模拟放牧斑块与氮素添加对半干旱草原群落植物生长的影响

放牧时,动物采食及其排泄物会影响植物的生长,但动物彩食及其排泄物的空间异质性可能会影响这咱效应.在位于我国北方典型农牧交错区的内蒙古多伦县,我们研究了模拟入牧斑块和施氧肥对植物生长的影响,实验采用模拟放牧采食斑块(观割半径分别0、10、20、40和8cm)和土壤施氮(分别为0、5、20Gn\m2)两种处理,植物地上部收获后分为绿体和立柯两部分,并分析其含氮量.结果表明,刈割降低了植物的生物量(40.5%),而施氮可增加生物量(57.8%)刈割交通规则植物生长的抑制作用在面积最水又施肥的斑块上表现更明显.土壤施氮可以促进杜物生长并且影响刈割效应.同时植物的绿-枯比阻碍施氮水平的增回而增回,因此氮会延迟植物的衰老.以上结果表明,刈割(模拟动物采食)斑块的大小会影响草原植物的生长,土壤施氮(模拟动物尿氮)可以提高草原生态系统的初级生产力,并影响刈割效应.     

放牧和刈割对内蒙古典型草原土壤可提取碳和氮的影响

依托内蒙古典型草原的长期野外放牧控制试验,探讨了放牧和刈割对土壤有机碳、全氮、可提取碳和氮、微生物生物量碳和氮的影响.结果表明: 放牧使可提取有机碳降低11.4%～37.1%,而刈割使可提取有机碳升高5.8%.放牧和刈割分别使可提取氮升高10%～340%和10%～240%.放牧强度不高于6.0 sheep·hm^-2的条件下有利于维持甚至增加微生物生物量碳,而重度放牧(7.5和9.0 sheep·hm^-2)则减少微生物生物量碳.刈割处理下微生物生物量碳和氮分别升高31.0%和9.8%.通径分析表明,放牧处理下微生物生物量碳的主要影响因素是有机碳、可提取全氮和全氮,其中直接影响因素是有机碳和可提取全氮;微生物生物量氮的主要影响因素是土壤pH、可提取有机碳、有机碳和可提取全氮,其中直接影响因素是有机碳和可提取全氮.刈割及轻度和中度放牧有利于维持或改善土壤功能,重度放牧将引起土壤退化.     

内蒙古草甸草原土壤理化性质和微生物学特性对刈割与氮添加的响应

频繁的刈割和氮输入增加是导致草地生态系统退化的重要原因.土壤微生物学特性作为评估土壤质量的重要生物学指标,对草地刈割和氮输入增加的响应规律仍不十分明确.本研究依托内蒙古呼伦贝尔草原刈割复合氮添加野外实验平台,分析了土壤理化性质、土壤微生物生物量、土壤呼吸和土壤酶对刈割、氮添加的响应及其生长季动态变化.结果表明: 刈割显著降低了土壤微生物生物量碳、氮、磷和土壤呼吸(基础呼吸和底物诱导呼吸),与刈割后导致的水分限制及碳限制有关.刈割显著降低了氮磷获取酶(N-乙酰-β-D-葡萄糖苷酶和酸性磷酸单酯酶)的活性,符合“资源分配假说”.氮添加显著降低土壤pH值,但土壤微生物生物量对氮添加和pH降低均无显著响应,表明氮输入增加引起的土壤酸化不是影响微生物生物量的主要因素.氮添加对土壤呼吸和酶活性也无显著影响,与以往在典型草原的大多数研究结果不一致.刈割和氮添加复合处理显著降低了土壤微生物生物量磷,但提高了土壤中有效磷含量,降低了酸性磷酸酶活性.微生物生物量碳、氮、磷和土壤呼吸等的相关参数均在7月最高,这与夏季高温多雨有关.土壤酶活性在春夏季较高,生长季末期较低.这表明在该草甸草原,刈割将导致土壤碳氮磷养分失衡,从而加剧草原退化;而氮添加在短期内并未对土壤微生物生物量和活性产生显著影响.     

短期氮素添加和模拟放牧对青藏高原高寒草甸生态系统呼吸的影响

氮沉降和放牧是影响草地碳循环过程的重要环境因子,但很少有研究探讨这些因子交互作用对生态系统呼吸的影响。在西藏高原高寒草甸地区开展了外源氮素添加与刈割模拟放牧实验,测定了其对植物生物量分配、土壤微生物碳氮和生态系统呼吸的影响。结果表明:氮素添加显著促进生态系统呼吸,而模拟放牧对其无显著影响,且降低了氮素添加的刺激作用。氮素添加通过提高微生物氮含量和土壤微生物代谢活性,促进植物地上生产,从而增加生态系统的碳排放;而模拟放牧降低了微生物碳含量,且降低了氮素添加的作用,促进根系的补偿性生长,降低了氮素添加对生态系统碳排放的刺激作用。这表明,放牧压力的存在会抑制氮沉降对高寒草甸生态系统碳排放的促进作用,同时外源氮输入也会缓解放牧压力对高寒草甸生态系统生产的负面影响。     

放牧和刈割对内蒙古典型草原大型土壤动物的影响

采用连续3年全季节放牧、3种季节性轮牧、秋季刈割和不利用对照6种处理, 研究了内蒙古典型草原大型土壤动物群落特征.调查在春、夏和秋3个季节进行,共捕获大型土壤动物597只,隶属于2门4纲11目,49个类群.结果表明: 全季节放牧导致土壤动物的个体密度、生物量和多样性降低;而刈割的影响相对较轻,土壤动物的个体密度、生物量和多样性甚至有提高趋势.3种季节性轮牧处理中,夏季和秋季放牧2次处理对土壤动物群落个体密度、生物量和多样性等指标的负面影响较轻.刈割管理对退化典型草原大型土壤动物群落的恢复较为有利;夏季和秋季放牧2次处理对大型土壤动物群落的负面影响较轻,是较理想的草地可持续管理措施.     

模拟升温和放牧对高寒草甸土壤有机碳氮组分和微生物生物量的影响

土壤活性、惰性有机质库和微生物生物量在数量和分配上的变化是陆地生态系统土壤有机质贮存和动态变化的决定性因素。采用OTCs(Open top chambers)升温以及刈割+粪便归还的方法,对青藏高原东部高寒草甸土壤有机碳氮组分和微生物生物量对气候变暖和放牧的响应进行了研究。结果表明,模拟升温在短期内显著降低土壤活性有机碳Ⅰ、活性有机氮Ⅰ和惰性有机碳的含量,而由于粪便归还作用,放牧明显增加土壤活性有机碳、氮Ⅰ的含量。模拟升温和放牧对有机碳、氮组分的作用效应相互抵消,两者共同作用下有机碳、氮组分仅略有降低。单一的模拟升温或放牧没有显著改变微生物生物量碳,但是两者共同作用却能够大大增加微生物生物量碳。放牧和取样时间存在着明显的交互作用,放牧效应随时间递减。本研究表明,气候变暖对放牧草甸有机碳、氮组分影响不大;放牧过程中的牲畜粪便归还作用不容忽视。     

放牧对若尔盖高原湿地CH4排放的影响

湿地是大气甲烷(CH_4)的主要排放源,而有关放牧对湿地CH_4排放的影响特征仍未得到足够的报道。因此,通过静态箱法,研究了放牧对四川省若尔盖高原湿地CH_4排放的影响,CH_4气体通过快速温室气体分析仪测量。结果表明:放牧样地和围栏内样地生长季CH_4排放量为(31.32±19.57)g/m~2和(30.31±23.46)g/m~2,它们之间无差异显著;但是集中放牧期间(7—9月),放牧样地(21.01±12.35)g/m~2较围栏内样地显著增加了CH_4排放量为54.3%。2014年生长季期间通过刈割植物模拟放牧表明两种刈割强度CH_4排放量为(5.01±5.37)g/m~2和(4.69±5.99)g/m~2,较未刈割样地(1.15±1.89)g/m~2增加了335.9%和308.0%,其原因可能是放牧或者刈割减少地表植物生物量,降低植物高度,缩短了CH_4排放的路径距离。该结果可为我国高原湿地保护与管理决策提供基础数据支撑。     

盐碱条件下刈割干扰对羊草的氮素分配策略及补偿生长的影响

土地盐碱化和过度放牧是制约松嫩平原畜牧业发展的两大因素,羊草是松嫩平原上的优势种,被认为具有较强的耐牧及耐盐碱能力.本文通过田间原位试验,以叶面涂抹标记¹⁵N-尿素的方法,研究了不同盐碱条件下刈割干扰对羊草的氮素分配策略及补偿生长的影响.结果表明: 总体上叶面新吸收的氮60%以上保留在地上部分.与不施盐碱无刈割处理的对照相比,单纯的盐碱胁迫使新吸收的氮在细根中的分配率显著增加了5.1%;而盐碱胁迫下,中度刈割使叶面新吸收的氮在地上部分的分配率增加了11.6%,地上及总生物量发生超补偿生长,但是重度刈割使叶面新吸收的氮在茎基部的分配率显著增加了9.5%,地上、细根及总生物量均表现为欠补偿生长.上述结果表明盐碱胁迫下,中度刈割干扰时羊草采取积极的再生策略,促进其超补偿生长,但在重度刈割时羊草会采取增加氮素在茎基部存储的相对保守的氮素分配和生长策略.     

刈割对草原化荒漠区驼绒藜(Krascheninnikovia ceratoides)根际土壤特性的影响

在休眠期对草原化荒漠中自然生长的驼绒藜(Krascheninnikovia ceratoides)进行不同频度的刈割处理(连年刈割、隔年刈割、对照),通过测定根际土壤理化性质、土壤微生物数量及土壤酶活性等指标,分析和讨论了不同频度的刈割处理对驼绒藜根际土壤特性的影响。结果表明:(1)连年刈割和隔年刈割都显著提高了根际土壤含水量,隔年刈割使根际土壤全碳含量显著上升、有机质含量显著下降,但刈割对根际土壤pH值和全氮含量的影响不明显;(2)刈割对根际土壤微生物总量的影响不明显,但显著影响细菌、真菌和放线菌的组成,连年刈割使真菌数量显著增加,隔年刈割使放线菌数量显著增加,驼绒藜根际土壤中放线菌所占比例最大,其数量表征了土壤的贫瘠程度;(3)刈割对根际土壤过氧化氢酶和中性磷酸酶活性有显著影响,两种刈割处理会显著提高土壤过氧化氢酶活性、降低土壤中性磷酸酶活性,而对土壤多酚氧化酶、脲酶、转化酶和碱性磷酸酶活性的影响不显著。总之,隔年刈割对植物根际土壤养分供给及土壤分解者的活性更加有利,而且土壤理化因子对土壤微生物数量和土壤酶活性的影响不显著。刈割对驼绒藜根际土壤特性影响的规律性不强,可能是由于半灌木刈割利用的时间较短,根际土壤各个测量指标之间尚未形成显著的相关性。     

Effects of nitrogen addition and mowing on nitrogen- and water-use efficiency of Artemisia frigida in a grassland restored from an abandoned cropland

氮添加和刈割对内蒙古弃耕草地冷蒿氮和水分利用效率的影响 在氮和水分限制的区域，植物氮利用效率(NUE)和水分利用效率(WUE)决定了它们在群落中的竞争优势。冷蒿(Artemisia frigida)是半干旱草地重度退化的先锋物种，在不同退化程度的草地中具有不 同的优势度，经常被认为是退化草地群落演替的指示物种。退化草地恢复过程中，氮添加和割草如何影响冷蒿的NUE和WUE尚不清晰。以内蒙古多伦县弃耕草地为研究对象，选取两个不同群落斑块(禾草和冷蒿为优势物种的斑块)，经过长期(2006–2013)氮添加和刈割(对照、氮添加、刈割、氮添加+刈割)处理后，研究冷蒿的NUE (叶片碳氮比)和WUE (叶片碳同位素，δ¹³C)对氮添加、刈割及其交互作用的响应； 结合植物和土壤的碳、氮同位素(δ¹³C和δ¹⁵N)及碳、氮库探究退化草地恢复过程中植物的资源利用策略及其机制。研究结果表明：(1)氮添加对冷蒿的WUE没有显著影响(P > 0.05)，但NUE 在禾草和冷蒿斑块 中分别显著降低了42.9%和26.6% (P < 0.05)；(2)植物对不同氮源(NH₄₊或NO_3-)的利用会引起植物和土壤δ¹⁵N的分馏，研究表明叶片和土壤的δ¹⁵N与NUE呈现相反的变化趋势，因此冷蒿的NUE对氮添加的响应与不同氮源的利用有关；(3)刈割不影响冷蒿的NUE (P > 0.05)，但在禾草斑块，冷蒿的WUE在刈割处理下显著提高了2.3% (P < 0.05)；(4)在禾草斑块，氮添加减缓了割草对冷蒿WUE的促进作用；(5)结构方程模型显示，土壤含水量直接或间接的调控着冷蒿的WUE和NUE。综上所述，在禾草斑块，氮添加+刈割处理维持较低的NUE和WUE，不利于冷蒿对资源的竞争，进一步降低其优势度，这也预示着氮添加+ 刈割处理会促进退化草地的恢复。     

Effects of grazing pattern and nitrogen availability on primary productivity

A major part of the impact of grazing on primary productivity results from the joint action of tissue removal and nutrient return to the soil via dung and urine. Grazing, however, is not uniformly distributed in space: grazed grasslands show a matrix of grazed and ungrazed patches, which in turn, may or may not be affected by faecal or urine deposition. This paper investigates the effects of grazing spatial pattern and nitrogen availability on primary productivity. We propose that grazed plants located at the edge of a grazed patch are more shaded by their taller ungrazed neighbours than plants at the center. Since the border effect is less important as patch size increases, the effects of grazing will be more positive, or less negative, when grazing pattern is coarse-grained than when it is fine-grained. We also propose that nitrogen availability will affect this response to grazing through its effects on the intensity of competition for light and on the amount of compensatory growth. We performed a field experiment in a grassland community of the Flooding Pampa, Argentina, in which we compared the productivity of undefoliated controls and defoliated patches of different size, with and without nitrogen application. Defoliation reduced primary productivity and this effect was greater in the smallest, fertilized patches. Productivity was highest at patches of intermediate and large sizes. Nitrogen addition increased productivity by two-fold. The integrated photon flux density reaching the base of the canopy was affected by defoliation and by patch size: it was lower in controls than in defoliated patches and increased with patch size. Our results showed that (a) the size of the defoliated patch modified the response of this grassland to defoliation, (b) this response was correlated with light availability, and (c) nitrogen addition, simulating urine depositions, increased primary productivity and affected the response to defoliation of the smallest patches.     

Small mammalian herbivore determines vegetation response to patchy nutrient inputs

Nutrient inputs to plant communities are often spatially heterogeneous, for example those deriving from the dung and urine of large grazing animals. The effect of such localised elevation of nutrients on plant growth and composition has been shown to be modified by the grazing of large herbivores. However, there has been little work on interactions between small mammalian herbivores and such patchy nutrient inputs, even though these interactions are potentially of major significance for plant performance and community structure.
We examined the effect of simulated cattle urine deposition on the vegetation structure, above-ground biomass and species composition of chalk grassland within enriched patches. Short-term exclosures were used to determine whether a small herbivore (rabbit) would preferentially graze the vegetation in enriched patches and what impact this interaction would have on the performance of plants in such patches. Rabbit grazing pressure determined whether nutrient inputs had a negative or positive effect on plant biomass. Nutrients increased plant biomass in the absence of grazing, but when exposed to grazing, plants in nutrient-rich patches had more biomass consumed by herbivores than neighbouring plants. Further, nutrients increased the relative palatability of a less preferred forage species ( Brachypodium pinnatum ), contributing to changes in plant community composition. We conclude that a small herbivore can drive plant responses to patchily distributed nutrients.     

Defoliation of a grass is mediated by the positive effect of dung deposition,moss removal and enhanced soil nutrient contents: results from a reindeer grazing simulation experiment

Herbivory is one of the key drivers shaping plant community dynamics. Herbivores can strongly influence plant productivity directly through defoliation and the return of nutrients in the form of dung and urine, but also indirectly by reducing the abundance of neighbouring plants and inducing changes in soil processes. However, the relative importance of these processes is poorly understood. We, therefore, established a common garden experiment to study plant responses to defoliation, dung addition, moss cover, and the soil legacy of reindeer grazing. We used an arctic tundra grazed by reindeer as our study system, and Festuca ovina, a common grazing‐tolerant grass species as the model species. The soil legacy of reindeer grazing had the strongest effect on plants, and resulted in higher growth in soils originating from previously heavily‐grazed sites. Defoliation also had a strong effect and reduced shoot and root growth and nutrient uptake. Plants did not fully compensate for the tissue lost due to defoliation, even when nutrient availability was high. In contrast, defoliation enhanced plant nitrogen concentrations. Dung addition increased plant production, nitrogen concentrations and nutrient uptake, although the effect was fairly small. Mosses also had a positive effect on aboveground plant production as long as the plants were not defoliated. The presence of a thick moss layer reduced plant growth following defoliation. This study demonstrates that grasses, even though they suffer from defoliation, can tolerate high densities of herbivores when all aspects of herbivores on ecosystems are taken into account. Our results further show that the positive effect of herbivores on plant growth via changes in soil properties is essential for plants to cope with a high grazing pressure. The strong effect of the soil legacy of reindeer grazing reveals that herbivores can have long‐lasting effects on plant productivity and ecosystem functioning after grazing has ceased.     

Forage quality in relation to long-term grazing history,current-year defoliation,and water resource

Forage nitrogen concentrations, nitrogen yields, and in vitro digestibilities were assessed in shortgrass steppe that had been ungrazed, lightly, or heavily grazed for 50 years. Caged plots were defoliated in amounts based upon removals observed in naturallygrazed reference plots or not defoliated. This was done in a year of average precipitation and with a supplemental water treatment to simulate a wet year. In general, current-year defoliation had positive effects, and longterm grazing and supplemental water had negative effects, on forage nitrogen concentrations and digestibilities. However, defoliation interacted with long-term grazing in determning forage nitrogen concentrations, and with grazing and with watering in determining digestibilities. Nitrogen concentration and digestibility increased with defoliation in lightly, but not in heavily, grazed treatments. The dilution effect of supplemental water an digestibilities through increased plant growth was offset by defoliation. The negative effects of long-term grazing on forage quality were small, equally or more than compensated for by defoliation in a year of average precipitation, but more pronounced in the simulated wet year. Nitrogen yields and digestible forage production were usually increased by defoliation, but this depended upon grazing and watering treatments. Increased nitrogen and digestible forage yields and concentrations in response to defoliation were greater than the biomass response in lightly grazed grassland. For both nitrogen and digestibility, yields were greater in grazed than ungrazed treatments in the year of average precipitation, but less in the simulated wet year. Optimizing quantity and year-to-year stability of nitrogen and digestible forage yield may best be achieved with light grazing rather than no or heavy grazing. Clipping was conducted in a manner closely resembling the natural pattern and intensity of defoliation by the cattle, and confirms the potential for a positive feedback of increased forage quality with defoliation observed in pot experiments. Long-term heavy grazing can diminish this response. Quantily (aboveground primary production, ANPP), quantity of quality (digestible and N yields), and quality (concentrations) do not necessarily respond similarly in interactions between current-year defoliation, long-term grazing history, and level of water resource.     

Simulated effects of precipitation and nitrogen on Serengeti grassland productivity

In the Serengeti National Park, Tanzania, precipitation and soil nitrogen vary greatly between northwestern tallgrass areas and southeastern shortgrass areas, with the tallgrass having higher total precipitation and lower soil fertility. We used a model of grassland productivity, carbon/nitrogen cycling, and abiotic factors to test the hypothesis that tallgrass productivity is limited primarily by nitrogen availability while shortgrass productivity is limited by water. Under observed grazing intensities and ungrazed conditions, precipitation exerted primary control over grassland productivity for both regions, with differences in soil texture mediating soil water availability to the grasses. Mineral nitrogen availability interacted with water availability to influence productivity at precipitation levels 130% of the mean. Nitrogen mineralization and precipitation were positively related for each grassland type, however, nitrification varied both between grassland types and between grazed and ungrazed conditions. Combined mineralization and nitrification could not maintain soil mineral nitrogen levels in the face of plant nitrogen uptake stimulated by increased precipitation, thus providing the mechanism by which nitrogen becomes a secondary limiting factor for both grasslands. Model experiments indicated that the pattern of primary limitation by precipitation and secondary limitation by nitrogen was robust to model assumptions concerning ungulate deposition of urine and dung nitrogen to the soil.     

Effects of sheep urine on growth characteristics of different life form plants in a Chinese steppe grassland

The effects of sheep urine deposition volume (0, 1, 2 or 4 L/m²) and deposition stage of plant growth (vegetative or reproductive) on the number and size of tillers/branches and the biomass of Stipa bungeana, Artemisia capillaries and Lespedeza davurica in a Chinese steppe grassland were determined. The results indicate that the response of the three plant species to sheep urine deposition differs, and is influenced by both urine deposition volume and deposition stage of plant growth. Urine deposition had a short-term scorch effect on grassland plants, which mainly occurred in the inner zone of urine patches. Urine application had a long-term positive effect on S. bungeana and a long-term negative effect on A. capillaries and L. davurica, which lasted at least two years and decreased with decrease in urine deposition volume. All species growing in the inner zone of urine patches were scorched by sheep urine deposition, some species in the marginal zone of patches were also scorched, while no species were scorched in the outer zones. The reproductive and vegetative stages of A. capillaries and the reproductive stages of S. bungeana and L. davurica were sensitive to sheep urine deposition.     

Effects of sheep urine on growth characteristics of different life form plants in a Chinese steppe grassland

The effects of sheep urine deposition volume (0, 1, 2 or 4 L/m²) and deposition stage of plant growth (vegetative or reproductive) on the number and size of tillers/branches and the biomass of Stipa bungeana, Artemisia capillaries and Lespedeza davurica in a Chinese steppe grassland were determined. The results indicate that the response of the three plant species to sheep urine deposition differs, and is influenced by both urine deposition volume and deposition stage of plant growth. Urine deposition had a short-term scorch effect on grassland plants, which mainly occurred in the inner zone of urine patches. Urine application had a long-term positive effect on S. bungeana and a long-term negative effect on A. capillaries and L. davurica, which lasted at least two years and decreased with decrease in urine deposition volume. All species growing in the inner zone of urine patches were scorched by sheep urine deposition, some species in the marginal zone of patches were also scorched, while no species were scorched in the outer zones. The reproductive and vegetative stages of A. capillaries and the reproductive stages of S. bungeana and L. davurica were sensitive to sheep urine deposition.     

Impact of selective grazing on plant production and quality through floristic contrasts and current-year defoliation in a wet grassland

Grazing impacts the structure and functional properties of vegetation through floristic changes (i.e., long-term effect) and current defoliation (i.e., short-term effect). The aim of this study was to assess the relative importance of these two grazing effects on productivity (ANPP) and plant quality (C/N ratio) among plant patches submitted to a variety of grazing intensity for several years. Long-term grazing effect was measured by comparing ANPP and C/N ratio among plant patches with contrasting floristic composition. Short-term impact of grazing was measured by comparing ANPP and C/N in plant patches, with and without defoliation. Floristic contrasts led to a lower ANPP in highly grazed patches than in lightly grazed ones. This result may be related to the increasing proportion of grazing-tolerant and grazing-avoiding species with increasing grazing intensity. Vegetation C/N contrasts were recorded among grazed patches but did not linearly relate to grazing intensity. Short-term effect of current-year defoliation on ANPP was limited as vegetation compensated for biomass removal. No evidence for grazing-enhancement of ANPP was found even at moderate grazing intensity. Long-term floristic changes with grazing thus appeared to be the main driving factor of variations in ANPP. In contrast, C/N ratio showed no general and consistent variation along the grazing gradient but varied consistently depending on the community investigated, thus suggesting an effect of the species pool available.     

短期氮添加对祁连山亚高山草地生产力及植物多样性的影响

全球氮沉降速率的急剧增加已显著地改变了生态系统的生产力及稳定性,特别是在受N限制较严重的亚高山草地生态系统。虽然氮沉降增加对草地生产力和植物多样性影响的研究报道已经很多,但是氮素沉降的生态系效应因气候区、草地系统类型、加氮水平、氮肥类型和试验时间长短等不同而差别很大。为了评估氮沉降增加对亚高山草地植物物种多样性和生产力的影响,通过在祁连山中部亚高山草地设置不同氮添加水平（0、2、5、10、15、25 g N m^-2 a^-1和50 g N m^-2 a^-1）的短期氮沉降增加模拟试验,探讨了生产力和物种多样性对不同水平氮添加的响应。结果显示：氮添加增加了禾本科（垂穗披碱草、赖草和草地早熟禾）和莎草科（矮嵩草）的地上生产力及其在群落生产力中所占的比例,主要表现在氮添加增加了禾本科和莎草科的株高和株数,降低了其他科（鹅绒委陵菜和葛缕子）的株高和株数;与生产力相比,植物多样性对氮添加的响应较慢,总体随着氮添加量的增加呈下降趋势但未达到显著水平;植物多样性与生产力呈显著的负相关关系。研究结果表明氮添加有助于提高禾本科和莎草科的生产力,进而提高群落生产力,但其他科的植物会被逐渐替代,导致群落植物物种多样性降低。研究结果可为我国亚高山草地的持续性管理提供一定的理论基础。