桂林峰丛洼地岩溶动力系统CO2特征及变化规律

桂林岩溶水文地质试验场属于典型的峰丛洼地地区.峰丛洼地表层岩溶动力系统与土壤CO2密切相关,土壤CO2体积分数以及表层岩溶带土壤CO2溶蚀量的变化受气温和降雨影响.对不同部位不同深度的土壤CO2体积分数进行了野外监测,并利用多参数自动记录仪监测了泉水的水化学,揭示了CO2体积分数的变化规律.其变化特征表现为:①土壤CO2体积分数的季节变化在泉水水化学上和土壤CO2溶蚀量上均能反映出来;②土壤CO2体积分数的变化具有季节性;③50 cm处的CO2体积分数较20 cm处大;④土壤层对泉水水化学起到重要调蓄作用.     

亚热带森林岩溶区土壤CO2迁移动态初步研究

贵州茂兰是研究森林覆盖下岩溶表层系统结构特征、运行规律的重要基地.本文初步研究了该地区碳迁移的若干特征 (1) 土壤剖面中CO2浓度变化.秋、冬季土下CO2浓度,50cm处始终高于20 cm处,而在春、夏季土壤剖面中CO2浓度变化幅度大,20cm处的浓度时常高出50cm处. 土下20cm、50cm处CO2浓度在不同季节的变化趋势是夏季(32 833×10-6、 38 666×1 0-6)春季(24 416×10-6,28 800×10-6)秋季(6 450×1 0-6),14 216×10-6＞冬季(3 833×10-6,8 833× -6),土下CO2浓度变化趋势与温度和降雨量有较好的正相关关系.20cm处的CO 2浓度变化与温度的相关系数r＝0.89,与降雨量的相关系数r＝0.70;50cm处的CO 2浓度变化与温度的相关系数r＝0.69, 与降雨量的相关系数r＝0.66.(2)土壤呼吸释放C O2的速率有类似的变化规律夏季为339.68mg.m-2.h-1、为281. 74mg.m-2.h-1、秋季为206.59mg.m-2.h-1、冬季为65.53mg.m-2.h-1.年均排放量为1.96kg.m-2.yr- 1.(3)随水排泄HCO3-1是岩溶表层泉碳迁移的重要组分.表层泉水的H CO3-1浓度的季节变化与气温、月降雨量、土下20cm处CO2浓度存在着负相关,其相关系数r＝-0.57、-0.71和-0.47,而与表层泉水的pH值之间没有显著的相关关系.这与非森林岩溶区的观测结果有一定的差异,内在的机理需要对相关的生物学的指标进一步的研究;(4)野外溶蚀试片的测试结果表明,夏季的岩溶作用强度是春季的2.6倍.     

亚热带森林岩溶区土壤CO_2迁移动态初步研究

贵州茂兰是研究森林覆盖下岩溶表层系统结构特征、运行规律的重要基地。本文初步研究了该地区碳迁移的若干特征 :(1)土壤剖面中CO2 浓度变化。秋、冬季土下CO2 浓度 ,5 0cm处始终高于 2 0cm处 ,而在春、夏季土壤剖面中CO2 浓度变化幅度大 ,2 0cm处的浓度时常高出5 0cm处。土下 2 0cm、 5 0cm处CO2 浓度在不同季节的变化趋势是夏季 (32 833× 10 - 6、 386 6 6× 10 - 6)春季 (2 4 4 16× 10 - 6,2 880 0× 10 - 6)秋季 (6 4 5 0× 10 - 6) ,142 16× 10 - 6>冬季 (3833× 10 - 6,8833× - 6) ,土下CO2 浓度变化趋势与温度和降雨量有较好的正相关关系。 2 0cm处的CO2 浓度变化与温度的相关系数r =0 89,与降雨量的相关系数r =0 70 ;5 0cm处的CO2 浓度变化与温度的相关系数r =0 6 9,与降雨量的相关系数r =0 6 6。 (2 )土壤呼吸释放CO2 的速率有类似的变化规律 :夏季为 339 6 8mg m- 2 h- 1、为 2 81 74mg m- 2 h- 1、秋季为 2 0 6 5 9mg m- 2 h- 1、冬季为 6 5 5 3mg m- 2 h- 1。年均排放量为 1 96kg m- 2 yr- 1。 (3)随水排泄HCO3 - 1是岩溶表层泉碳迁移的重要组分。表层泉水的HCO3 - 1浓度的季节变化与气温、月降雨量、土下 2 0cm处CO2浓度存在着负相关 ,其相关系数r =- 0 5 7、     

半干旱岩溶区土壤次生碳酸盐比例及对岩溶碳汇计算的影响

定量评价半干旱岩溶区土壤次生碳酸盐比例和来源有助于认识土壤系统影响岩溶作用的机理。选取山西晋中盆地西南,吕梁山东侧的半干旱岩溶区马跑神泉小流域为研究对象,通过对林地、退耕地、灌丛地土壤剖面进行分层取样并测定碳酸盐含量及其δ13C、CO2浓度及其δ13C值,分析其随深度的变化规律和控制因素;并结合研究区碳酸盐岩的δ13C值计算3个剖面各层土壤次生碳酸盐所占比例。研究结果表明:3个土壤剖面的碳酸盐含量、CO2浓度在0~50 cm土层随深度增加而增加,在50~70 cm土层随深度增加而减少;土壤碳酸盐δ13C值、δ13CCO2值在0~50 cm土层随深度增加而偏负,在50~70 cm土层随深度增加而偏重;土壤碳酸盐含量及其δ13C值主要受次生碳酸盐比例控制,而土壤CO2及其δ13CCO2值在上层主要受大气CO2和土壤有机质分解生成的CO2共同影响,下层还受土-岩界面岩溶作用过程制约;退耕地、林地、灌丛剖面次生碳酸盐所占比例的均值分别为52%、42%和32%,证实北方半干旱岩溶区土壤中存在原生碳酸盐向次生碳酸盐转化过程。      

土地利用和覆被变化对岩溶区土壤CO2浓度的影响

通过选择3个具有不同地质背景、气候条件等环境特征的山西汾阳马跑-郭庄岩溶泉域、湖南湘西大龙洞地下河流域、广西桂江流域,对流域内具有代表性的不同土地利用方式和覆被类型下垫面土壤20~50cm深处CO2浓度进行检测。结果显示,土地利用方式和覆被变化对3个流域岩溶土壤中20cm、30cm、40cm和50cm深处CO2浓度具有明显的影响作用:湖南湘西大龙洞地下河流域多数样地土壤CO2表现为随土层的加深先增加后降低的双向梯度;山西马跑-郭庄泉域玉米地的土壤CO2浓度比种植马铃薯的高,且随着覆被条件由草地→灌丛→林地的改善,土壤的扰动性变小,CO2浓度差趋于减少,变幅趋于稳定。各个流域相同覆被类型,群落结构和优势种变化越小,土壤CO2浓度变幅越小。      

土壤CO_2浓度变化特征及其水文地质意义研究

利用EGM-4便携式环境气体检测仪,在野外现场及室内开展沙柱试验,检测土壤不同深度的CO_2浓度。结果表明:土壤中CO_2浓度具有明显的差异性,具有随着植被发育程度增高而升高的趋势。(1)土壤中CO_2浓度比当地大气及地表CO_2浓度显著偏高;(2)野外现场测试得到,随深度增加,土壤温度及CO_2浓度逐渐升高,于深度210cm处土壤CO_2浓度似存在极大值;(3)不同坡度时,坡度较小者的土壤CO_2浓度偏高;相同坡度时,植被条件好的土壤CO_2浓度偏高;(4)在单棵树株周围,具有随着与树干距离增加,同样深度土壤CO_2浓度逐渐减小的趋势。文章讨论了土壤(包气带)CO_2浓度变化与水的溶滤能力及地下水化学性质之间的关系等水文地质意义。     

峰丛洼地坡面流径流过程——以丫吉试验场为例

选取裸露型和土壤植被覆盖型两种峰丛洼地地貌结构.通过降雨量、pH、电导率(Ec)、CO2分压和流量的过程线来分析降雨中详细的产流过程.裸露性坡地因包气带结构简单仅存在局部的超渗产流和表层岩溶带的回归流.水化学性质较稳定;有土壤植被覆盖的坡地的产流过程可以分为3个阶段:补偿阶段(可出现超渗产流)、饱和径流阶段、稳定阶段,补偿阶段仅在降雨强度大于入渗强度时可产生坡面流,饱和径流阶段坡面流流量与降雨强度成正比.稳定阶段坡面流流量趋于稳定,不随雨强的变化而变化,坡面流的水化学性质变化剧烈,pH、电导率(Ec)、CO2分压基本上同步变化,水漫(T)在降雨前期变化规律不明显.后期与pH、Ec等呈相反变化.     

小降雨事件对土壤水分及植物水势空间差异性的影响

本文以云南省蒙自市断陷盆地高原面上典型封闭式岩溶洼地小流域为研究对象,研究小降雨事件对土壤水分及植物水势的影响。结果表明:（1）在研究区内小降雨事件一般只能补给10 cm以上的土壤,因此在旱季（强降雨事件发生前）,土壤水分随着深度的增加整体呈变小的趋势;受洼地地形影响,整个土壤剖面（0 ~ 80 cm）的土壤水分存在从坡顶到洼地底部逐渐增加,苹果树叶水势逐渐升高的现象;受地质背景的影响,土石质坡地平均土壤水分比石质坡地土壤水分高2.67%,相对应的土石质坡地苹果树受干旱胁迫的程度要低于石质坡地。（2）通过观测对比发现,8天内12次的小降雨事件可以使0~10 cm土壤水分整体上略有升高,但并未能完全改变0~10 cm土壤水分洼地底部大于两侧坡地,而土石质坡地高于石质坡地的特征。（3）小降雨事件虽然只能补给0~10 cm的土壤水分,但由于坡地地区苹果树根系分布较浅（5~30 cm）,部分浅层分布的苹果树根系已能吸收到水分,另一方面小降雨事件具有降温、增湿,减少太阳辐射的作用,可以减小苹果树蒸腾作用,从而降低苹果树叶水势,因此推测小雨事件可以明显减轻苹果树受干旱胁迫的程度      

断陷盆地高原面典型岩溶洼地旱季土壤水氢氧同位素时空差异特征

以云南省蒙自断陷盆地东山山区典型岩溶洼地为研究区,通过野外采集土壤样品与实验室测试分析相结合的方法,运用稳定同位素技术研究旱季不同深度土壤水氢氧同位素组成,揭示区内土壤水氢氧同位素时空变化特征,为进一步研究云南断陷盆地山区土壤水分运移机制和当地农业合理利用和管理水资源提供科学依据。结果表明:(1)土壤水δD、δ18O同位素值的变化范围分别为-128.3‰~-27.6‰和-17.5‰~2.5‰,平均值分别为-96.1‰±20.7‰和-12.3‰±3.7‰,降雨转化为土壤水和水分在土壤中重新分布时发生一定程度的氢氧同位素分馏。(2)旱季两个月份土壤水氢氧同位素组成发生变化,4月份土壤水δD、δ18O同位素平均值分别为-86.3‰±23.83‰和-10.6‰±4.3‰,显著高于2月份(δD:-106.1‰±9.5‰;δ18O:-14.1‰±1.6‰)(p<0.05),主要和4月份土壤水的蒸发作用强烈有关。(3)在空间上,坡地与洼地之间土壤水氢氧同位素组成存在差异,2月份坡地与洼地之间土壤水δD、δ18O值差异显著(p<0.05),洼地土壤水δD、δ18O比坡地偏轻;4月份坡地与洼地之间土壤水δD、δ18O值差异不显著(p>0.05)。(4)土壤垂直剖面方向上土壤水δD、δ18O值随着土壤深度的增加而减小,浅层土壤水δ18O和深层土壤水δ18O存在显著差异,2月份浅层土壤水δ18O比深层土壤水δ18O偏正2.8‰,4月份浅层土壤水δ18O比深层土壤水δ18O偏正10.5‰。      

石漠化治理对土壤中CO2、CH4变化特征及碳汇效应的影响

为探究石漠化治理对土壤中CO2、CH4变化特征及碳汇效应的影响,采用气相色谱法对重庆市南川石漠化治理示范区土壤中CO2、CH4浓度进行观测,结合土壤温度、土壤含水率、土壤容重和土壤有机碳对石漠化治理区（试验区）和对比区（未经过石漠化治理的荒草地）进行研究,并用溶蚀量数据估算岩溶区碳汇量。结果显示:土壤中CO2浓度随土壤深度的增加先增加后减小,变化范围为393～7 400 mg·L-1;而土壤中CH4浓度随土壤深度的增加先减小后增大,变化范围为1.13～3.42 mg· L-1。试验区土壤中CO2浓度均值为2 131 mg· L-1,CH4浓度均值为1.94 mg· L-1 ;而对比区土壤中CO2浓度均值为2 338 mg· L-1,CH4浓度均值为2.10 mg·L-1。土壤温度、土壤有机碳与土壤中CO2浓度变化趋势呈显著正相关关系,而与土壤中CH4变化趋势呈显著负相关关系,说明土壤温度和土壤有机碳是影响土壤中CO2、CH4浓度的主要因素;土壤温度与土壤中CO2浓度呈正相关关系且相关性随石漠化治理而变弱,说明经过石漠化治理土壤温度对土壤中CO2浓度的影响减弱。试验区岩溶试片溶蚀速率大于对比区,且经过石漠化治理,由岩溶作用产生的碳汇可提高0.66～9.42 t·km-2·a-1 ;说明石漠化治理对于岩溶区碳汇起到了促进作用。      

Soil CO2 concentration in biological soil crusts and its driving factors in a revegetated area of the Tengger Desert,Northern China

Biological soil crusts (BSCs) are an important cover in arid desert landscapes, and have a profound effect on the CO₂ exchange in the desert system. Although a large number of studies have focused on the CO₂ flux at the soil–air interface, relatively few studies have examined the soil CO₂ concentration in individual layers of the soil profile. In this study, the spatiotemporal dynamics of CO₂ concentration throughout the soil profile under two typical BSCs (algae crusts and moss crusts) and its driving factors were examined in a revegetated sandy area of the Tengger Desert from Mar 2010 to Oct 2012. Our results showed that the mean values of the vertical soil CO₂ concentrations under algal crusts and moss crusts were 600–1,200 μmol/mol at the 0–40 cm soil profiles and increased linearly with soil depth. Daily CO₂ concentrations showed a single-peak curve and often had a 1–2 h time delay after the maximum soil temperature. During the rainy season, the mean soil CO₂ concentration profile was 1,200–2,000 μmol/mol, which was 2–5 times higher as compared to the dry season (400–800 μmol/mol). Annually, soil moisture content was the key limiting factor of the soil CO₂ concentration, but at the daily time scale, soil temperature was the main limiting factor. Combined with infiltration depth of crusted soils, we predicted that precipitation of 10–15 mm was the most effective driving factor in arid desert regions.     

Spatial heterogeneity of soil organic matter and soil total nitrogen in a Mollisol watershed of Northeast China

The spatial heterogeneity of soil nutrients influences crop yield and the environment. Previous research has focused mainly on the surface layer, with little research being carried out on the deep soil layers, where high root density is highly related to crop growth. In the study, 610 soil samples were collected from 122 soil profiles (0–60 cm) in a random-sample method. Both geostatistics and traditional statistics were used to describe the spatial variability of soil organic matter (SOM) and total nitrogen (TN) deeper in the soil profile (0–60 cm) with high root density from a typical Mollisol watershed of Northeast China. Also, the SOM and TN in farmland and forest (field returned to forest over 10 years) areas was compared. The spatial autocorrelations of SOM at 0–50 cm depth and TN at 30–60 cm depth were strong, and were mainly influenced by structural factors. Compared to farmland, SOM and TN were typically lower in the 0–30 cm depth of the forest areas, while they were higher in the 30–60 cm depth. As well, both SOM and TN decreased from the 0–20 cm layer to the 30–40 cm layer, and then discontinues, while they continuously decreased with increasing soil depth in the farmland. SOM and TN were typically higher at the gently sloped summit of the watershed and part of the bottom of the slope than at mid-slope positions at the 0–30 cm depth. SOM and TN were lower on the back slope at the 30–60 cm depth, but were higher at the bottom of the slope. Also, the spatial distribution of the carbon storage and nitrogen storage were all highest at the bottom of the slope and part of the summit, while they were lowest in most of back slope in depth of 0–60 cm, and mainly caused by soil loss and deposition. SOM at 0–60 cm and TN at 0–40 cm greater than the sufficiency level for crop growth (3.7–79.2 and 0.09–3.09 g kg^?1, respectively) covered 99 % of the total area, yet for TN, over 35 % of the total area was less than the insufficiency level at the 40–60 cm depth. Generally, accurately predicting SOM and TN is nearly impossible when based only on soil loss by water, although the fact that variability is influenced by elevation, soil loss, deposition and steepness, was shown in this research. Nitrogen fertilizer and manure application were needed, especially in conjunction with conservation tillage in special conditions and specific areas such as the back slope, where soil loss was severe and the deep soil that lacked TN was exposed at the surface.     

表层岩溶系统中土-气-水界面碳流通的短尺度效应——以贵州茂兰国家喀斯特森林公园的秋季日动态监测为例

在2001年秋季对贵州省荔波县茂兰国家喀斯特森林公园林地、草地植被下土壤CO₂呼吸释放及岩溶表层泉水HCO₃及其^δ13C值的变化进行了日动态的野外监测,表明岩溶系统中土-气-水界面间存在着碳交换的日动态变化以及所伴随的同位素交换的变化,这种变化与土温的日动态有密切的关系。林地植被显示了平抑这种日动态幅度的效应,而草地植被则显示响应于温度变化的较灵敏的动态变化。这种短尺度的变化构成了表层岩溶系统对外界条件的灵敏响应,进一步揭示了在生物作用下岩溶地质作用在碳循环过程及其同位素交换上的灵敏性和动态性。其不同植被系统下的日动态差异在解释岩溶沉积记录和讨论岩溶作用与碳循环时值得充分注意     

Carbon dioxide concentration and atmospheric flux in the Hudson River

We made direct measurements of the partial pressure of CO₂ (P_{CO 2}) in the tidal-freshwater portion of the Hudson River Estuary over a 3.5-yr period. At all times the Hudson was supersaturated in CO₂ with respect to the atmosphere. P_{CO 2} in surface water averaged 1125±403 (SD) μatm while the atmosphere averaged 416±68 μatm. Weekly samples at a single, mid-river station showed a pronounced and reproducible seasonal cycle with highest values (～2000 μatm) in mid-to-late summer, and lowest values (～500 μatm) generally in late winter. Samples taken along the length of the 190-km section of river showed a general decline in CO₂ from north to south. This decline was most pronounced in summer and very slight in spring. Diel and vertical variation were small relative to the standing stock of CO₂. Over six diel cycles, all taken during the algal growing season, the mean range was 300±114 μatm. CO₂ tended to increase slightly with depth, but the gradient was small, about 0.5 μmol m^?1, or an increase of 190 μatm from top to within 1 m of the bottom. For a large subset of the samples (n=452) we also calculated CO₂ from measurements of pH and total DIC. Calculated and measured values of CO₂ were in reasonably good agreement and a regression of calculated versus measured values had a slope of 0.85±0.04 and an r₂ of 0.60. Combining our measurements with recent experimental studies of gas exchange in the Hudson, we estimate that the Hudson releases CO₂ at a rate of 70–162 g C m^?2 yr^?1 from the river to the atmosphere.     

Carbon losses in soils previously exposed to elevated atmospheric CO2 in a chaparral ecosystem: Potential implications for a sustained biospheric C sink

Between 1996 and 2001 an experimental set up in a chaparral community near San Diego, CA, examined various plant and ecosystem responses to CO₂ concentrations ranging from 250 to 750 μl l^− 1. These experiments indicated a significant increase in soil C sequestration as CO₂ rose above the ambient levels. In 2003, two years after the cessation of the CO₂ treatments, we returned to this site to examine soil C dynamics with a particular emphasis on stability of specific pools of C. We found that in as little as two years, C content in the surface soils (0–15 cm) of previously CO₂ enriched plots had dropped to levels below those of the ambient and pretreatment soils. In contrast, C retained in response to CO₂ enrichment was more durable in the deeper soil layers (> 25 cm deep) where both organic and inorganic C were on average 26% and 55% greater, respectively, than C content of ambient plots. Using stable isotope tracers, we found that treatment C represented 25% of total soil C and contributed to 55% of soil CO₂ efflux, suggesting that most of treatment C is readily accessible to decomposers. We also found that, C present before CO₂ fumigation was decomposed at a faster rate in the plots that were exposed to elevated CO₂ than in those exposed to ambient CO₂ levels. To our knowledge, this is the first report that allows for a detail accounting of soil C after ceasing CO₂ treatments. Our study provides a unique insight to how stable the accrued soil C is as CO₂ increases in the atmosphere.     

大夏河甘南段河流湿地土壤节肢动物群落特征及季节动态

采用国际通用采样方法,在春、夏、秋三季对大夏河甘南段河流湿地6个样点土壤节肢动物群落进行了调查研究,比较分析了土壤节肢动物群落组成、多样性及其季节动态特征.结果表明：共捕获土壤节肢动物8 743只,隶属于3纲9目33科35类,其中,大型土壤节肢动物2 743只,占捕获量的35.52%;中小型土壤节肢动物6 000只,占64.48%;大型土壤节肢动物的优势类群为摇蚊科幼虫和长足虻科幼虫;中小型土壤节肢动物的优势类群为绥螨科、绒螨科、等节跳属和原等跳属. 在不同样点土壤节肢动物类群数和个体数量表现出了明显季节变化,其高低顺序为秋季>夏季>春季;不同样点土壤节肢动物的垂直分布具有明显的表聚特征,即从地表向下,随着土壤深度的增加土壤节肢动物类群数和个体数量逐渐减少.研究结果为进一步开展高原寒区河流湿地土壤节肢动物生态学研究提供了基础资料.     

Time-lapse crosswell seismic and VSP monitoring of injected CO<Subscript>2</Subscript> in a brine aquifer

Seismic surveys successfully imaged a small scale CO₂ injection (1,600 ton) conducted in a brine aquifer of the Frio Formation near Houston, Texas. These time-lapse borehole seismic surveys, crosswell and vertical seismic profile (VSP), were acquired to monitor the CO₂ distribution using two boreholes (the new injection well and a pre-existing well used for monitoring) which are 30 m apart at a depth of 1,500 m. The crosswell survey provided a high-resolution image of the CO₂ distribution between the wells via tomographic imaging of the P-wave velocity decrease (up to 500 m/s). The simultaneously acquired S-wave tomography showed little change in S-wave velocity, as expected for fluid substitution. A rock physics model was used to estimate CO₂ saturations of 10–20% from the P-wave velocity change. The VSP survey resolved a large (∼70%) change in reflection amplitude for the Frio horizon. This CO₂ induced reflection amplitude change allowed estimation of the CO₂ extent beyond the monitor well and on three azimuths. The VSP result is compared with numerical modeling of CO₂ saturations and is seismically modeled using the velocity change estimated in the crosswell survey.     

Experimental and numerical studies of the O exchange between CO2 and water in the atmosphere-soil invasion flux

The ¹⁸O/¹⁶O ratio of CO₂ is a potentially powerful tracer of carbon dioxide fluxes from the soil to the atmosphere, which is influenced by complex interactions involving both biotic and abiotic soil processes. We use a simplified experimental approach and numerical simulations to examine in isolation the ¹⁸O exchange between CO₂ and soil water associated with the abiotic invasion of atmospheric CO₂ into soil. This allowed us to verify, in particular, whether the ¹⁸O of the retro-diffusion flux of CO₂ from the soil reflects ¹⁸O equilibration with water at the soil surface, or at some depth. Sterile soil samples with known water isotopic composition were placed in a closed box attached to a specially designed flow chamber and the changes in δ¹⁸O of CO₂ between the chamber inlet and outlet, due only to invasion effects, were determined. Numerical simulations constrained by the laboratory gas exchange measurements indicated that between the two commonly used diffusion models [Penman, H.L. (1940). Gas and vapor movements in soil, 1: the diffusion of vapors through porous solids. Int. J. Agric. Sci.30, 437-462; Moldrup, P., Olesen, T., Yamaguchi, T., Schjonning, P., Rolston, D.E. (1999). Modeling diffusion and reaction in soils, IX, the Backingham-Burdine-Campbell equation for gas diffusivity in undisturbed soil. Soil Sci.164, 542-551], only the former provided good agreement with the measurements over a wide range of soil water contents. Based on the model calculations constrained by experimental data, and on comparison of characteristic diffusion/reaction times, we conclude that the depth required for full CO₂-water ¹⁸O equilibration ranges between 2 and 8.5 cm. The depth depends, in order of importance, on (1) soil moisture content; (2) temperature, which dominates the rate of hydration isotopic exchange; (3) CO₂ residence time, which is determined by the time of replacement of the column air above the soil; and (4) soil structure, including porosity, tortuosity and grain size, with the later probably influencing the water surface area exposed to CO₂ exchange. Using field data from a semi-arid forest site in Israel, numerical simulations indicated that the ¹⁸O full equilibrium depth varied at this site between 4 cm (January) and 8 cm (November), being sensitive mostly to temperature and soil water content. Deepening of the equilibration depth as the soil dries should limit the effects of ¹⁸O evaporative enrichment at the surface on the isotopic composition of the soil-atmosphere CO₂ flux.     

乌鲁木齐河源1号冰川雪-冰界面含氮离子迁移研究

冰川积累区雪-冰界面附近的化学物质迁移对冰芯记录的形成具有重要意义,为讨论主要含氮离子在这一界面的迁移,本研究基于2004年11月至2006年3月在天山乌鲁木齐河源1号冰川连续采集的64组雪冰样品分析了NO3与NH4+的变化情况.结果表明,雪层底部干季(11月至翌年3月)含氮离子浓度的平均值高于湿季(4-10月)的,而...