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1.
Understanding the effects of degradation on belowground biomass (BGB) is essential for assessment of carbon budget of the alpine meadow ecosystem on the Tibetan Plateau, China. This ecosystem has been undergoing serious degradation owing to climate change and anthropogenic activities. This study examined the response of the vertical distribution of plant BGB to degradation and explored the underlying mechanisms in an alpine meadow on the Tibetan Plateau. A field survey was conducted in an alpine meadow with seven sequential degrees of degradation in the Zoige Plateau on the Tibetan Plateau during the peak growing season of 2018. We measured aboveground biomass (AGB), BGB, soil water content (SWC), soil bulk density (SBD), soil compaction (SCOM), soil organic carbon (SOC), soil total nitrogen (STN), soil total phosphorus (STP), soil available nitrogen (SAN), and soil available phosphorus (STP) in the 0-30 cm soil layers. Our results show that degradation dramatically decreased the BGB in the 0-10 cm soil layer (BGB0-10) but slightly increased the subsoil BGB. The main reason may be that the physical-chemical properties of surface soil were more sensitive to degradation than those of subsoil, as indicated by the remarked positive associations of the trade-off value of BGB0-10 with SWC, SCOM, SOC, STN, SAN, and STP, as well as the negative correlation between the trade-off value of BGB0-10 and SBD in the soil layer of 0-10 cm. In addition, an increase in the proportion of forbs with increasing degradation degree directly affected the BGB vertical distribution. The findings suggest that the decrease in the trade-off value of BGB0-10 in response to degradation might be an adaptive strategy for the degradation-induced drought and infertile soil conditions. This study can provide theoretical support for assessing the effects of degradation on the carbon budget and sustainable development in the alpine meadow ecosystem on the Tibetan Plateau as well as other similar ecosystems in the world.  相似文献   

2.
The change of freeze-thaw pattern of the Tibetan Plateau under climate warming is bound to have a profound impact on the soil process of alpine grassland ecosystem;however,the research on the impact of the freeze-thaw action on nitrogen processes of the alpine grassland ecosystem on the Tibetan Plateau has not yet attracted much attention.In this study,the impact of the freezing strength on the soil nitrogen components of alpine grassland on the Tibetan Plateau was studied through laboratory freeze-thaw simulation experiments.The 0–10 cm topsoil was collected from the alpine marsh meadow and alpine meadow in the permafrost region of Beilu River.In the experiment,the soil samples were cultivated at –10°C,–7°C,–5°C,–3°C and –1°C,respectively for three days and then thawed at 2°C for one day.The results showed that after the freeze-thaw process,the soil microbial biomass nitrogen significantly decreased while the dissolved organic nitrogen and inorganic nitrogen significantly increased.When the freezing temperature was below –7°C,there was no significant difference between the content of nitrogen components,which implied a change of each nitrogen component might have a response threshold toward the freezing temperature.As the freeze-thaw process can lead to the risk of nitrogen loss in the alpine grassland ecosystem,more attention should be paid to the response of the soil nitrogen cycle of alpine grasslands on the Tibetan Plateau to the freeze-thaw process.  相似文献   

3.
The association between biodiversity and belowground biomass (BGB) remains a central debate in ecology. In this study, we compared the variations in species richness (SR) and BGB as well as their interaction in the top (0-20 cm), middle (20-50 cm) and deep (50-100 cm) soil depths among 8 grassland types (lowland meadow, temperate desert, temperate desert steppe, temperate steppe desert, temperate steppe, temperate meadow steppe, mountain meadow and alpine steppe) and along environmental gradients (elevation, energy condition (annual mean temperature (AMT) and potential evapotranspiration (PET)), and mean annual precipitation (MAP)) based on a 2011-2013 survey of 379 sites in Xinjiang, Northwest China. The SR and BGB varied among the grassland types. The alpine steppe had a medium level of SR but the highest BGB in the top soil depth, whereas the lowland meadow had the lowest SR but the highest BGB in the middle and deep soil depths. The SR and BGB in the different soil depths were tightly associated with elevation, MAP and energy condition; however, the particular forms of trends in SR and BGB depended on environmental factors and soil depths. The relationship between SR and BGB was unimodal in the top soil depth, but SR was positively related with BGB in the middle soil depth. Although elevation, MAP, energy condition and SR had significant effects on BGB, the variations in BGB in the top soil depth were mostly determined by elevation, and those in the middle and deep soil depths were mainly affected by energy condition. These findings highlight the importance of environmental factors in the regulations of SR and BGB as well as their interaction in the grasslands in Xinjiang.  相似文献   

4.
BI Xu  LI Bo  NAN Bo  FAN Yao  FU Qi  ZHANG Xinshi 《干旱区科学》2018,10(4):612-627
Soil organic carbon(SOC) and soil total nitrogen(STN) in arid regions are important components of global C and the N cycles, and their response to climate change will have important implications for both ecosystem processes and global climate feedbacks. Grassland ecosystems of Funyun County in the southern foot of the Altay Mountains are characterized by complex topography, suggesting large variability in the spatial distribution of SOC and STN. However, there has been little investigation of SOC and STN on grasslands in arid regions with a mountain-basin structure. Therefore, we investigated the characteristics of SOC and STN in different grassland types in a mountain-basin system at the southern foot of the Altai Mountains, north of the Junggar Basin in China, and explored their potential influencing factors and relationships with meteorological factors and soil properties. We found that the concentrations and storages of SOC and STN varied significantly with grassland type, and showed a decreasing trend along a decreasing elevation gradient in alpine meadow, mountain meadow, temperate typical steppe, temperate steppe desert, and temperate steppe desert. In addition, the SOC and STN concentrations decreased with depth, except in the temperate desert steppe. According to Pearson's correlation values and redundancy analysis, the mean annual precipitation, soil moisture content and soil available N concentration were significantly positively correlated with the SOC and STN concentrations. In contrast, the mean annual temperature, p H, and soil bulk density were significantly and negatively correlated with the SOC and STN concentrations. The mean annual precipitation and mean annual temperature were the primary factors related to the SOC and STN concentrations. The distributions of the SOC and STN concentrations were highly regulated by the elevation-induced differences in meteorological factors. Mean annual precipitation and mean annual temperature together explained 97.85% and 98.38% of the overall variations in the SOC and STN concentrations, respectively, at soil depth of 0–40 cm, with precipitation making the greatest contribution. Our results provide a basis for estimating and predicting SOC and STN concentrations in grasslands in arid regions with a mountain-basin structure.  相似文献   

5.
以新疆天山中段巴音布鲁克主要草地类型为研究对象,分析了不同草地类型土壤有机碳(SOC)的分布特征及其与气候因子、植被特征和土壤特性的关系。结果表明:分布在盆地海拔最低处的高山沼泽化草甸的土壤有机碳含量最高,而分布在盆地中间海拔的高山草原最低,分布在较高海拔的高寒草甸和高山草原化草甸处于高山沼泽化草甸和高山草原之间。0-30cm土壤有机碳含量与空气相对湿度、草地生产力、植被盖度、土壤含水量呈显著正相关(P<0.05),与土壤容重、土壤紧实度、土壤pH呈显著负相关(P<0.05),土壤有机碳与温度存在一定负相关,但未达到显著水平。偏相关分析显示,影响表层土壤有机碳含量最主要的因素是土壤含水量、土壤紧实度、草地生产力、空气相对湿度。  相似文献   

6.
银川平原草甸湿地土壤养分特征与植物响应   总被引:1,自引:0,他引:1  
为探究草甸湿地土壤养分特征,阐明草甸湿地土壤养分对植物养分的影响,在银川平原选取3种生境的草甸湿地(沼泽草甸、典型草甸和盐生草甸)作为研究对象,通过野外调查、实验室分析,结合经典统计学方法对土壤养分及植物养分进行分析。结果表明:①水平梯度上,除全磷(TP)外,3种草甸湿地之间土壤养分含量在土层020cm变化显著(P<0.05)。②在垂直梯度上,全氮(TN)、碱解氮(AN)在盐生草甸中垂直变化不显著(P>0.05),但在典型草甸与沼泽草甸垂直方向上波动幅度较大;TP在草甸湿地土壤中垂直变化不显著(P>0.05);速效磷(AP)与速效钾(AK)在草甸湿地表层具有一定程度的富集效应,并且在不同草甸湿地土层垂直方向上变化显著(P<0.05)。③土壤中C、N和P含量的变化趋势一致;AK与土壤P具有显著的相关性(P<0.05)。④草甸湿地植物养分均表现为N限制,其中C∶N、C∶P与土壤养分呈负相关,植物N∶P受土壤有机碳(SOC)、AN影响较为显著。  相似文献   

7.
Land cover change plays an essential role in the alternation of soils properties.By field investigation and applying satellite images,land cover information in the Shelihu wetland was carried out in an area of 2,819 hm 2 in 1985,1995,2000,2005,2010 and 2011,respectively,in Horqin Sandy Land.A total of 57 soil sampling sites across Shelihu were chosen in wet meadow(CL0),cropland(CL) and sandy land(SL) according to the spatial characteristics of water body change.Soil texture,organic carbon(SOC),total nitrogen(TN) and total phosphorus(TP) contents,electrical conductivity(EC) and pH were measured at the soil depths of 0-10,10-20 and 20-40 cm to examine the influence of agricultural conversion and continuous cultivation on soil properties.The results showed that the study area was covered by water body in 1985,which gradually declined afterwards and then reclaimed rapidly at a mean annual rate of 132.1 hm 2 /a from wet meadow to cropland since 1995.In 2011,water body was drained and the area was occupied by 10.8% of CL0,76.9% of CL and 12.3% of SL.Large amounts of SOC,TN and TP were accumulated in the above depths in CL0.Soil in CL0 also had higher EC and silt and clay fractions,lower pH than in SL and CL.Soil in SL was seriously degraded with lower contents of SOC,TN and TP than in CL and CL0.SOC,TN content and EC in CL decreased with the increase of cultivation age,while pH showed a reverse trend with significance at plough horizon.The agricultural conversion in Shelihu was driven by the comprehensive factors of precipitation reduction,economic development and intense competitions for irrigation water.Continuous cultivation in this process is not sustainable because of SOC degradation and nutrient content reduction.The key point is that conventional tillage and removal of residuals induced further land degradation.Wetland reclamation for immediate economic interests led to greater costs in the long-term environmental restoration in Horqin Sandy Land.  相似文献   

8.
在东祁连山高寒草地,对围栏7年和不同放牧强度的草地进行了物种数、地上生物量、地下生物量、土壤理化性质等研究。结果表明,围栏7年的高寒草地鲜草产量为425.8 g·m-2,显著高于夏季中牧159.3 g·m-2和夏季重牧91.0 g·m-2,但与冬季轻牧、夏季轻牧差异不显著。围栏条件下的物种数为26.3种·16 m-2,显著低于其他放牧条件下的物种数,但显著高于夏季重牧条件下的物种数23.0种·16 m-2;轻度或重度放牧都会使物种数减少,夏季中牧下的物种数最高(33.5种·16 m-2)。在0~10 cm的表层土壤中,围栏7年的草地根系生物量显著高于其他放牧强度。随着放牧强度的增加,根系生物量在0~10 cm土壤中呈下降趋势,在30~40 cm土壤中则表现为升高趋势。围栏7年的土壤容重低于其他放牧强度下的土壤容重,但差异不显著;夏季重牧的土壤容重显著高于围栏7年和其他放牧强度的土壤容重。随着放牧强度的增加,0~10 cm土壤碱解氮增加,围栏7年草地最低。围栏封育可有效改善和恢复草地植被,但不能长时间禁牧不进行放牧利用。合理的放牧能够维护高寒草甸草地生态系统功能、促进物种丰富度和土壤营养的均衡。  相似文献   

9.
ManHou XU 《干旱区科学》2015,7(2):189-204
Climate warming and livestock grazing are known to have great influences on alpine ecosystems like those of the Qinghai-Tibetan Plateau(QTP) in China. However, it is lacking of studies on the effects of warming and grazing on plant and soil properties in these alpine ecosystems. In this study, we reported the related research from manipulative experiment in 2010–2012 in the QTP. The aim of this study was to investigate the individual and combined effects of warming and clipping on plant and soil properties in the alpine meadow ecosystem. Infrared radiators were used to simulate climate warming starting in July 2010, while clipping was performed once in October 2011 to simulate the local livestock grazing. The experiment was designed as a randomized block consisting of five replications and four treatments: control(CK), warming(W), clipping(C) and warming+clipping combination(WC). The plant and soil properties were investigated in the growing season of the alpine meadow in 2012. The results showed that W and WC treatments significantly decreased relative humidity at 20-cm height above ground as well as significantly increases air temperature at the same height, surface temperature, and soil temperature at the depth of 0–30 cm. However, the C treatment did not significantly decrease soil moisture and soil temperature at the depth of 0–60 cm. Relative to CK, vegetation height and species number increased significantly in W and WC treatment, respectively, while vegetation aboveground biomass decreased significantly in C treatment in the early growing season. However, vegetation cover, species diversity, belowground biomass and soil properties at the depth of 0–30 cm did not differ significantly in W, C and WC treatments. Soil moisture increased at the depth of 40–100 cm in W and WC treatments, while belowground biomass, soil activated carbon, organic carbon and total nitrogen increased in the 30–50 cm soil layer in W, C and WC treatments. Although the initial responses of plant and soil properties to experimental warming and clipping were slow and weak, the drought induced by the downward shift of soil moisture in the upper soil layers may induce plant belowground biomass to transfer to the deeper soil layers. This movement would modify the distributions of soil activated carbon, organic carbon and total nitrogen. However, long-term data collection is needed to further explain this interesting phenomenon.  相似文献   

10.
Alpine meadow ecosystem is fragile and highly sensitive to climate change.An understanding of the allocation of above-and below-ground plant biomass and correlations with environmental factors in alpine meadow ecosystem can result in better protection and effective utilization of alpine meadow vegetation.We chose an alpine meadow in the Qinghai-Tibetan Plateau of China as the study area and designed experimental warming plots using a randomized block experimental design.We used single-tube infrared radiators as warming devices,established the warming treatments,and measured plant above- (AGB) and below-ground biomass (BGB) during the growing seasons (May to September) in 2012 and 2013.We determined the allocation of biomass and the relationship between biomass and soil environment under the warming treatment.Biomass indices including above-ground biomass,below-ground biomass and the ratio of root to shoot (R/S) ,and soil factors including soil moisture and soil temperature at different depths were measured.The results showed that (1) BGB of the alpine meadow had the most significant allometric correlation with its AGB (y=298.7x~ (0.44) ,P0.001) ,but the relationship decreased under warming treatment and the determination coefficient of the functional equation was 0.102 which was less than that of 0.188 of the unwarming treatment (control) ; (2) BGB increased,especially in the deeper soil layers under warming treatment (P0.05) .At 0–10 cm soil depth,the percentages of BGB under warming treatment were smaller than those of the control treatment with the decreases being 8.52% and 8.23% in 2012 and 2013,respectively.However,the BGB increased 2.13% and 2.06% in 2012 and 2013,respectively,at 10–50 cm soil depths; (3) BGB had significant positive correlations with soil moisture at 100 cm depth and with soil temperature at 20–100 cm depths (P0.05) ,but the mean correlation coefficient of soil temperature was 0.354,greater than the 0.245 of soil moisture.R/S ratio had a significant negative correlation with soil temperature at 20 cm depth (P0.05) .The warmer soil temperatures in shallow layers increased the biomass allocation to above-ground plant parts,which leading to the increase in AGB;whereas the enhanced thawing of frozen soil in deep layers causing by warming treatment produced more moisture that affected plant biomass allocation.  相似文献   

11.
Chenopodiaceae is one of the most important families in arid and saline environments. Several studies have observed the mycorrhizal structure in Chenopodiaceae plants(i.e., chenopods), but the mycorrhizal colonization status of chenopods in saline habitats and the influencing factors are still not well understood. The mycorrhizal colonization of twenty chenopod species in three different saline habitats(a saline alkaline meadow in the Songnen Plain of northeastern China, a saline desert in the Junggar Basin of northwestern China, and a saline alpine meadow in the Tibetan Plateau of western China) and the chenopod-associated environmental factors(including soil moisture, soil available phosphorous(P) concentration, pH, and salt content) were analyzed. Our results showed that approximately 60% of the studied chenopods were colonized by arbuscular mycorrhizal(AM) fungi with a colonization percentage ranging from 5% to 33%. Structural analysis of mycorrhizal association indicated that vesicles were quite common, while arbuscules and hyphal coils were relatively rare. In addition, a positive correlation between mycorrhizal colonization rate and soil electrical conductivity(r=0.920, P0.01) and two negative correlations of mycorrhizal colonization rates with soil moisture(r= –0.818, P0.01) and the soil available P concentration(r= –0.876, P0.01) confirmed that mycorrhizal colonization rate in the roots of chenopods was environment-dependent.  相似文献   

12.
Knowledge of soil carbon(C) distribution and its relationship with the environment can improve our understanding of its biogeochemical cycling and help to establish sound regional models of C cycling. However, such knowledge is limited in environments with complex landscape configurations. In this study, we investigated the vertical distribution and storage of soil organic carbon(SOC) and soil inorganic carbon(SIC) in the 10 representative landscapes(alpine meadow, subalpine shrub and meadow, mountain grassland, mountain forest, typical steppe, desert steppe, Hexi Corridor oases cropland, Ruoshui River delta desert, Alxa Gobi desert, and sandy desert) with contrasting bioclimatic regimes in the Heihe River Basin, Northwest China. We also measured the 87 Sr/86 Sr ratio in soil carbonate to understand the sources of SIC because the ratio can be used as a proxy in calculating the contribution of pedogenic inorganic carbon(PIC) to total SIC. Our results showed that SOC contents generally decreased with increasing soil depth in all landscapes, while SIC contents exhibited more complicated variations along soil profiles in relation to pedogenic processes and parent materials at the various landscapes. There were significant differences of C stocks in the top meter among different landscapes, with SOC storage ranging from 0.82 kg C/m~2 in sandy desert to 50.48 kg C/m~2 in mountain forest and SIC storage ranging from 0.19 kg C/m~2 in alpine meadow to 21.91 kg C/m~2 in desert steppe. SIC contributed more than 75% of total C pool when SOC storage was lower than 10 kg C/m~2, and the proportion of PIC to SIC was greater than 70% as calculated from Sr isotopic ratio, suggesting the critical role of PIC in the C budget of this region. The considerable variations of SOC and SIC in different landscapes were attributed to different pedogenic environments resulted from contrasting climatic regimes, parent materials and vegetation types. This study provides an evidence for a general trade-off pattern between SOC and SIC, showing the compensatory effects of environmental conditions(especially climate) on SOC and SIC formation in these landscapes. This is largely attributed to the fact that the overall decrease in temperature and increase in precipitation from arid deserts to alpine mountains simultaneously facilitate the accumulation of SOC and depletion of SIC.  相似文献   

13.
陕西省眉县猕猴桃园土壤碳氮磷生态化学计量学特征   总被引:2,自引:0,他引:2  
以眉县猕猴桃园土壤为研究对象,对土壤pH值、含水率、有机碳(SOC)、总氮(TN)、总磷(TP)的分布及其生态化学计量学特征进行研究。结果表明:研究区域猕猴桃园土壤含水率、pH值、SOC、TN和TP含量均存在显著性差异,分别处于1.12%~3.46%、7.12~8.40、4.22~13.90 g·kg~(-1)、0.77~1.84 g·kg~(-1)和0.73~2.45 g·kg~(-1)之间,均值分别为2.73%、7.83、7.66 g·kg~(-1)、1.20 g·kg~(-1)和1.40 g·kg~(-1),其表现C、N元素相对匮乏,而P元素相对丰富;其次,不同区域及不同品种园区土壤中C、N和P的生态化学计量学特征均存在显著性差异,C/N、C/P和N/P的变异系数分别为28.30%、35.71%和21.15%,变化范围分别为3.06~11.99、2.68~10.90和0.48~1.41,均值分别为6.57、5.91和0.90,均低于全国平均水平;相关分析表明,在0.05水平上,pH值与C/P呈显著正相关性;在0.01水平上,pH值与TN、pH值与TP、TN与C/N、TN与C/P、TP与C/N、TP与C/P、TP与N/P呈显著的负相关性,pH值与C/N、SOC与C/N、SOC与C/P、TN与TP、C/N与C/P及C/P与N/P呈显著正相关性。  相似文献   

14.
Ecosystems in high-altitude regions are more sensitive and respond more rapidly than other ecosystems to global climate warming.The Qinghai-Tibet Plateau(QTP)of China is an ecologically fragile zone that is sensitive to global climate warming.It is of great importance to study the changes in aboveground biomass and species diversity of alpine meadows on the QTP under predicted future climate warming.In this study,we selected an alpine meadow on the QTP as the study object and used infrared radiators as the warming device for a simulation experiment over eight years(2011-2018).We then analyzed the dynamic changes in aboveground biomass and species diversity of the alpine meadow at different time scales,including an early stage of warming(2011-2013)and a late stage of warming(2016-2018),in order to explore the response of alpine meadows to short-term(three years)and long-term warming(eight years).The results showed that the short-term warming increased air temperature by 0.31℃and decreased relative humidity by 2.54%,resulting in the air being warmer and drier.The long-term warming increased air temperature and relative humidity by 0.19℃and 1.47%,respectively,and the air tended to be warmer and wetter.The short-term warming increased soil temperature by 2.44℃and decreased soil moisture by 12.47%,whereas the long-term warming increased soil temperature by 1.76℃and decreased soil moisture by 9.90%.This caused the shallow soil layer to become warmer and drier under both short-term and long-term warming.Furthermore,the degree of soil drought was alleviated with increased warming duration.Under the long-term warming,the importance value and aboveground biomass of plants in different families changed.The importance values of grasses and sedges decreased by 47.56%and 3.67%,respectively,while the importance value of weeds increased by 1.37%.Aboveground biomass of grasses decreased by 36.55%,while those of sedges and weeds increased by 8.09%and 15.24%,respectively.The increase in temperature had a non-significant effect on species diversity.The species diversity indices increased at the early stage of warming and decreased at the late stage of warming,but none of them reached significant levels(P>0.05).Species diversity had no significant correlation with soil temperature and soil moisture under both short-term and long-term warming.Soil temperature and aboveground biomass were positively correlated in the control plots(P=0.014),but negatively correlated under the long-term warming(P=0.013).Therefore,eight years of warming aggravated drought in the shallow soil layer,which is beneficial for the growth of weeds but not for the growth of grasses.Warming changed the structure of alpine meadow communities and had a certain impact on the community species diversity.Our studies have great significance for the protection and effective utilization of alpine vegetation,as well as for the prevention of grassland degradation or desertification in high-altitude regions.  相似文献   

15.
高寒草甸不同类型草地土壤机械组成及肥力比较   总被引:3,自引:0,他引:3  
研究了青藏高原高寒草甸不同类型草地土壤机械组成和土壤养分变化特征,并用相关分析探讨了土壤理化特征、土壤机械组成对不同草地类型群落物种组成、生物量变化的响应。结果表明:不同草地类型土壤机械组成分布大致是矮嵩草草甸:粉粒>细砂粒>粘粒>粗砂粒;高山嵩草草甸:细砂粒>粉粒>粘粒>粗砂粒;藏嵩草沼泽化草甸:细砂粒>粉粒>粘粒>粗砂粒;金露梅灌丛:粉粒>粘粒≥细砂粒>粗砂粒。矮嵩草草甸、高山嵩草草甸为粉砂质粘壤土,藏嵩草沼泽化草甸为壤土,金露梅灌丛为壤质粘土。矮嵩草草甸、高山嵩草草甸和金露梅灌丛土壤颗粒分布相对比较均匀(除藏嵩草沼泽化草甸外),主要集中在<0.5mm的范围内,土壤粘粒含量普遍大于20%。土壤全量养分和速效养分以及土壤物理特征均影响着高寒草甸不同草地类型土壤质量和土壤结构。土壤结构和养分状况是判断高寒草甸生态系统生态功能维持的关键指标之一。  相似文献   

16.
分析高寒草甸植被生育期耗水量及植被生物量积累与气象因子的关系,结果表明植被生育期耗水量呈单峰型变化过程,7月耗水量最大。初期营养生长阶段的5月耗水量、植被生物量均较低,水分影响着植物的初期营养生长但不甚显著;植物旺盛生长的6~7月,耗水量高,而生物量波动明显,温度和水分均影响到生物量的提高,且水分是影响植被生长的关键因素;植物生长末期的8~9月,耗水量及植被阶段累积生物量均较低,水分条件充足,并非是植物生长的限制因素。海北高寒草甸地区植被年地上净初级生产量、地下净初级生产量、净初级生产量与植被耗水量关系不明显。而与相应的温度具有较显著的正相关关系。表明高寒草甸地区植被净初级生产量受温度条件限制的影响比水分条件更为明显。  相似文献   

17.
不同草地类型土壤有效态微量元素含量特征   总被引:11,自引:1,他引:10  
以贺兰山西坡不同草地类型土壤为对象,研究了土壤中微量元素Fe,Mn,Zn,Cu有效态含量特征及土壤有机碳、pH值、黏粉粒含量与气候因素之间的相互关系。结果表明:土壤有效态Fe,Mn,Zn的含量随着海拔的降低而逐渐降低,有效态Cu含量的积累顺序为:山地草原>荒漠化草原>高山草甸>草原化荒漠。4种元素在各种草地类型的积累量变化为:高山草甸Fe>Mn>Zn和Cu;山地草原和荒漠化草原Fe>Mn>Cu>Zn,草原化荒漠土壤中Fe和Mn含量差异不大,并大于Zn和Cu。土壤有效态Fe,Mn,Zn的含量与年均降水量、土壤有机碳、<0.05 mm黏粉粒含量都呈显著正相关,而与年均温度和土壤pH值呈显著负相关。土壤有效态Cu含量与年降水量、年均温度、土壤有机碳含量和<0.05 mm黏粉粒含量基本呈二次多项式,而与土壤pH相关性不显著。影响土壤有效态Fe和Mn含量的关键因素,0~20 cm土层为有机碳、年降水量和年均温,而20~40 cm土层土壤有机碳是其最重要的影响因素。0~20 cm土层土壤有效态Zn主要受土壤pH、黏粉粒含量和年降水量的影响。  相似文献   

18.
HAI Xuying 《干旱区科学》2022,14(10):1109-1123
Manipulated precipitation patterns can profoundly influence the metabolism of soil microorganisms. However, the responses of soil organic carbon (SOC) and nutrient turnover to microbial metabolic limitation under changing precipitation conditions remain unclear in semi-arid ecosystems. This study measured the potential activities of enzymes associated with carbon (C: β-1,4-glucosidase (BG) and β-D-cellobiosidase (CBH)), nitrogen (N: β-1,4-N-acetylglucosaminidase (NAG) and L-leucine aminopeptidase (LAP)) and phosphorus (P: alkaline phosphatase (AP)) acquisition, to quantify soil microbial metabolic limitations using enzymatic stoichiometry, and then identify the implications for soil microbial metabolic limitations and carbon use efficiency (CUE) under decreased precipitation by 50% (DP) and increased precipitation by 50% (IP) in a temperate grassland. The results showed that soil C and P were the major elements limiting soil microbial metabolism in temperate grasslands. There was a strong positive dependence between microbial C and P limitations under manipulated precipitation. Microbial metabolism limitation was promoted by DP treatment but reversed by IP treatment. Moreover, CUE was inhibited by DP treatment but promoted by IP treatment. Soil microbial metabolism limitation was mainly regulated by soil moisture and soil C, N, and P stoichiometry, followed by available nutrients (i.e., NO- 3, NH+ 4, and dissolved organic C) and microbial biomass (i.e., MBC and MBN). Overall, these findings highlight the potential role of changing precipitation in regulating ecosystem C turnover by limiting microbial metabolism and CUE in temperate grassland ecosystems.  相似文献   

19.
贺兰山西坡不同类型草地土壤酶活性特征   总被引:3,自引:0,他引:3  
以阿拉善左旗境内贺兰山中段(西坡)山前地带的主要草地类型为对象,分析不同类型草地土壤酶活性的分布特征,及其与气候、植被和土壤等环境因子的关系。结果表明:① 随着海拔高度的降低,土壤脲酶、蔗糖酶、碱性磷酸酶和过氧化氢酶活性表现为:高山草甸>山地草原>山地荒漠草原>草原化荒漠,且在0~10 cm土层的差异尤其显著;② 各类草地土壤酶活性均沿土壤垂直剖面依次降低,差异呈显著性水平;③ 偏相关及逐步回归分析表明,影响该区草地土壤脲酶和蔗糖酶活性最主要的因素为土壤微生物碳氮、有机碳和全氮,碱性磷酸酶主要受土壤微生物碳和全氮影响,对过氧化氢酶影响最大的因子为土壤微生物碳、pH、全氮和降水量。  相似文献   

20.
天山南坡高寒草地物种多样性及地上生物量研究   总被引:8,自引:0,他引:8  
在新疆天山巴音布鲁克草原对高寒草甸、高寒草原和高寒草甸化草原的物种多样性进行了研究,结果表明:盖度+高度指标测度群落物种多样性指数要优于盖度和株数指标,更适于测度高寒草地的物种多样性指数。丰富度指数、Margalef指数与Shannon-wiener指数相关性显著,在小的空间研究尺度内,草地植物群落物种多样性指数受丰富度指数的影响较大。地上生物量与丰富度指数、Margalef指数和Shannon-wiener指数呈负相关关系。  相似文献   

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