崇明东滩南部河口盐沼植物群落种间关系的数量分析

对崇明东滩南部盐沼植物群落样方进行调查,基于现有17种高等植物,特别是8种常见植物的2×2联列表和植被盖度值,利用方差比率法、χ²检验以及Spearman秩相关分析对物种关联性和相关性进行分析.结果表明: 方差比率(VR=0.61)的检验统计量W=48.61,落在 χ² 2个临界值区间之外,因此该区域盐沼植物群落内植物整体关联度表现为显著负相关;依据各优势植物对环境的适应方式和生境的主导因素,参考Spearman秩相关分析的结果,将它们划分为4个生态种组: 芦苇、糙叶苔草-藨草-水莎草、互花米草-海三棱藨草、白茅-稗草.崇明东滩南部盐沼植物群落种间关系复杂,群落表现极不稳定,植物对于环境影响较为敏感.在明确物种之间关系的基础上,针对海三棱藨草的分布现状提出了相应种群的保护措施和建议.     

崇明东滩盐沼植被成带性对土壤因子的响应

对东滩湿地不同植被带与土壤环境因子的关系进行了探讨,分析植被成带性分布与土壤含水量、土壤盐度、土壤温度之间的关系,研究表明:(1)光滩(TF)、海三棱藨草(Sm)、互花米草带(Sa)土壤含水量差异显著(P0.05),随着土壤含水量的显著变化,海三棱藨草和互花米草种群分布呈现明显带状分布,土壤含水量对植被带的分布起到一定的平衡作用,在土壤经常性淹水下,互花米草种群的海向性拓殖受到一定抑制。(2)光滩带、海三棱藨草带、互花米草带之间的土壤盐分(NaCl)差异极显著(P0.001),从海向陆依次为:NaCl光滩带NaCl海三棱带NaCl互花米草带,NaCl含量增加土壤含水量相对减小,土壤盐度和含水量的差异极大影响了海三棱藨草和互花米草植被带的分布模式,从而进一步制约了其演替进程。不同植被带间温度差异显著,总体趋势为互花米草带最高而潮滩带最低,并且互花米草带土壤温度显著高于其它各带,小尺度空间上植被对环境因子的响应明显。(3)相对于7月份而言,5月份各带内土壤含水量显著较高,但植被带间没有显著性变化。光滩最高,依次为海三棱带和互花米草带。然而,7月份土壤盐度和温度显著大于5月份,互花米草带最高,依次为海三棱和光滩带。     

海三棱藨草及互花米草对模拟盐胁迫的响应及其耐盐阈值

盐度作为滨海湿地的关键环境因子之一,影响盐沼植物的存活、生长及分布。未来海平面上升引起的盐水入侵,将导致滨海湿地的盐沼植物面临高盐胁迫的挑战,进而影响滨海湿地生态系统的结构和功能。本研究选择长江口中低潮滩的主要先锋植物海三棱藨草(Scirpus mariqueter)和互花米草(Spartina alterniflora)为对象,通过人工控制实验,比较不同盐度处理下两种盐沼植物存活、营养生长及繁殖的响应,并确定两种盐沼植物存活的耐盐阈值,从而比较未来盐水入侵背景下,本地物种海三棱藨草及外来物种互花米草对盐胁迫的响应和适应性。结果表明:(1)海三棱藨草和互花米草的存活率随着盐度的增加均呈下降趋势,相同盐度处理下互花米草的存活率显著高于海三棱藨草的存活率(P0.05);(2)盐胁迫明显影响了海三棱藨草和互花米草的生长,随着盐度的增加,海三棱藨草株高、地上生物量及地下生物量均呈逐渐下降的趋势,而互花米草株高、地上生物量及地下生物量呈先增加后下降的趋势,均在盐度为10‰时最高;(3)海三棱藨草和互花米草的分蘖数及结穗率均随着盐度增加呈下降趋势,盐胁迫在一定程度上抑制了两种植物的繁殖能力;(4)互花米草存活的耐盐阈值为43‰,高于海三棱藨草存活的耐盐阈值(21‰);(5)外来物种互花米草比本地物种海三棱藨草具有更强的耐盐性,未来海平面上升引起的盐水入侵将对本地物种海三棱藨草产生更加严重的影响。     

崇明东滩湿地不同盐沼植物群落土壤碳储量分布

海岸带盐沼植被的高生产力对湿地土壤碳库的形成具有重要意义.本文研究了长江口崇明东滩湿地3种主要盐沼植物(芦苇、互花米草和海三棱藨草)群落生物量差异、土壤碳储量时空动态和垂向分布特征.结果表明： 湿地盐沼植被总生物量表现为互花米草群落(5750.7 g·m^-2)>芦苇群落(4655.1 g·m^-2)>海三棱藨草群落(812.7 g·m^-2),且地上生物量在夏、秋季最高,地下生物量在冬季最高.湿地土壤碳储量(0～50 cm)在春季最低,随后逐渐增加,至冬季达到最大值.土壤碳储量年增量从高潮滩向低潮滩递减,表现为芦苇群落(711.8 g·m^-2)>互花米草群落(646.2 g·m^-2)>海三棱藨草群落(185.3 g·m^-2)>光滩(65.6 g·m^-2).光滩土壤碳储量在25～30 cm处最高,海三棱藨草、互花米草和芦苇群落土壤碳储量分别在10～15、30～35和30～40 cm处达到最大值,且不同群落土壤碳储量与植被地下生物量具有显著的线性关系.     

崇明东滩湿地不同潮汐带入侵植物互花米草根际细菌的多样性

为了调查崇明东滩湿地入侵植物互花米草(Spartina Alterniflora)在不同潮汐带和季节根际细菌的多样性与丰富度,以本地植物芦苇、海三棱藨草(P. australis和 S.mariqueter)和光滩为对照实验研究,在崇明东滩湿地10样点采集根际土壤和光滩土壤,通过PCR-DGGE分子生物学等技术并结合传统培养方法对土壤细菌进行分析研究。研究表明:东滩湿地不同潮汐带的植物根际细菌群落丰富度和多样性不同,在夏季中潮带的根际细菌丰富度(P=0.021<0.05)较高,各个潮带的植物根际细菌在夏秋季有高多样性,其中中潮带的植物根际细菌平均多样性指数最高(H=4.20)。在中潮带入侵物种互花米草根际细菌的丰富度和多样性要显著高于本地植物芦苇和海三棱藨草,其中海三棱藨草的根际细菌在夏季略高。崇明东滩湿地入侵植物互花米草根际细菌与本地植物相比较具有较高的多样性,而且外来种互花米草对湿地土壤微生物群落结构有着较强影响;入侵种互花米草根际细菌的高丰富度和多样性可能是其成功入侵东滩湿地的一个重要因素。     

互花米草与海三棱藨草的生长特征和相对竞争能力

外来物种互花米草(Spartinaalterniflora)已对我国特有种海三棱藨草 (Scirpusmariqueter)发生了竞争取代。作者通过在长江口崇明东滩湿地取样和盆栽竞争实验,比较了二者的主要生长特征和种间相对竞争能力。结果表明:无论是先锋种群还是成熟种群,互花米草的高度、盖度、地上生物量、地下生物量和平均每花序种子数都显著大于海三棱藨草;海三棱藨草的密度和单位面积结实枝条数显著大于互花米草。两种植物成熟种群的单位面积种子产量和种子的萌发率没有显著差异。种内竞争和种间竞争显著降低了两种植物的平均每株产生的无性小株数、结实株数、地上生物量和地下球茎数(海三棱藨草产生球茎),互花米草的种间竞争能力 (相对邻里效应指数 )显著大于海三棱藨草。互花米草在生长上的优势可能导致其在种间竞争上的优势,从而使互花米草能够在海三棱藨草群落中成功入侵。     

崇明东滩湿地高等植被演替特征

研究了崇明东滩湿地植被演替过程中生态特征以及重要值、地上部分生物量、植被地上部分氮含量以及氮容量的季节性变化.结果表明：随着高程的升高,演替早期的代表物种海三棱藨草（Scirpus mariqueter）的重要值逐渐减小,互花米草（Spartina alterniflora）和芦苇（Phragmites australis）的重要值增大.演替过程中植物的生物多样性逐渐增加.3种植物地上部分生物量在生长季节内（3—10月）均呈单峰变化,一般在夏季（7、8月）生物量最大.3种植物地上部分氮含量在生长季节内均呈降低趋势,氮容量在生长季节内呈单峰变化.估算每年崇明东滩保护区内芦苇地上部分蓄积的氮为383.4 t,互花米草为39.3 t,海三棱藨草为50.5 t.     

盐度及种间相互作用对海三棱藨草、互花米草萌发及生长的影响

盐度和种间作用是影响湿地植物群落构建的关键因子。然而,已有研究主要集中于植物成体阶段,我们对生活史早期更新阶段的种间相互作用了解十分有限。崇明东滩国家级自然保护区是位于长江口的重要湿地,外来入侵植物互花米草对优势土著物种海三棱藨草的竞争排斥对当地生态系统造成了严重的负面影响。通过受控实验探讨了盐度及种间作用对海三棱藨草和互花米草种子萌发及生长的影响,以深入了解更新过程在盐沼湿地植物群落构建中的作用。结果表明,在培养皿中盐度对海三棱藨草的萌发有显著抑制作用,互花米草的萌发率受盐度影响不显著但萌发进程被延迟。混种处理对两者的萌发存在一定促进效应,且其作用强度受到盐度的调控。海三棱藨草与互花米草种子在萌发阶段的相互促进并非是通过化感作用实现的,可能是由于萌发过程对盐分的吸收减弱了盐胁迫的影响。盆栽条件下,两物种混种时的萌发及生长表现（高度、地上生物量）较单种时有所下降,但差异不显著。种间竞争受环境胁迫程度及生活史阶段的影响,竞争作用在胁迫较弱的淡水环境及生活史后期更强。盐沼湿地植物群落在形成早期受到盐度等环境因子的影响较大,不同植物对盐胁迫的响应是影响种群建成的主导因素,后期种间竞争的重要性不断增加,最终决定了植物群落的整体格局。     

海三棱藨草的组织培养与快繁体系

以海三棱藨草(Scirpus × mariqueter)成熟种子为外植体, 通过无菌萌发、丛生芽诱导、增殖、壮苗、生根和移栽等过程, 建立了海三棱藨草的无菌快繁体系。结果表明: 丛生芽诱导和增殖的最适培养基为MS+2.0 mg·L^-1 6-BA+0.002 mg·L^-1 TDZ+0.2 mg·L^-1 IBA; 壮苗最适培养基为1/2MS+0.05 mg·L^-1 6-BA+0.01 mg·L^-1 IBA; 生根最适培养基为1/2 MS+0.2 mg·L^-1 IBA; 最适培养温度为30°C; 再生苗移入珍珠岩:草炭:蛭石=1:1:1 (体积比)的混合基质中, 移栽成活率可达85%以上。生根培养阶段选用容积较大的塑料容器育苗, 可以降低生产成本和提高生产效率。     

滨海湿地植被-土壤相互作用及其对沉积环境分异的响应格局

开展滨海湿地植被与土壤之间相互作用机制的研究对湿地植被修复工程的实践具有重要的指导意义。本文旨在解析海三棱藨草(Scirpus mariqueter)如何响应湿地土壤沉积环境的改变,并建立植被指数与土壤环境因子之间的统计关系模型。选择南汇东滩滩涂,采集了2015—2017年32个采样点的土壤理化参数数据及高程数据,以及7个采样点的海三菱藨草光谱反射率数据。采用相关分析、回归分析、ArcGIS空间分析等方法,探讨了植被指数、土壤理化参数及滩涂高程变化之间的相互作用。研究将高程变化与NDVI变化的幅度分为12个级别,取中值6作为分析的阈值。结果表明,高程变化值与NDVI变化值同时不低于6的区域占总区域面积的51.45%,主要集中在研究区东部,西部有小范围分布。80.45%的NDVI变化值为级别6及以上区域包含在滩涂高程变化值为级别6以上的区域里,同时,围垦后南汇东滩高程逐年增加,NDVI值也呈增加趋势。这表明,在一定范围里,滩涂高程与植被NDVI变化在空间动态里具有同步性。滩涂高程与土壤理化因子地统计分析表明,高程与土壤盐度、含水率具有统计显著性的空间相关性,土壤盐度、含水率是显著影响海三棱藨草群落空间分布的主导土壤因子。研究表明,沉积环境分异所导致的高程变化是海三棱藨草空间分布的主要控制因素,而基于NDVI的植被指数研究有利于从宏观上把握植被群落的变化及扩散的整体格局动态。     

基于遥感的九段沙湿地植被群落动态变化分析

九段沙是长江口重要的新生湿地.作为主要地物类型之一的植被群落,是反映潮滩湿地生态环境变化重要而又敏感的指标因子.本文通过1987～2008年六景Landsat卫星遥感数据对九段沙植被群落进行了分类提取,并利用ArcGIS软件分析了长江口九段沙植被群落20年来的时空动态变化.结果显示1987～1997年间,九段沙湿地植被以先锋植被海三棱藨草为主,植被面积随潮滩不断淤涨而增长;1997年人工促淤种植了芦苇和互花米草,至2008年,芦苇、互花米草和海三棱藨草三种植被群落所占植被总面积百分比分别为31.47%、39.35%和29.17%,其中外来物种互花米草优势明显,当地植被海三棱藨草所占面积比例显著下降.     

胶州湾互花米草湿地氮、磷元素的垂直分布及季节变化

为了研究胶州湾互花米草湿地N、P的垂直分布及季节变化特征,分别于2015年4、7、9、10、11和12月对该区域互花米草湿地和光滩土壤全氮(TN)、铵态氮(NH₄⁺-N)、全磷(TP)、速效磷(AP)、总有机碳(TOC),以及pH、盐度、含水量进行了测定.结果表明: 胶州湾互花米草湿地土壤TN、NH₄⁺-N、TP、AP含量平均值分别为0.396 g·kg^-1、12.14 mg·kg^-1、0.419 g·kg^-1、16.52 mg·kg^-1,光滩平均值分别为0.385 g·kg^-1、8.13 mg·kg^-1、0.423 g·kg^-1、19.57 mg·kg^-1.总体来说,它们的含量随着土壤深度(0～60 cm)的增加逐渐降低;互花米草湿地N、P含量的季节变化明显,互花米草湿地土壤全氮含量在春季最高,秋季最低,而光滩土壤随着季节变化逐渐降低;二者土壤全磷含量的季节变化趋势相反,而速效磷含量的季节变化趋势一致;胶州湾互花米草湿地土壤TN、TP与土壤TOC含量呈显著相关,而在光滩土壤中无显著相关关系.pH、盐度显著影响互花米草湿地和光滩土壤N、P含量.     

Stoichiometric characteristics of carbon,nitrogen and phosphorus of Sibiraea angustata shrub on the eastern Qinghai-Xizang Plateau

Aims Little is known about the stoichiometric characteristics of carbon (C), nitrogen (N) and phosphorus (P) in plateau shrubs across China. Sibiraea angustata is a typical and representative shrub species on the eastern Qinghai- Xizang Plateau, and exploring its C, N and P distribution patterns and stoichiometric properties in different organs (including root, shoot, leaf, twig and fruit) would help us better understand the mechanisms of C, N and P cycling and balance in the S. angustata dominated shrub ecosystem.
Methods Sixteen sampling sites were selected on the eastern Qinghai-Xizang Plateau by the stratified sampling method. The height and coverage of the dominant shrubs, latitude, longitude and altitude of the sites were recorded. Three 5 m × 5 m plots were selected at each site. At least 128 biological samples of plant organs of S. angustata were collected and measured, respectively. The C and N concentrations of plant samples were analyzed using an elemental analyzer (2400 II CHNS). The P concentration was analyzed using the molydate/ascorbic acid method after H₂SO₄-H₂O₂ digestion.
Important findings The C, N and P concentrations of different organs followed the order of: shoot (495.07 g·kg^-1) > twig (483.37 g·kg^-1) > fruit (480.35 g·kg^-1) > root (468.47 g·kg^-1) > leaf (466.33 g·kg^-1); leaf (22.27 g·kg^-1) > fruit (19.74 g·kg^-1) > twig (7.98 g·kg^-1) > shoot (4.54 g·kg^-1) > root (4.00 g·kg^-1) and fruit (2.85 g·kg^-1) > leaf (1.92 g·kg^-1) > twig (0.96 g·kg^-1) > root (0.52 g·kg^-1) > shoot (0.45 g·kg^-1), respectively. The ranges of the coefficient of variation (CV) for C, N and P concentrations were 1.71%-4.44%, 14.49%-25.50% and 11.46%-46.15%, respectively. Specifically, the C concentration was relatively high and stable, and the maximum CV values for N and P were found in roots. The N:P value of different organs varied from 7.12-12.41 and the minimum CV for N:P was found in twig, which indicated that N:P in twig had higher internal stability. In addition, correlation analysis indicated that the C concentration was significantly negatively correlated with N and P concentrations and correlation coefficients were -0.407 and -0.342, respectively. However, N concentration had dramatically positive correlation with P concentration and the correlation coefficient was 0.814. These results also could indicate that the C, N and P stoichiometric characteristics in the S. angustata shrub accorded with the homeostatic mechanism and growth rate hypothesis to some extent, the distributions of C, N and P concentrations were closely related to the function of the organs and it should be prudent to use ecological stoichiometric ratios to judge the condition of nutrient limitation at the species level.     

Spatio-temporal characteristics of evapotranspiration and water use efficiency in grasslands of Xinjiang

Aims Xinjiang is located in the hinterland of the Eurasian arid areas, with grasslands widely distributed. Grasslands in Xinjiang provide significant economic and ecological benefits. However, research on evapotranspiration (ET) and water use efficiency (WUE) of the grasslands is still relatively weak. This study aimed to explore the spatio-temporal characteristics on ET and WUE in the grasslands of Xinjiang in the context of climate change.Methods The Biome-BGC model was used to determine the spatio-temporal characteristics of ET and WUE of the grasslands over the period 1979-2012 across different seasons, areas and grassland types in Xinjiang.Important findings The average annual ET in the grasslands of Xinjiang was estimated at 245.7 mm, with interannual variations generally consistent with that of precipitation. Overall, the value of ET was lower than that of precipitation. The higher values of ET mainly distributed in the Tianshan Mountains, Altai Mountains, Altun Mountains and the low mountain areas on the northern slope of Kunlun Mountains. The lower values of ET mainly distributed in the highland areas of Kunlun Mountains and the desert plains. Over the period 1979-2012, average annual ET was 183.2 mm in the grasslands of southern Xinjiang, 357.9 mm in the grasslands of the Tianshan Mountains, and 221.3 mm in grasslands of northern Xinjiang. In winter, ET in grasslands of northern Xinjiang was slightly higher than that of Tianshan Mountains. Average annual ET ranked among grassland types as: mid-mountain meadow > swamp meadow > typical grassland > desert grassland > alpine meadow > saline meadow. The highest ET value occurred in summer, and the lowest ET value occurred in winter, with ET in spring being slightly higher than that in autumn. The higher WUE values mainly distributed in the areas of Tianshan Mountains and Altai Mountains. The lower WUE values mainly distributed in the highland areas of Kunlun Mountains and part of the desert plains. The average annual WUE in the grasslands of Xinjiang was 0.56 g·kg^-1, with the seasonal values of 0.43 g·kg^-1 in spring, 0.60 g·kg^-1 in summer, and 0.48 g·kg^-1 in autumn, respectively. Over the period 1979-2012, the values of WUE displayed significant regional differences: the average values were 0.73 g·kg^-1 in northern Xinjiang, 0.26 g·kg^-1 in southern Xinjiang, and 0.69 g·kg^-1 in Tianshan Mountains. There were also significant differences in WUE among grassland types. The values of WUE ranked in the order of mid-mountain meadow > typical grassland > swamp meadow > saline meadow > alpine meadow > desert grassland.     

基于无人机遥感监测滩涂湿地入侵种互花米草植被覆盖度

为了实现对沿海滩涂湿地资源与生态环境的有效管理与利用,需要对区域内的入侵种互花米草进行高精度的监测与分析.本文以福建三沙湾为试验区,以低空无人机获取的可见光和多光谱影像为数据源,对互花米草植被覆盖度进行监测与分析,通过NDVI指数模型获取了多光谱影像的植被覆盖度信息,以可见光影像为参考进行了精度检验.结果表明: 影像区互花米草植被覆盖度以40%～60%和60%～80%的中高和高等级覆盖度为主.NDVI模型估算值与真实值之间的均方根误差RMSE为0.06,决定系数R²为0.92,两者具有较好的一致性.     

Effects of peach branches returning on autotoxins and microbes in soil and tree growth of peaches

Aims This study aimed to investigate the effects of branch returning on the growth of peach (Amygdalus persica "Chunmei/Maotao") saplings, soil enzyme activity, and soil contents of phenolic acids and amygdalin, thereby providing scientific evidence against the application of branch returning for peach trees. Methods One-year-old potted peach tree (Amygdalus persica "Chunmei/Maotao") was used in this study with four agricultural treatments applied, including soil coverage by fragmented peach tree branches (fragment treatment;1.5 and 22.5 g·kg^-1) and applying leachate solutions of peach tree branches to soil (leachate treatment; 1.5 and 22.5 g·kg^-1). No branch addition was used as control (CK). Solid phase extraction, high performance liquid chromatography (HPLC), biological high-throughput sequencing was used to determine the content of autotoxic substances, and microbial community structure in soil. Soil coverage and leachate solution treatments of 30 g and 450 g branches applied to the peach trees were described as 1.5 and 22.5 g·kg^-1, respectively in this paper.Important findings Compared with CK, the phenolic acid and amygdalin contents significantly increased after both fragment and leachate treatments in high quantities (22.5 g·kg^-1). Soil microbial community structure altered in both treatments, with the proportion of fungi (particularly Agaricomycetes, Tubeufia and Cystofilobasidiaceae) increased significantly and bacteria decreased accordingly. Invertase activity in both high-quantity treatments exceeded that in the CK significantly. The activity of catalase and urease was higher at first and then decreased relative to CK under high-quantity fragment and leachate treatments. Specifically, the effect of leachate treatment on enzyme activity was higher than the fragment treatment in the short term. Chlorophyll content, ground diameter (diameter of 5 cm from the ground) growth and net photosynthesis rate of plants were lower in high-quantity fragment and leachate treatments than those in CK, with earlier retardation of new shoot growth. We observed an increase in soil phenolic acids and enzymes in treatments in normal pruning quantity, while no inhibition effect was found on the tree growth. In conclusion, autotoxins (such as phenolic acid and amygdalin) inhibited the growth of peach trees both directly and indirectly through changing soil enzyme activity and microbial community.     

怀山药类原球茎的诱导形成与植株再生

为提高山药离体繁殖的速度, 缩短繁殖周期, 以铁棍山药(Dioscorea opposita cv. ‘Tiegun’)带腋芽茎段为材料, 对类原球茎的诱导、增殖、分化与植株再生进行了研究。结果表明, 铁棍山药类原球茎诱导的最适培养基为MS+1.0 mg·L^-1 TDZ+30 g·L^-1蔗糖, 增殖的最适培养基为MS+9 mg·L^-1 6-BA+30 g·L^-1蔗糖, 分化的最适培养基为MS+2 mg·L^-1 KT+0.02 mg·L^-1 NAA+30 g·L^-1蔗糖, 最适生根培养基为1/4MS+0.05 mg·L^-1 NAA+1.0 mg·L^-1 PP333+15 g·L^-1蔗糖, 生根率达80%, 移栽成活率可达85%。类原球茎的诱导形成及植株再生体系的建立为怀山药种苗的快速繁殖提供了一条新途径。     

不同地下水矿化度对柽柳光合特征及树干液流的影响

为揭示柽柳(Tamarix chinensis)光合能力及耗水特征对地下水矿化度的响应规律, 以黄河三角洲建群种——柽柳3年生植株为研究对象, 在1.2 m的潜水水位下, 模拟设置淡水、微咸水、咸水和盐水4种不同的地下水矿化度, 测定柽柳叶片光合-光响应、蒸腾速率和树干液流的日变化。结果表明: 地下水矿化度通过影响土壤盐分可显著影响柽柳光合特性及耗水性能。随地下水矿化度升高, 柽柳叶片净光合速率(P_n)、最大P_n、蒸腾速率、气孔导度、表观量子效率和暗呼吸速率均先升高后降低, 而水分利用效率(WUE)持续降低。淡水、微咸水和盐水处理下, 柽柳P_n光响应平均值分别比咸水处理降低44.1%、15.1%和62.6%; 微咸水、咸水和盐水处理下, 柽柳WUE光响应平均值分别比淡水处理降低25.0%、29.2%和41.7%。随地下水矿化度升高, 柽柳叶片光饱和点先升高后降低, 而光补偿点持续升高, 光照生态幅变窄, 光能利用率变低。淡水和盐水处理下, 柽柳P_n下降分别是非气孔限制和气孔限制引起的。柽柳树干液流速率随地下水矿化度升高而先升高后降低, 咸水处理下树干液流速率日变幅最大, 日液流量最高。淡水、微咸水和盐水处理下日液流速率平均值分别比咸水处理降低61.8%、13.1%和41.9%。咸水矿化度下柽柳有较高的光合特性, 在蒸腾耗水较严重的情况下可实现高效生理用水, 适宜柽柳较好地生长。     

Effects of nitrogen addition on soil respiration of Rhododendron simsii shrubland in the subtropical mountainous areas of China

Aims As the second largest C flux between the atmosphere and terrestrial ecosystems, soil respiration plays a vital role in regulating atmosphere CO₂ concentration. Therefore, understanding the response of soil respiration to the increasing nitrogen deposition is urgently needed for prediction of future climate change. However, it is still unclear how nitrogen deposition influences soil respiration of shrubland in subtropical China. Our objectives were to explore the effects of different levels of nitrogen fertilization on soil respiration, root biomass increment, and litter biomass, and to analyze the relationships between soil respiration and soil temperature and moisture.
Methods From January 2013 to September 2014, we conducted a short-term simulated nitrogen deposition experiment in the Rhododendron simsii shrubland of Dawei Mountain, located in Hunan Province, southern China. Four levels of nitrogen addition treatments (each level with three replicates) were established: control (CK, no nitrogen addition), low nitrogen addition (LN, 2 g·m^-2·a^-1), medium nitrogen addition (MN, 5 g·m^-2·a^-1) and high nitrogen addition (HN, 10 g·m^-2·a^-1). Soil respiration was measured by LI-8100 soil CO₂ efflux system. At the same time, we measured root biomass increment and litter biomass in each plot.
Important findings Soil respiration exhibited a strong seasonal pattern, with the highest rates found in summer and the lowest rates in winter. Annual accumulative soil respiration rate in the CK, LN, MN and HN was (2.37 ± 0.39), (2.79 ± 0.42), (2.26 ± 0.38) and (2.30 ± 0.36) kg CO₂·m^-2, respectively. Annual mean soil respiration rate in the CK, LN, MN and HN was (1.71 ± 0.28), (2.01 ± 0.30), (1.63 ± 0.27) and (1.66 ± 0.26) μmol CO₂·m^-2·s^-1, respectively, and it was 17.25% higher in the LN treatment compared with CK (p = 0.06). The root biomass increment was increased by LN, MN, and HN treatments by 18.36%, 36.49% and 61.63%, respectively, compared to CK. The litter biomass was increased by LN, MN, and HN treatments by 35.87%, 22.17% and 15.35%, respectively, compared with CK. Soil respiration exhibited a significant exponential relationship with soil temperature (p < 0.01, R² is 0.77 to 0.82) and a significant linear relationship with soil moisture at the depth of 5 cm (p < 0.05, R² is 0.10 to 0.15). The temperature sensitivity (Q₁₀) value of CK, LN, MN and HN plots was 3.96, 3.60, 3.71 and 3.51, respectively. These results suggested that nitrogen addition promoted plant growth and decreased the temperature sensitivity of soil respiration. The increase of root biomass under N addition may be an important reason for the change of soil respiration in the study area.     

Effects of groundwater salinity on the characteristics of leaf photosynthesis and stem sap flow in Tamarix chinensis

AimsThe objective of this study was to investigate the change pattern of leaves photosynthesis and stem sap flow of Tamarix chinensisin under different groundwater salinity, which can be served as a theoretical basis and technical reference for cultivation and management of T. chinensis in shallow groundwater table around Yellow River Delta.MethodsThree-year-old T. chinensis, one of the dominated species in Yellow River Delta, was selected. Plants were treated by four different salinity concentrations of groundwater—fresh water (0 g∙L^-1), brackish water (3.0 g∙L^-1), saline water (8.0 g∙L^-1), and salt water (20.0 g∙L^-1) under 1.2 m groundwater level. Light response of photosynthesis and the diurnal courses of leaf transpiration rate, stem sap flux velocity and environment factors under different groundwater salinity were determined via LI-6400XT portable photosynthesis system and a Dynamax packaged stem sap flow gauge based on stem-heat balance method, respectively.Important findings The result showed that groundwater salinity had a significant impact on photosynthesis efficiency and water consumption capacity of T. chinensis by influencing the soil salt. The net photosynthetic rate (P_n), maximum P_n, transpiration rate, stomatal conductance, apparent quantum yield and dark respiration rate increased first and then decreased with increasing groundwater salinity, while the water use efficiency (WUE) continuously decreased. The mean P_n under fresh water, brackish water and salt water decreased by 44.1%, 15.1% and 62.6%, respectively, compared with that under saline water (25.90 µmol∙m^-2∙s^-1). The mean WUE under brackish water, saline water and salt water decreased by 25.0%, 29.2% and 41.7%, respectively, compared with that under fresh water (2.40 µmol∙mmol^-1). With the increase of groundwater salinity from brackish water to salt water, light saturation point of T. chinensisdecreased while the light compensation point increased, which lead to the decrease of light ecological amplitude and light use efficiency. Fresh water and brackish water treatment helped T. chinensis to use low or high level light, which could significantly improve the utilization rate of light energy. The decrease in P_n of T. chinensis was mainly due to non-stomatal limitation under treatment from saline water to fresh water, while the decrease in P_n of T. chinensis was due to stomatal limitation from saline water to salt water. With increasing groundwater salinity, stem sap flux velocity of T. chinensis increased firstly and then decreased, reached the maximum value under saline water. The mean stem sap flux velocity under fresh water, brackish water and salt water decreased by 61.8%, 13.1% and 41.9%, respectively, compared with that under saline water (16.96 g·h^-1). Tamarix chinensis had higher photosynthetic productivity under saline water treatment, and could attained high WUE under severe water deprivation by transpiration, which was suitable for the growth of T. chinensis.