准噶尔盆地荒漠植物碳同位素组成研究

通过对准噶尔盆地古尔班通古特沙漠南缘17个科、41个属的53种荒漠植物的稳定碳同位素分析,结果显示准噶尔盆地荒漠植物的叶片稳定碳同位素值在-7.77‰~-30.10‰之间变化,其稳定碳同位素比值分布范围较广,C3和C4植物资源丰富。其中,C3植物有34种,δ13C值分布区间为-23.27‰~-30.10‰,平均值为-26.77‰;C4植物有19种,δ13C值的变化范围为-7.77‰～-14.90‰,平均值为-13.04‰。研究区内木本植物和草本植物的δ13C平均值分别为-16.74‰和-19.81‰,说明木本植物的水分利用效率明显高于草本植物,这种现象可能是全球荒漠生态系统的一种共性。但是一年生草本植物的δ13C平均值（-19.54‰）却高于多年生草本植物的δ13C平均值（-20.07‰）,由于植物叶片δ13C可以用来间接指示植物的长期水分利用效率,即δ13C值越大,植物的水分利用效率越高;也就是说在该地区,相对于多年生草本植物而言,一年生草本植物对环境的适应能力较强。     

阜康典型荒漠C3植物稳定碳同位素值的环境分析

通过对阜康典型荒漠C3植物稳定碳同位素值的分析。叶片炭同位素值在-23‰和-29‰之间变化,其中主要在-27‰附近波动。这与前人报道的世界上其他地区荒漠植物碳同位素值的变化非常一致。降水可以改变叶片碳同位素值的大小,降水越多,叶片碳同位素值越负,它们的变化幅度有物种的依赖性。叶片碳同位素值也受植物生长形式或期望寿命的影响,木本植物或寿命长的植物叶片碳同位素值要高。分析表明,利用该区土壤或陆相沉积中有机质碳同位素值可以判断气候的干湿变化：土壤或陆相沉积中有机质碳同位素值越高,气候则越干燥。     

黄土碳酸盐古气候意义及其研究展望

碳酸盐是黄土中的主要矿物,是黄土—古土壤序列中含量变化最显著的矿物之一,其在表生环境下极易移动,并且它的迁移变化受大气降水、温度等古气候因素制约,在黄土高原风尘堆积序列的古气候研究中具有极其重要的意义,其变化能够较好地反映古季风的演变规律。黄土—古土壤中碳酸盐的含量变化和东亚夏季风降水的强度密切相关,碳酸盐矿物中白云石和方解石的存在与否及淋失深度对夏季风演变同样有很好的指示意义。稳定同位素δ¹⁸O可以作为夏季风的代用指标,指示成壤时期环境中的古温度;δ¹³C值表现出在黄土层中高,而在古土壤层中低,因此碳酸盐δ¹³C值可能更多反映了植被发育程度。碳酸盐中Sr同位素能够反映风化作用的强弱,而去除碳酸盐后的Sr同位素则能更好地反映成壤作用的强度和判别风尘物质的来源。与其它季风气候替代性指标相比,酸溶相中的δ¹¹B值变化与降水有直接关系,可以很好地作为夏季风降水指标。非传统稳定同位素Li、Ba和Fe有应用于黄土研究中,但目前的研究表明它们对气候环境暂无较好的指示意义。     

黄土碳酸盐碳同位素环境意义讨论

黄土碳酸盐碳同位素广泛应用于第四纪气候环境变化的研究中,以往的大多数研究中无论是利用钙结核、次生碳酸盐还是成壤碳酸盐,认为其反映了C4植物的丰度。黄土高原碳酸盐碳同位素表现为黄土层高,古土壤层中低,即黄土层中C4植物丰度高于古土壤层。然而,这样的结果和黄土有机碳同位素得到的结果矛盾,有机碳同位素的结果表明温度对C4植物的分布起到了决定性作用。由于有机碳同位素对植物类型的反映更为直接而可靠,因此碳酸盐碳同位素反映C4植物丰度存在疑问。对黄土高原黄土碳酸盐碳同位素的系统概括后认为,第四纪期间黄土碳酸盐碳同位素与C4植物有直接联系,但C4植物丰度不是唯一决定性的因素,碳酸盐碳同位素的指示意义存在复杂性。在黄土高原地区,植被发育程度、与大气CO2交换程度、植被本身的碳同位素值的变化以及原生碳酸盐的影响等因素都会对碳酸盐碳同位素产生影响。由黄土碳酸盐碳同位素的讨论可延伸到不同土壤碳酸盐碳同位素揭示的环境指示意义,不同的土壤环境,其气候条件、植被类型及发育程度、大气CO2的交换情况、微生物的活动及土壤次生碳酸盐受原生碳酸盐溶解的影响等因素都会对碳同位素产生不同程度影响,哪种或哪几种因素产生主要作用,在不同区域土壤环境中是不一样的。具体研究中需确定影响的核心因素,才能确定碳同位素的环境指示意义。     

湖泊自生碳酸盐碳同位素在环境变化中的应用

湖泊自生碳酸盐碳同位素组成(δ13Cc)在区域气候与环境变化方面的应用研究近年来进展迅速,成果显著,保存在各类湖泊沉积物柱芯中的δ13Cc记录揭示了湖表水体与大气CO2的交换程度、暖季降水量的多少、流域C3和C4植被变化情况、水生生物光合作用或呼吸作用强弱、湖泊生产力大小、湖泊水体化学特征、湖水不同深度层的有机质变化过程等重要的气候和环境信息;对此进行归纳和述评。     

黄土碳酸盐碳同位素环境意义讨论

黄土碳酸盐碳同位素广泛应用于第四纪气候环境变化的研究中,以往研究中多利用钙结核、次生碳酸盐或成壤碳酸盐,认为其反映了C₄植物的丰度。黄土高原碳酸盐碳同位素表现为黄土层高,古土壤层中低,即黄土层中C₄植物丰度高于古土壤层。然而,这样的结果和黄土有机碳同位素得到的结果矛盾,有机碳同位素的结果表明温度对C₄植物的分布起到了决定性作用。由于有机碳同位素对植物类型的反映更为直接而可靠,因此碳酸盐碳同位素反映C₄植物丰度存在疑问。对黄土高原黄土碳酸盐碳同位素的系统概括后认为,第四纪期间黄土碳酸盐碳同位素与C₄植物有直接联系,但C₄植物丰度不是唯一决定性的因素,碳酸盐碳同位素的指示意义存在复杂性。在黄土高原地区,植被发育程度、与大气CO₂交换程度、植被本身的碳同位素值的变化以及原生碳酸盐的影响等因素都会对碳酸盐碳同位素产生影响。由黄土碳酸盐碳同位素的讨论可延伸到不同土壤碳酸盐碳同位素揭示的环境指示意义,不同的土壤环境,其气候条件、植被类型及发育程度...     

表土分粒级碳酸盐与碳同位素分布特征及其凤尘源区示踪意义

对科尔沁沙地、松嫩沙地及哈尔滨道路松散裸土等不同区域表土样品进行粒度分级,分别测定碳酸盐含量和碳同位素组成,发现大部分沙地样品和全部道路表土样品的碳酸盐含量随粒度变细而增大.松嫩沙地的部分样品和科尔沁沙地的大部分样品碳酸盐含量随粒度变化还表现出其它复杂关系,风成砂和经历过强烈成壤作用改造的沙地样品中的碳酸盐含量与粒度的关系皆表现为随粒度变细而减小;大部分沙地样品和道路表土样品不同粒级组分的碳酸盐δ13C组成表现出随粒度变细而趋于偏正的特征,但变化范围较小.松嫩沙地和科尔沁沙地碳酸盐含量的地区差异性极不明显,且各粒级组分碳酸盐含量的变化幅度大大超过了其碳酸盐区域差异值,故不能作为区分松嫩沙地和科尔沁沙地风尘源区的示踪指标;而科尔沁沙地和松嫩沙地碳酸盐δ13C组成存在明显差异,且不同粒级组分碳酸盐δ13C值差别较小,是一个比碳酸盐含量更好的风尘源区示踪指标.     

黄土碳酸盐的研究

黄土是过去气候变化研究的重要对象之一。黄土中的碳酸盐则是黄土研究的一个重要内容。黄土碳酸盐的研究涉及了对次生碳酸盐的辨识、碳酸盐的含量、碳酸盐中的碳氧同位素以及碳酸盐的Sr同位素及其它微量元素等内容。对前人在这几个方面的研究作一初步的归纳总结,包括次生碳酸盐的辨识和提取对解释古气候环境有重要意义;碳酸盐的含量可反映出黄土和古土壤之间的不同气候状况;根据碳酸盐中的碳氧同位素则能大体定量得到古温度以及古植被状况进而反映古降水情况;而Sr同位素及其它微量元素则能反映出当时的化学风化程度,指示季风的强弱变化。     

安西荒漠草原兽类资源分布的研究

安西地处甘肃河西走廊的西部。这里气候干旱少雨, 年雨量31.5-100毫米, 形成了荒漠植被, 是中亚荒漠的一部分。荒漠草原环境中分布着较丰富的动物资源, 甘肃省已建立安西戈壁荒漠草原自然保护区, 面积约8000平方公里, 保护区内已知兽类25种, 其中资源兽类14种, 分布在不同的自然地理区:(1)走廊绿洲荒漠(戈壁)区;(2)祁连山前山地区;(3)北山-低山、中山区。     

内蒙古典型草原与荒漠草原NDVI对气象因子的响应

分析了内蒙古典型草原与荒漠草原NDVI的变化,探讨了干旱对NDVI的影响,建立了NDVI与气象因子的回归模型。结果表明:2000-2016年内蒙古典型草原与荒漠草原NDVI呈现波动变化,变异较小。干旱对典型草原区的羊草(Leymus chinensis)群落与大针茅(Stipa grandis)群落NDVI影响显著(P<0.05);与正常年份相比,干旱导致羊草群落与大针茅群落NDVI降低约23%。5-8月降水量和干燥度指数影响内蒙古典型草原羊草群落与大针茅群落NDVI;荒漠草原区羊草+短花针茅(Stipa breviflora)群落与沙生针茅(Stipa plareosa)群落NDVI的主要影响因子分别为年均气温与5-8月平均气温;5-8月降水量和年均气温是影响典型草原和荒漠草原NDVI的重要因子。基于气象因子的NDVI回归模型能够较好地对区域NDVI进行估测。生长季降水是影响典型草原NDVI的关键因素,而气温显著影响荒漠草原NDVI。在未来气候变化的背景下,内蒙古典型草原NDVI对干旱的响应会更加敏感。     

Effects of seasonal grazing,drought, fire,and carbon enrichment on soil microarthropods in a desert grassland

This study was designed to test hypotheses about the combined effects of short-term, seasonal grazing with seasonal drought, fire, and carbon enrichment on soil microarthropod communities in a Chihuahuan Desert grassland. The study was conducted in eighteen 0.5 ha plots following three consecutive years of treatment: six plots intensively grazed in summer, six in winter, and six not grazed. There was no difference in perennial grass cover on the summer-grazed and winter-grazed plots. Intensive seasonal grazing had no effect on the abundance and community composition of soil microarthropods. Within each plot there were six subplots: summer rain-out, winter rain-out, burned, glucose amendment, rain-out control and burn-glucose control. Fire and carbon enrichment had no significant effect on soil microarthropod abundance or community composition. The average number of microarthropods ranged from 8915 ± 1422 m⁻² in the ungrazed, unburned plots to 7175 ± 1232 m⁻² in the winter-grazed, unburned plots. Microarthropod densities in the glucose-amended plots were 8917 ± 4902 m⁻² in the winter-grazed plots and 10,731 ± 863 m⁻² in the glucose-amended, summer-grazed subplots.The prostigamatid mite, Tydeus sp., was the most abundant microarthropod taxon in all treatment plots.     

开垦对内蒙古温带草地土壤不同有机碳组分的影响(英文)

Cultivation is one of the most important human activities affecting the grassland ecosystem besides grazing, but its impacts on soil total organic carbon (C), especially on the liable organic C fractions have not been fully understood yet. In this paper, the role of cropping in soil organic C pool of different fractions was investigated in a meadow steppe region in Inner Mongolia of China, and the relationships between different C fractions were also discussed. The results indicated that the concentrations of different C fractions at steppe and cultivated land all decreased progressively with soil depth. After the conversion from steppe to spring wheat field for 36 years, total organic carbon (TOC) concentration at the 0 to 100 cm soil depth has decreased by 12.3% to 28.2%, and TOC of the surface soil horizon, especially those of 0-30 cm decreased more significantly (p<0.01). The dissolved organic carbon (DOC) and microbial biomass carbon (MBC) at the depth of 0-40 cm were found to have decreased by 66.7% to 77.1% and 36.5% to 42.4%, respectively. In the S.baicalensis steppe, the ratios of soil DOC to TOC varied between 0.52% and 0.60%, and those in the spring wheat field were only in the range of 0.18%-0.20%. The microbial quotients (qMBs) in the spring wheat field, varying from 1.11% to 1.40%, were also lower than those in the S. baicalensis steppe, which were in the range of 1.50%-1.63%. The change of DOC was much more sensitive to cultivation disturbance. Soil TOC, DOC, and MBC were significantly positive correlated with each other in the S. baicalensis steppe, but in the spring wheat field, the correlativity between DOC and TOC and that between DOC and MBC did not reach the significance level of 0.05.     

Effects of land use and cultivation time on soil organic and inorganic carbon storage in deep soils

The vertical distribution and exchange mechanisms of soil organic and inorganic carbon(SOC, SIC) play an important role in assessing carbon(C) cycling and budgets. However, the impact of land use through time for deep soil C(below 100 cm) is not well known. To investigate deep C storage under different land uses and evaluate how it changes with time, we collected soil samples to a depth of 500 cm in a soil profile in the Gutun watershed on the Chinese Loess Plateau(CLP); and determined SOC, SIC, and bulk density. The magnitude of SOC stocks in the 0–500 cm depth range fell into the following ranking: shrubland(17.2 kg m~(-2)) grassland(16.3 kg m~(-2)) forestland(15.2 kg m~(-2)) cropland(14.1 kg m~(-2)) gully land(6.4 kg m~(-2)). The ranking for SIC stocks were: grassland(104.1 kg m~(-2)) forestland(96.2 kg m~(-2)) shrubland(90.6 kg m~(-2)) cropland(82.4 kg m~(-2)) gully land(50.3 kg m~(-2)). Respective SOC and SIC stocks were at least 1.6-and 2.1-fold higher within the 100–500 cm depth range, as compared to the 0–100 cm depth range. Overall SOC and SIC stocks decreased significantly from the 5 th to the 15 th year of cultivation in croplands, and generally increased up to the 70 th year. Both SOC and SIC stocks showed a turning point at 15 years cultivation, which should be considered when evaluating soil C sequestration. Estimates of C stocks greatly depends on soil sampling depth, and understanding the influences of land use and time will improve soil productivity and conservation in regions with deep soils.     

Changes in soil organic carbon and other physical soil properties along adjacent Mediterranean forest, grassland, and cropland ecosystems in Turkey

Cultivation, overgrazing, and overharvesting are seriously degrading forest and grassland ecosystems in the Taurus Mountains of the southern Mediterranean region of Turkey. This study investigated the effects of changes on soil organic carbon (SOC) content and other physical soil properties over a 12-year period in three adjacent ecosystems in a Mediterranean plateau. The ecosystems were cropland (converted from grasslands in 1990), open forest, and grassland. Soil samples from two depths, 0–10 and 10–20 cm, were collected for chemical and physical analyses at each of cropland, open forest, and grassland ecosystems. SOC pools at the 0–20 cm depth of cropland, forest, and grassland ecosystems were estimated at 32,636, 56,480, and 57,317 kg ha⁻¹, respectively. Conversion of grassland into cropland during the 12-year period increased the bulk density by 10.5% and soil erodibility by 46.2%; it decreased SOM by 48.8%, SOC content by 43%, available water capacity (AWC) by 30.5%, and total porosity by 9.1% for the 0–20 cm soil depth (p<0.001). The correlation matrix revealed that SOC content was positively correlated with AWC, total porosity, mean weight diameter (MWD), forest, and grassland, and negatively with bulk density, pH, soil erodibility factor, and cropland. The multiple regression (MLR) models indicated that any two of the three ecosystems and one of the two soil depths accounted for 86.5% of variation in mean SOC values ((p<0.001).     

全球主要河流流域碳酸盐岩风化碳汇评估

碳酸盐岩风化吸收的大气CO₂主要以HCO₃ ^-形式连续地经由河流从大陆输送到海洋,成为陆地生态系统的重要碳汇。目前主要河流流域的碳酸盐岩风化碳汇估算存在不确定性,分布格局尚不清晰。基于GEMS-GLORI全球河流数据库提供的全球10万km ²以上主要河流流域多年平均监测数据,利用水化学径流法估算出全球主要河流流域碳酸盐岩对CO₂的吸收速率为0.43±0.15 Pg CO₂ yr ^-1,平均CO₂吸收通量为7.93±2.8 t km ^-2 yr ^-1。CO₂吸收通量在不同气候带下差异显著,热带和暖温带CO₂年吸收速率占全球主要河流流域年吸收速率的62.95%。冷温带CO₂年吸收速率占全球主要河流流域的33.05%,仅次于热带地区。本文划分出全球CO₂吸收通量的9个关键带,关键带的交汇处CO₂吸收通量较高。喀斯特出露流域碳酸盐岩对CO₂吸收通量的均值为8.50 t km ^-2 yr ^-1,约为非喀斯特流域的3倍。全球喀斯特出露流域碳酸盐岩风化碳汇在全球碳循环、水循环及碳收支平衡估算研究方面占据重要地位。     

干旱区盐碱土剖面无机碳组分分布特征

通过分离土壤动态性无机碳,结合14C同位素技术,有效量化了盐碱土剖面无机碳组分的存储数量和年龄特征。结果表明：整个土壤剖面,盐土难溶性无机碳含量和可溶性无机碳含量明显高于碱土。无论是土壤难溶性无机碳储量还是可溶性无机碳储量,盐土和碱土中有近80%碳是存储在1 m以下,50%存储于3 m以下。相同土层,土壤可溶性无机碳储量约占土壤难溶性无机碳储量的30%。无论是盐土还是碱土,无机碳的年龄超过万年,而土壤可溶性无机碳的年龄明显低于土壤无机碳的年龄。研究结果证实尽管土壤可溶性无机碳储量较低,但其周转时间短,速率高,因此在参与现代碳循环的程度上明显要高于土壤无机碳。     

Estimation of soil organic carbon reservoir in China

The paper respectively adopted physio-chemical properties of every soil stratum from 2473 soil profiles of the second national soil survey. The corresponding carbon content of soils is estimated by utilizing conversion coefficient 0.58. In the second soil survey, the total amount of soil organic carbon is about 924.18×108t and carbon density is about 10.53 kgC/m2 in China according to the area of 877.63×106 hm2 surveyed throughout the country. The spatial distribution characteristics of soil organic carbon in China is that the carbon storage increases when latitude increases in eastern China and the carbon storage decreases when longitude reduces in northern China. A transitional zone with great variation in carbon storage exists. Moreover, there is an increasing tendency of carbon density with decrease of latitude in western China. Soil circle is of great significance to global change, but with substantial difference in soil spatial distribution throughout the country. Because the structure of soil is inhomogeneous, it could bring some mistakes in estimating soil carbon reservoirs. It is necessary to farther resolve soil respiration and organic matter conversion and other questions by developing uniform and normal methods of measurement and sampling.     

Estimation of soil organic carbon reservoir in China

1 IntroductionResearch on global change has aroused many scientists' attention to the balance, storage and spatial distribution of carbon in the terrestrial ecosystem. The carbon stored in soil is 2.5-3 times as much as that stored in plants[1,2], so the distribution and conversion of carbon in humus has become one of the global research foci on organic carbon at present[3]. Organic carbon and nitrogen contents in soils are not only important components of soils but also the most important eco…     

准噶尔盆地灰漠土无机磷形态及磷吸附特性研究

选择新疆准噶尔盆地灰漠土作为研究对象,通过测定灰漠土中不同形态的无机磷素含量并进行土壤磷素等温吸附实验,研究灰漠土中各形态无机磷素的有效性和土壤磷吸附特征。结果表明,灰漠土中无机磷形态主要是Ca-P,占全磷含量75%以上,且以Ca₁₀-P形式为主,其次为Ca₈-P和Ca₂-P,无机磷中Al-P、Fe-P和O-P含量较少。全剖面中随着土层深度增加,Ca₂-P、Ca₈-P和Al-P占全磷总量的比例减少,Ca₁₀-P占全磷总量则有所增加,0~20 cm土层全磷和Olsen-P含量最高,分别平均为926 mg·kg^-1和51.54 mg·kg^-1。统计分析表明Ca₂-P、Al-P是最有效的磷源,Ca₈-P和Fe-P是第二有效磷源,O-P和Ca₁₀-P则是作物的潜在磷源。利用Langmuir方程拟合灰漠土的磷等温吸附曲线,得出土壤最大吸磷量（Xm）为957±629 mg·kg^-1,吸附参数（K）为149.285±89.225;灰漠土的粘粒含量对Xm影响最大,其次是有机质,pH值影响最小。     

Dissolved and total organic and inorganic carbon in some British rivers

Rivers transport both organic and inorganic carbon from their sources to the sea. Results of ~800 organic and inorganic analyses from various British rivers of contrasting size and land use are presented here: (1) the headwater River Tern, a rural river of 852 km² catchment; (2) the Ouseburn, a small urban 55 km² catchment; (3) the River Tyne, a larger river system of ~3000 km² catchment; (4) a spatial survey from 205 sample sites on ~60 rivers from SW England. We found that, with the exception of peat-rich headwaters, DIC concentration is always greater than DOC. DIC is primarily in the form HCO₃ ⁻ , with DIC concentrations highest in highly urbanised catchments, typically greater than those observed in catchments with carbonate bedrock, demonstrating a significant and previously unrecognised anthropogenic inorganic carbon input to urban rivers.