算了不同类型的森林土壤不同的温室气体生长期内的排放总量,阔叶混交林土壤CH₄、CO₂和N₂O排放总量分别是:-5.34kg/(hm²·a),13.9Mg/(hm²·a) 和2.58kg/(hm²·a); 辽东栎林土壤3种气体排放总量分别是:-6.20kg/(hm²·a), 14.07Mg/(hm²·a)和4.19kg/(hm²·a); 油松林土壤3种气体排放总量分别是-6.85kg/(hm²·a), 15.71Mg/(hm²·a)和4.30kg/(hm²·a).