Element cycling in the dominant plant community in the Alpine tundra zone of Changbai Mountains, China

Element cycling in the dominant plant communities including Rh. aureum, Rh. redowskianum and Vaccinium uliginosum in the Alpine tundra zone of Changbai Mountains in northeast China was studied. The results indicate that the amount of elements from litter decomposition was less than that of the plant uptake from soil, but that from plant uptake was higher than that in soil with mineralization process released. On the other hand, in the open system including precipitation input and soil leaching output, because of great number of elements from precipitation into the open system, the element cycling(except N, P) in the Alpine tundra ecosystem was in a dynamic balance. In this study, it was also found that different organ of plants had significant difference in accumulating elements. Ca, Mg, P and N were accumulated more obviously in leaves, while Fe was in roots. The degree of concentration of elements in different tissues of the same organ of the plants also was different, a higher concentration of Ca, Mg, P and N in mesophyll than in nerve but Fe was in a reversed order. The phenomenon indicates (1) a variety of biochemical functions of different elements, (2) the elements in mesophyll were with a shorter turnover period than those in nerve or fibre, but higher utilization rate for plant. Therefore, this study implies the significance of keeping element dynamic balance in the alpine tundra ecosystem of Changbai Mountains.

Effective Seed Distribution Pattern of an Upward Shift Species in Alpine Tundra of Changbai Mountains

The vegetation of alpine tundra in the Changbai Mountains has experienced great changes in recent decades. Narrowleaf small reed(Deyeuxia angustifolia), a perennial herb from the birch forest zone had crossed the tree line and invaded into the alpine tundra zone. To reveal the driven mechanism of D. angustifolia invasion, there is an urgent need to figure out the effective seed distribution pattern, which could tell us where the potential risk regions are and help us to interpret the invasion process. In this study, we focus on the locations of the seeds in the soil layer and mean to characterize the effective seed distribution pattern of D. angustifolia. The relationship between the environmental variables and the effective seed distribution pattern was also assessed by redundancy analysis. Results showed that seeds of D. angustifolia spread in the alpine tundra with a considerable number(mean value of 322 per m2). They were mainly distributed in the low elevation areas with no significant differences in different slope positions. Effective seed number(ESN) occurrences of D. angustifolia were different in various plant communities. Plant communities with lower canopy cover tended to have more seeds of D. angustifolia. Our research indicated reliable quantitative information on the extent to which habitats are susceptible to invasion.

Responses and feedback of litter properties and soil mesofauna to herbaceous plants expansion into the alpine tundra on Changbai Mountain,China

Global climate changes result in the expansion of lower elevation plants to higher elevations.The rapid upward expansion of herbaceous plants into the alpine tundra on Changbai Mountain resulted in changes in different levels of ecosystem organization.However,the responses and feedback of litter properties and soil mesofauna to herbaceous plants expansion have not been studied yet.To understand the mechanisms underlying those changes,we conducted a field experiment in the range of 2250-2300 m in the alpine tundra of the Changbai Mountain and collected a total of 288 samples from four degrees of herbaceous plants expansion to study the litter physiochemical properties,soil mesofauna,and soil nutrient contents,and their relationships in that tundra ecosystem suffered from various degrees of herbaceous invasion.We found that herbaceous plant expansion is responsible for a major shift in the dominant species of soil mesofauna from mites to collembolan and has significant impacts on the community structure(R2=0.54,p=0.001)and diversity of soil mesofauna(Shannon-Weiner index,p=0.01).The increasing herbaceous plant expansion resulted in a significant increase in litter biomass from 91 g·m^(-2) in the original tundra vegetation(OIT)to 118 g·m^(-2) in the moderately invaded tundra(MIT),and an increase in litter thickness from 2.37 cm(OIT)to 3.05 cm(MIT).And,the litter total nitrogen content significantly increased,but the values of the litter carbon content,the lignin content,the C/N ratio,and the lignin/N ratio decreased with increased herbaceous coverage(both p<0.05).The litter physical properties pathway(biomass and thickness)directly explained 31% of the total variance in soil mesofauna diversity and 59% of the total variance in soil mesofauna community composition.Furthermore,both the soil available nutrients(incl.AN and AP)and plant biomass(incl.the total plant biomass and herbs/shrubs biomass)significantly increased with increasing coverage of herbaceous plant(both p<0.05),and litter chemical properties pathway directly explained 50% of the soil nutrient content variance and indirectly explained 20% of soil nutrient by affecting soil mesofauna.We found that both soil available nutrients and soil mesofauna were positively correlated with the herbaceous expansion from OIT to MIT,indicating a positive feedback of herbaceous expansion,and the abundance of soil mesofauna decreased in the severely invaded tundra vegetation,suggesting a negative feedback.While,both litter N content and soil available nitrogen were consistently increased in the severely invaded tundra vegetation,indicating a positive feedback of herbaceous expansion.Therefore,this study provides new insights into the process of herbaceous plant expansion into tundra,and provides possible evidence for further expansion according to responses and feedback of in litter properties and soil mesofauna to herbaceous plants expansion.Furthermore,these positive or/and negative feedback systems in the Changbai alpine tundra ecosystem in relation to herbaceous expansion have important implications for the tundra protection,and thus,need to be deeply studied.

Spatial pattern of soil carbon and nutrient storage at the Alpine tun-dra ecosystem of Changbai Mountain, China

In August 2003, we investigated spatial pattern in soil carbon and nutrients in the Alpine tundra of Changbai Moun-tain, Jilin Province, China. The analytical results showed that the soil C concentrations at different depths were significantly (p<0.05) higher in Meadow alpine tundra vegetation than that in other vegetation types; the soil C (including inorganic carbon) concentrations at layer below 10 cm are significantly (p<0.05) higher than at layer of 1020 cm among the different vegetation types; the spatial distribution of soil N concentration at top surface of 0-10 cm depth was similar to that at 1020 cm; the soil P concentrations at different depths were significantly (p<0.05) lower at Lithic alpine tundra vegetation than that at other vegetation types; soil K concentration was significantly (p<0.05) higher in Felsenmeer alpine tundra vegetation and Lithic alpine tundra vegetation than that in Typical alpine tundra, Meadow alpine tundra, and Swamp alpine tundra vegetations.. However, the soil K had not significant change at different soil depths of each vegetation type. Soil S concentration was dramatically higher in Meadow alpine tundra vegetation than that in other vegetation types. For each vegetation type, the ratios of C: N, C: P, C: K and C: S generally decreased with soil depth. The ratio of C: N was significantly higher at 010 cm than that at 1020 cm for all vegetation types except at the top layer of the Swamp alpine tundra vegetation. Our study showed that soil C and nutrients storage were significantly spatial heterogeneity.

Soil Microbial Community and Enzyme Activity Responses to Herbaceous Plant Expansion in the Changbai Mountains Tundra, China

As one of the most sensitive regions to global climate change, alpine tundra in many places around the world has been undergoing dramatic changes in vegetation communities over the past few decades.Herbaceous plant species in the Changbai Mountains area have significantly expanded into tundra shrub communities over the past 30 yr.Soil microbial communities, enzyme activities, and soil nutrients are intertwined with this expansion process.In order to understand the responses of the soil microbial communities to such an expansion, we analyzed soil microbial community structures and enzyme activities in shrub tundra as well as areas with three different levels of herbaceous plant expansion.Our investigation was based on phospholipid fatty acid(PLFA) analysis and 96-well microtiter plates.The results showed that herbs have expanded greatly in the tundra, and they have become the dominant species in herbaceous plant expansion areas.There were differences for community composition and appearance among the shrub tundra and the mild expansion, moderate expansion, and severe expansion areas.Except for soil organic matter, soil nutrients were increased in herbaceous plant expansion areas, and the total nitrogen(TN), total phosphorus(TP), available nitrogen(AN), and available phosphorus(AP) were greatest in moderate expansion areas(MOE), while soil organic matter levels were highest in the non-expanded areas(CK).The total soil PLFAs in the three levels of herbaceous plant expansion areas were significantly higher than those in the non-expanded areas, and total soil PLFAs were highest in the moderately expanded area and lowest in the severely expanded area(SEE).Bacteria increased significantly more than fungi and actinomycetes with herbaceous plant expansion.Soil hydrolase activities(β-1,4-glucosidase(βG) activity, β-1, 4-N-acetylglucosaminidase(NAG) activity, and acid phosphatase(aP) activity) were highest in MOE and lowest in the CK treatment.Soil oxidase activities(polyphenol oxidase(PPO) activities and peroxidase(PER) activities) were also highest in MOE, but they were lowest in the SEE treatment.The variations in total soil PLFAs with herbaceous plant expansion were mostly correlated with soil organic matter and available phosphorus concentrations, while soil enzyme activities were mostly correlated with the total soil nitrogen concentration.Our results suggest that herbaceous plant expansion increase the total soil PLFAs and soil enzyme activities and improved soil nutrients.However, soil microorganisms, enzyme activity, and nutrients responded differently to levels of herbaceous plant expansion.The soil conditions in mild and moderate expansion areas are more favorable than those in severe expansion areas.

Effects of Nitrogen Deposition on Tundra Vegetation Undergoing Invasion by Deyeuxia angustifolia in Changbai Mountains

In recent years, herbaceous species such as Deyeuxia angustifolia （Kom.） Y. L. Chang has invaded alpine tundra regions of the western slope of the Changbai Mountains. Because atmospheric nitrogen deposition is predicted to increase under a warming climate and D. angustifolia is sensitive to nitrogen addition, field experiments were conducted from 2010 to 2013 to determine the effect of increased nitrogen deposition on the mechanisms of D. angustifolia invasion. The goal of this study is to evaluate the impact of increased nitrogen deposition on the changes in alpine tundra vegetation （consisting mostly of Rhododendron chrysanthum Pall. and Vaccinium uliginosum Linn.）. The results showed that： 1） simulated nitrogen deposition affected overall characteristics and structure of R. chrysanthum and E uliginosum communities and had a positive impact on the growth of tundra vegetation invaded by 1）. angustifolia; 2） R. chrysanthum was more resistant to invasion by D. angustifolia than V.. uliginosum; 3） simulated nitrogen deposition could improve the growth and enhance the competitiveness of D. angustifolia, which was gradually replacing R. chrysanthum and V. uliginosum and might become the dominant species in the system in future, transforming alpine tundra into alpine meadow in the Chanebai Mountains.

Comparative Assessment of Tundra Vegetation Changes Between North and Southwest Slopes of Changbai Mountains, China, in Response to Global Warming

Vegetation in high altitude areas normally exhibits the strongest response to global warming. We investigated the tundra vegetation on the Changbai Mountains and revealed the similarities and differences between the north and the southwest slopes of the Changbai Mountains in response to global warming. Our results were as follows: 1) The average temperatures in the growing season have increased from 1981 to 2015, the climate tendency rate was 0.38℃/10 yr, and there was no obvious change in precipitation observed. 2) The tundra vegetation of the Changbai Mountains has changed significantly over the last 30 years. Specifically, herbaceous plants have invaded into the tundra zone, and the proportion of herbaceous plants was larger than that of shrubs. Shrub tundra was transforming into shrub-grass tundra. 3) The tundra vegetation in the north and southwest slopes of the Changbai Mountains responded differently to global warming. The southwest slope showed a significantly higher degree of invasion from herbaceous plants and exhibited greater vegetation change than the north slope. 4) The species diversity of plant communities on the tundra zone of the north slope changed unimodally with altitude, while that on the tundra zone of the southwest slope decreased monotonously with altitude. Differences in the degree of invasion from herbaceous plants resulted in differences in species diversity patterns between the north and southwest slopes. Differences in local microclimate, plant community successional stage and soil fertility resulted in differential responses of tundra vegetation to global warming.

草本植物上侵长白山苔原对牛皮杜鹃孤岛化的作用分析

对近年来长白山出现草本植物上侵灌木苔原,导致牛皮杜鹃(Rhododendron aureum)孤岛化的现象进行了研究.结果表明:草本植物入侵导致苔原带牛皮杜鹃分布范围缩小、重要值下降、生态位总宽度下降,草本植物与牛皮杜鹃生态位重叠程度加重;草本植物入侵使苔原带牛皮杜鹃与岳桦林下牛皮杜鹃隔离加大;苔原带现有草本入侵的景观与牛皮杜鹃景观差异增大;牛皮杜鹃景观破碎程度加重.苔原的低海拔区域受草本入侵影响程度比中高海拔区域强烈.草本植物入侵苔原带并持续扩张,使牛皮杜鹃景观基质面被打散;在苔原带下部出现草甸亚带,使苔原带和岳桦林带成为两个独立的牛皮杜鹃分布区,两个带牛皮杜鹃基因交流的廊道被切断;苔原带上牛皮杜鹃景观破碎程度越来越大,与原来景观的差异越来越大,且这种作用从低海拔逐渐向高海拔推进,在空间上牛皮杜鹃生存范围将越来越小,牛皮杜鹃物种孤岛化问题将越来越严重.

Carbon cycling of alpine tundra ecosystems on Changbai Mountain and its comparison with arctic tundra

The alpine tundra on Changbai Mountain was formed as a left-over ‘island' in higher elevations after the glacier retrieved from the mid-latitude of Northern Hemisphere to the Arctic during the fourth ice age. The alpine tundra on Changbai Mountain also represents the best-reserved tundra ecosystems and the highest biodiversity in northeast Eurasia. This paper examines the quantity of carbon assimilation, litters, respiration rate of soil, and storage of organic carbon within the alpine tundra ecosystems on Changbai Mountain. The annual net storage of organic carbon was 2092 t/a, the total storage of organic carbon was 33457 t, the annual net storage of organic carbon in soil was 1054 t/a, the total organic carbon storage was 316203 t, and the annual respiration rate of soil was 92.9% and was 0.52 times more than that of the Arctic. The tundra-soil ecosystems in alpine Changbai Mountain had 456081 t of carbon storage, of which, organic carbon accounted for 76.7% whereas the mineral carbon accounted for 23.3%.

长白山苔原带土壤跳虫群落组成和表聚性特征研究

跳虫是土壤动物群落的重要组成部分,且对环境变化非常敏感,极端环境条件下跳虫的组成和分布特征研究相对不足。为了解高山苔原带土壤跳虫群落的组成和分布特征,于2021年7月和8月在长白山北坡苔原带进行了土壤跳虫取样调查。研究采用了Vortis采样器采集土壤表面0 cm跳虫,采用土钻采集土壤层(0~5 cm和5~15 cm)跳虫来完整揭示土壤跳虫的群落组成。研究共收集土壤跳虫3 958只,隶属于9科25属34种。结果表明,采用吸虫器和土钻相结合的方法能够获得更完整的土壤跳虫群落;3种土壤深度的跳虫群落组成、丰富度和多样性指数均存在显著差异且呈现出明显的表聚性特征(0~5 cm);研究筛选出指示跳虫物种17种,土壤表面0 cm的指示物种12种,土壤0~5 cm的指示物种5种,2个土壤层次指示物种明显不同,土壤5~15 cm无指示物种;总氮、总碳和碳氮比是影响跳虫群落的主要因素。本研究可为长白山地生物多样性保护和生态系统评估提供科学的理论依据。

长白山苔原带土壤真菌与环境因子的相关性

【目的】探明长白山苔原带土壤真菌群落组成、多样性及其与土壤理化特性的关系,为深入了解长白山北坡苔原带土壤微生物群落特征及长白山苔原带变化规律提供参考。【方法】以长白山北坡苔原带土壤作为研究对象,基于真菌形态学观察鉴别,利用指标检测法分析不同海拔土壤的含水率、pH、有效磷、铵态氮,并深入分析长白山北坡苔原带不同海拔地区土壤真菌的群落变化特征及其与土壤理化特性的关系。【结果】在长白山北坡苔原带土壤中共获得3门5纲7目9科17属土壤真菌,在属水平上的优势类群为青霉属(Penicillium)、木霉属(Trichoderma)、曲霉属(Aspergillus)、镰孢属(Fusarium)、毛霉属(Mucor)。根霉属(Rhizopus)、放射毛霉属(Actinomucor)、弯颈霉属(Tolypocladium)及毛壳属(Chaetomiua)在不同生境的分布存在显著差异。各海拔区内,土壤含水量、温度、pH、有效磷、硝态氮和铵态氮可能是影响长白山苔原带土壤真菌群落组成成分的关键性土壤环境因子。【结论】长白山苔原带随着海拔上升,土壤真菌多样性总体数量下降,土壤硝态氮、有效磷、铵态氮及含水率对土壤真菌群落特征影响较大。

长白山西坡小叶章侵入苔原带过程及影响

长白山西坡岳桦林带的草本植物(以小叶章为代表)侵入了苔原带,形成了独特的植物入侵现象。在光谱及影像分析的基础上,结合GPS(Global Positional System)定位技术,并依据小叶章与牛皮杜鹃的光谱差异及其反演的NDVI(Normalized Difference Vegetation Index)植被指数,揭示小叶章侵入苔原带的过程;通过对不同侵入时间、强度的斑块进行群落调查及土壤测试,探究小叶章侵入苔原带的生态后果。结果显示小叶章侵入苔原带始于20世纪80年代后期,由低海拔向高海拔推进,进入21世纪后逐渐形成了稳定的以小叶章为优势物种的植物群落结构。目前,低海拔处的小叶章斑块经过多年扩张已连接成片,而高海拔处的斑块正处于扩张的初期阶段。从生物多样性变化可以看出,小叶章侵入苔原带导致植物群落多样性升高和物种数量的增加,苔原带原有的灌木数量明显减少,草本植物逐渐增多。植被的改变影响了土壤的理化性质,C/N比下降,土壤腐殖质含量和全氮含量下降,但速效氮和土壤持水能力上升,土壤养分的高效利用又进一步推动了小叶章的侵入。小叶章侵入苔原带已经造成了严重的生态后果。

长白山苔原带优势植物种的分布格局及其关联性研究

通过开展植被样方调查,确定苔原带的主要优势种,分析优势种的分布格局及其关联性,从地理角度分析长白山苔原带植被变化特征。研究表明:1长白山苔原带8个优势种中,草本植物已占6个。灌木中牛皮杜鹃(Rhododendron chrysanthum)依然为最主要的优势种,但笃斯越橘(Vaccinium uliginosum)的优势地位已被草本的小白花地榆(Sanguisorba parviflora)取代。草本植物聚集程度强,苔原植被存在草甸化趋势。2除牛皮杜鹃与大白花地榆(Sanguisorba stipulata)之间存在较显著的负联结,排它现象明显外,多种优势种之间存在正联结,有弱的伴生现象,牛皮杜鹃和小白花地榆为强正联结,伴生现象更明显,草本植物与灌木伴生将长期存在。3各草本植物入侵、定植、扩展机制多样。小白花地榆分布广,聚集程度较弱,以种子繁殖为主,扩展速度较快;大白花地榆、小叶章(Calamagrostis angustifolia)等聚集程度较强,以无性繁殖为主,扩展速度较慢,但竞争能力强,在适宜生境中,能驱除其它物种。

长白山岳桦苔原过渡带动态与气候变化

应用样带网格调查方法 ,对长白山岳桦苔原过渡带上岳桦径级结构、分布格局以及过渡带的环境因子进行调查 ,并与最近几十年的极端低温进行了对比研究 ,用格局的差异和径级结构的动态变化来揭示全球变暖对岳桦苔原过渡带的影响。结果表明 :全球气候变暖对长白山岳桦苔原过渡带产生很大影响 ,气候变暖使得岳桦苔原过渡带中的岳桦分布主要以幼苗和幼树为主 ,其中岳桦的径级分布呈倒J字型 ,过渡带中岳桦种群格局呈聚集型分布。整个岳桦种群随着全球气候变暖有一种整体向上迁移的趋势 ,尤其以岳桦苔原过渡带最为明显 ,岳桦苔原过渡带变宽 ,岳桦向苔原侵入的程度加剧。

长白山高山冻原生态系统凋落物养分归还功能

研究了长白山高山冻原生态系统中凋落物量及其养分空间分布特征 ,并对凋落物在养分生物循环中的功能进行了讨论。结果表明 :长白山高山冻原植被凋落物量为 1.378～ 2 .4 76 t/hm2 ,通过对不同海拔凋落物量的数量特征进行分析 ,海拔是影响长白山高山冻原植被凋落物量的主要因子。长白山高山冻原生态系统凋落物中 S、N和 P含量分别为 0 .14 % ,0 .4 9%和0 .2 1% ;3种营养元素在凋落物中积累量为 81.99kg/hm2 ,其中 S、N和 P积累量分别是 15 .0 4 kg/hm2 ,4 5 .93kg/hm2 和2 1.0 2 kg/hm2 。长白山高山冻原生态系统中 5种植被型 (FA,L A,TA,MA和 SA)年归还量依次为 0 .72 ,1.35 ,14 .6 5 ,10 .88和 11.91kg/(hm2· a) ;平均归还率依次 0 .33,0 .4 2 ,0 .39,0 .39和 0 .4 8。典型高山冻原植被型的归还量最大 ,而归还率却较低。长白山高山冻原生态系统内 S、N和 P的利用效率分别是 7.14、2 .0 4和 4 .76。在整个长白山高山冻原生态系统中 S和P的利用效率大于

长白山高山冻原植被生物量的分布规律

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 4 3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 (Rhododendronchrysanthum) (15 9 0 1kg·hm-2 )、笃斯越桔 (Vacciniumjliginosumvar.alpinum)(137 5 2kg·hm-2 )、高山笃斯 (Vacciniumuliginosum) (134 7kg·hm-2 )、宽叶仙女木 (Dryasoctopetalavar .asiatica) (131 5kg·hm-2 )圆叶柳 (Salixrotundifolia) (12 8 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 2 1t·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 .

高山带雪斑对牛皮杜鹃群落生产力的影响

研究了长白山高山带雪斑牛皮杜鹃（Rhododendron aureum）群落的生产力特征及其同微生境条件的关系,以阐明寒冷条件下碳蓄积特征。结合土壤温度连续观测,测定了雪斑不同部位的群落生产力以及土壤养分特征。牛皮杜鹃群落的积雪时间超过240d,土壤温度在-1~0℃的时间长达150d,是非雪斑地段的3倍以上。尽管雪斑的热量条件不如周围优越,但是群落生产力相对高出很多。雪斑中心的牛皮杜鹃群落近3 a的现存量（1707g/m2）是边缘无雪地段（288g/m2）的6倍。雪斑中心的土壤养分水平比周围高,雪斑同时为植物提供了极端低温条件下的避难场所。苔原生态系统生产力的维持依赖于寒冷季节的相对温暖环境,而不是生长季节的热量水平。

长白山苔原带土壤动物群落结构及多样性

长白山苔原生态系统对环境变化非常敏感,一旦破坏很难恢复。土壤动物是陆地生态系统的重要组成部分,联系着地上和地下生态系统。为探讨长白山苔原带土壤动物群落的组成、结构和多样性特征,于2009年5月、7月和9月对上部和下部苔原带土壤动物进行了研究。研究表明:长白山整个苔原带土壤动物优势类群为甲螨亚目、节跳虫科和球角跳虫科。下部苔原亚带土壤动物个体数和类群数多,群落结构较为复杂。土壤动物的个体数随生境和时间变化有很大波动,类群数变化则较小。在7月份个体数最少,而类群数随着时间的变化有减少的趋势。土壤动物的垂直分布随时间和生境的不同而异。上部苔原亚带9月的甲螨亚目(P﹤0.01)、革螨亚目(P﹤0.05)及下部苔原亚带5月的甲螨亚目、革螨亚目、辐螨亚目(P=0.03,P=0.011,P=0.027)0—5 cm土层显著高于凋落物层;下部苔原亚带5月的球角跳虫科(P=0.001)及各月的节跳虫科和山跳虫科在各层之间存在显著差异(P=0.001,P=0.036,P=0.005,P=0.001,P=0.04,P=0.009)。两个亚带土壤动物多样性随时间的变化都有递减的趋势。土壤动物的多样性指数、丰富度指数和均匀度指数均是下部苔原亚带高于上部苔原亚带,而优势度指数则相反。相似性指数表明两个亚带土壤动物群落组成上存在一定的差异,各类群的相对数量差异在9月最大。下部苔原亚带的生境条件较适宜土壤动物生存,生物多样性较高。

氮沉降对长白山苔原植被影响的试验研究

为了探讨氮沉降增加对苔原植被的影响,特别是对草本植物侵入苔原的作用,在长白山高山苔原带进行了连续4 a的人工氮沉降模拟实验,测定3种设定的氮沉降水平下牛皮杜鹃(Rhododendron chrysanthum)、笃斯越橘(Vaccinium uliginosum)和小叶章(Deyeuxia angustifolia)的生长状况和群落结构变化。研究结果表明:1与牛皮杜鹃、笃斯越橘等苔原本地种相比,氮沉降量增加更有利于侵入的小叶章生长;牛皮杜鹃生长对氮沉降量变化响应微弱,氮沉降量增加能明显抑制笃斯越橘的生长。2无小叶章侵入的牛皮杜鹃和笃斯越橘斑块在不同氮沉降量条件下,群落结构变化不明显,氮沉降增加不是小叶章侵入苔原带的直接原因。3在小叶章侵入牛皮杜鹃和笃斯越橘斑块后,氮沉降量增加强化了小叶章的竞争能力,逐渐取代牛皮杜鹃或笃斯越橘,成为优势种,推动高山苔原向高山草甸转化。因此,随着氮沉降量的不断增加,长白山苔原带将面临退化与草甸化。

长白山高山冻原生态系统三种养分含量的空间分布

对长白山高山冻原生态系统中 3种养分 (N、P和 S)在植被 -凋落物 -土壤中的空间分布规律进行了研究。结果表明 :(1)在长白山高山冻原植被亚系统中 ,3种养分总含量分布规律是石质高山冻原 (ST) >典型高山冻原 (TT) >沼泽高山冻原 (WT) >草甸高山冻原 (MT) >石海高山冻原 (RT) ;3种养分积累总量为 72 .4 6 kg· hm- 2 ,其中 N、P和 S分别是 4 8.5 5 kg· hm- 2 ,10 .33kg· hm- 2 和 13.6 1kg· hm- 2 ;生物量与养分积累分布规律是 WT>TT>MT>ST>RT。 (2 )在长白山高山冻原凋落物亚系统中 ,平均凋落物量是 1.96 kg· hm- 2 ;3种养分积累总量为 :82 .5 kg· hm- 2 ,其中 N、P和 S分别是 4 6 .2 8kg· hm- 2 ,2 1.14 kg· hm- 2 和 15 .0 8kg· hm- 2 ;养分积累总量分布规律是 TT>WT>RT>MT>ST。 (3)长白山高山冻原土壤 (0～ 2 0cm)亚系统中 ,养分积累总量为 39.6 t· hm- 2 ,其中 N、P和 S分别是 2 3.76 t· hm- 2 ,5 .86 t· hm- 2和 9.98t· hm- 2。 4 )在长白山高山冻原生态系统中 ,3种养分总积累量为 4 0 6 4 4 .98kg· hm- 2 ,其中 N、P和 S分别是 2 4 734.85 kg· hm- 2 ,10 0 18.7kg·hm- 2 和 5 891.4 3kg· hm- 2 。