不同植被类型的土壤水分对黄土高原的影响

Water stored in deep loess soil is one of the most important resources regulating vegetation growth in the semi-arid area of the Loess Plateau, but planted shrub and forest often disrupt the natural water cycle and in turn influence plant growth. The purpose of this study was to examine the effects of main vegetation types on soil moisture and its inter-annual change. Soil moisture in 0–10 m depth of six vegetation types, i.e., crop, grass, planted shrub of caragana, planted forests of arborvitae, pine and the mixture of pine and arborvitae were measured in 2001, 2005 and 2006. Soil moisture in about 0–3 m of cropland and about 0–2 m of other vegetation types varied inter-annually dependent on annual precipitation, but was stable inter-annually below these depths. In 0–2 m, soil moisture of cropland was significantly greater than those of all other vegetation types, and there were no significant differences among other vegetation types. In 2–10 m, there was no significant moisture difference between cropland and grassland, but the soil moistures under both of them were significantly higher than those of planted shrub and forests. The planted shrub and forests had depleted soil moisture below 2 m to or near permanent wilting point, and there were no significant moisture differences among forest types. The soil moisture of caragana shrub was significantly lower than those of forests, but the absolute difference was very small. The results of this study implicated that the planted shrub and forests had depleted deep soil moisture to the lowest limits to which they could extract and they lived mainly on present year precipitation for transpiration.     

不同植被类型对厚层黄土剖面水分含量的影响

为了研究不同植被类型土壤水分差异和土壤水分的年际变化特征, 对陕西省绥德县境 内的农地、天然草地、人工柠条林、人工侧柏林、人工油松林、人工油松侧柏混交林地0~10 m 土壤剖面的土壤水分含量进行了测定与分析。农地土壤约在3 m 以上、其他植被类型约在 2 m 以上土层的土壤含水量随年降雨量的大小存在年际变化, 且农地土壤含水量显著高于其 他植被类型, 其他植被类型间无显著性差异。0~2 m 土层农地土壤水分在不同测定年份始终在易效水以上, 但其他植被类型的土壤水分随降雨量的不同变化于难效- 无效水与易效水之间。农地3 m、其他植被类型约2 m 以下的土壤含水量无显著性年际变化。农地与天然草地 土壤含水量显著高于其他人工林植被, 但二者含水量之间无显著差异, 土壤水分都属易效水 范围。人工柠条灌木林土壤水分显著低于其他植被类型, 人工侧柏林、人工油松林和人工油 松侧柏混交林之间土壤含水量无显著性差异。人工柠条林土壤水分属于难效-无效水范围, 人工乔木林接近难效-无效水范围。     

黄土高原半干旱区天然锦鸡儿灌丛对土壤水分的影响

本文选择黄土高原半干旱区定西地区的一种地带性植被,天然甘蒙锦鸡儿灌丛,将其0～99m深的土壤水分含量与人工柠条锦鸡儿灌丛、人工杏树林、天然草地、放牧荒坡和农地的土壤水分含量进行了比较。结果发现,天然锦鸡儿灌丛在1m以下土壤各层的水分含量均高于人工柠条灌丛和人工杏树林,而与放牧荒坡和农地的土壤湿度接近,略低于农地。天然锦鸡儿灌丛4m以上土层的土壤湿度还明显高于天然草地;天然锦鸡儿灌丛形成的难效—无效水层深度在2m土层以上,而人工柠条灌丛形成的难效无效水层则深达56m,人工杏树林42m,天然草地、放牧荒坡分别为36m和33m,农地1m。     

蓝田、长安人工林地土层含水量研究

根据蓝田孟村杨树林和梧桐林、长安县韦曲镇南杨树林地与西安市南郊麦地土壤含水量的测定,研究了0～600cm土壤含水量的变化和土壤干层特点与分布。实验表明,蓝田、长安地区在正常降雨年份人工林地土壤含水量从地表向地下呈现由高到低再到高的变化：12龄杨树林、14龄梧桐林、13龄和10龄杨树林地180～360cm深度范围内土壤含水量平均为9．5％、9．3％、9．0和9．2％,发育了明显的土壤干层：麦地土层含水量较梧桐林和杨树林地明显高,无土壤干化的显示;在丰水年蓝田、长安地区人工林土层含水量与正常降雨年份林地土壤含水量显著不同,12龄杨树林、14龄梧桐林、13龄和10龄杨树林地180～360cm深度范围内土壤含水量平均为22．5％、23．2％、22．5％和22．4％,土壤干层消失。这表明在降水量增加的条件下,土壤干层中的水分完全有可能恢复。土壤干层的发育会影响植物的正常生长,植被类型,植树造林和生态环境恢复,因此土壤干层水分恢复有重要意义。     

黄土高原西部荒漠草原植被恢复的土壤水分管理研究

针对兰州地区荒漠草原带具有代表性的三种地带性植被：草本植被短花针茅、灌木植被珍珠猪毛菜、荒漠锦鸡儿,对其0~2.0 m的土壤含水量进行了比较,同时对草本和灌木植被的根系进行了测定。结果表明：天然植被对土壤含水量的影响在1 m以上。随着土壤深度的不断加深,土壤含水量呈减少趋势而后趋于稳定。短花针茅区1 m以上含水量比珍珠猪毛菜和荒漠锦鸡区平均高1.08和1.21个百分点;1 m以下土壤含水量变化情况是:珍珠猪毛菜区最高,荒漠锦鸡儿区最低。本文在分析了兰州地区荒漠草原区土壤水分动态的基础上,提出了这一地区植被恢复的对策。     

Effects of afforestation on soil carbon turnover in China’s subtropical region

Afforestation in China’s subtropics plays an important role in sequestering CO2 from the atmosphere and in storage of soil carbon (C). Compared with natural forests, plantation forests have lower soil organic carbon (SOC) content and great potential to store more C. To better evaluate the effects of afforestation on soil C turnover, we investigated SOC and its stable C isotope (δ13C) composition in three planted forests at Qianyanzhou Ecological Experimental Station in southern China. Litter and soil samples were collected and analyzed for total organic C, δ13C and total nitrogen. Similarly to the vertical distribution of SOC in natural forests, SOC concentrations decrease exponentially with depth. The land cover type (grassland) before plantation had a significant influence on the vertical distribution of SOC. The SOC δ13C composition of the upper soil layer of two plantation forests has been mainly affected by the grass biomass 13C composition. Soil profiles with a change in photosynthetic pathway had a more complex 13C isotope composition distribution. During the 20 years after plantation establishment, the soil organic matter sources influenced both the δ13C distribution with depth, and C replacement. The upper soil layer SOC turnover in masson pine (a mean 34% of replacement in the 10 cm after 20 years) was more than twice as fast as that of slash pine (16% of replacement) under subtropical conditions. The results demonstrate that masson pine and slash pine plantations cannot rapidly sequester SOC into long-term storage pools in subtropical China.     

地表径流对荒漠灌丛生境土壤水分空间特征的影响

土壤水分是干旱区多尺度生态水文过程的关键影响因素和驱动因子,其时空格局是生态、水文、气象、地形等自然过程研究的重要参数。笔者研究了降水径流事件后3种不同灌丛个体尺度土壤水分空间异质性特征,结果表明,珍珠灌丛个体尺度土壤水分空间分布特征表现为灌丛边缘>灌丛内部>灌丛间裸地,驼绒藜灌丛表现为灌丛内部>灌丛边缘>灌丛间裸地,而狭叶锦鸡儿灌丛不同微生境土壤水分差异不显著。珍珠和驼绒藜灌丛同一微生境土壤水分存在坡位梯度,珍珠灌丛3个微生境土壤水分均表现为上坡位大于下坡位,而驼绒藜灌丛边缘表现为上坡位小于下坡位,其他两个微生境无明显规律;狭叶锦鸡儿灌丛土壤水分无明显的坡位梯度。3种灌丛不同微生境土壤含水量随土层深度增加的变化不明显。这说明在降水径流事件中,不同斑块的反应差异引起了地表径流的形成以及随之发生的资源再分配,从而导致了景观内土壤水分的空间异质性。     

Comparison of Soil Moisture in Different Soil Layers between Three Typical Forests in the Upper Reaches of Lijiang River Basin,Southern China

Throughfall, stemflow, evapotranspiration and infiltration are likely to vary with forest types, and consequently affect soil moisture regimes in different soil layers. In this study, the spatial and temporal characteristics of soil moisture were investigated to understand variations in soil moisture in three typical forests, including Phyllostachys pubescens forest (abbreviated as PPF), Schima superba forest (abbreviated as SSF) and Cunninghamia lanceolata forest (abbreviated as CLF) in the upper reaches of Lijiang River basin in southern China. The results showed that, (1) Litterfall and soil physical properties differed significantly in the three typical forests. Infiltration capacity in SSF was more favorable to soil moisture than in PPF and CLF. (2) Large variations were found in soil moisture at different forest stands and depths. Due to complicated vertical structures, there were obvious differences in soil moisture from the 0-20 cm soil layer to the 50-80 cm soil layer. (3) Average soil moisture in each layer was higher in SSF than in PPF and CLF. (4) Soil moisture in different layers correlated closely with precipitation (P<0.01) and the three typical forests had the same change trends with rainfall during the studying period. (5) In topsoil, soil moisture was influenced by soil properties which were mostly determined by litterfall, while in deep soil, soil moisture was affected by variations of soil characteristics, which were mostly determined by root distribution. This study provides a scientific basis for better understanding the relationships between forest vegetation and its hydrological effects, helping to facilitate water resources conservation and achieving wise forest management in the upper reaches of Lijiang River basin.     

不同地形条件对沙漠植物生长和沙地土壤水分的影响

对沙坡头地区人工植被固定沙地内不同地形条件下土壤水分和植物生长的变化进行了研究。结果表明,沙地土壤水分的变化以及植物生长的变化依照不同的地形条件表现出一定的规律性。沙地土壤水分含量由高至低的变化趋势根据地形条件依次表现为:丘间低地>迎风坡>坡顶>背风坡;灌木植物密度和盖度与土壤水分变化密切相关,由大到小的变化趋势同样为:丘间低地>迎风坡>坡顶>背风坡;而草本植物密度和盖度可能还受结皮等其它环境因素的影响,由大到小的变化趋势为:背风坡>坡顶>迎风坡>丘间低地。     

人工固沙植被区土壤水分动态及空间分布

土壤水分是干旱区固沙植被生长发育最主要的限制因子,了解其动态变化特征对沙区人工植被建设具有重要意义。本研究利用EnviroSMART土壤水分监测系统,于2009-2013年对宁夏沙坡头地区人工固沙植被区的土壤水分动态进行连续监测。结果表明:(1)降水对土壤水分状况及动态变化有较大的影响。土壤水分总体处于过度消耗状态,在非生长季,土壤水分没有明显的回升现象。(2)生长季初期(4-5月)为土壤水分弱消耗阶段;生长旺盛期(6-8月)为土壤水分快速消耗阶段,水分变化波动较剧烈,空间异质性最强;生长季末期(9-10月)的土壤水分处于相对稳定状态。(3)土壤水分随深度增加呈“S”形变化趋势,浅层的土壤含水量明显高于其他深度,200 cm深度土壤含水量较低且年际间变化不大(1.53%~2.10%)。湿润年份土壤水分剧烈变化的土层深度为0～100 cm,而干旱年份为0～20 cm。(4)相对于干旱年份,湿润年份的土壤含水量不但较高,而且水分变化波动较为剧烈。当土壤水分较低时,其变异性会随着土壤水分含量的增加而增加。(5)试验区灌木盖度在5年间呈下降趋势,一年生草本受降水量影响年际变化较大。受降水时空分布影响的土壤水分是沙坡头人工植被演替的重要驱动力。     

腾格里沙漠不同类型沙丘土壤水分含量与地形-植被因子关系研究

土壤水分是沙区主要的生态限制因子,其分布受气候、地形和植被等众多因素的影响。以腾格里沙漠沙坡头地区3种类型的沙丘（固定沙丘、半固定沙丘和流动沙丘）为研究对象,利用方差分析和冗余分析（RDA）等方法对沙丘不同部位和不同深度土壤水分的分布特征及其与地形-植被因子之间的关系进行了综合分析。结果表明：（1） 不同类型沙丘上0~300 cm的土壤水分随着深度的增加而增加,表层土壤水分的波动程度大于中层和深层。（2） 固定沙丘不同部位及不同深度的土壤水分之间没有明显的差异,半固定沙丘和流动沙丘迎风坡与丘底的土壤水分高于背风坡和丘顶。（3） 固定沙丘上的土壤水分受地形-植被因子的影响较半固定沙丘和流动沙丘小,影响固定沙丘土壤水分的主要因子有坡向、高差和灌木多度。（4） 地形-植被因子与研究区绝大多数半固定沙丘和流动沙丘的土壤水分均有负相关关系。研究揭示了腾格里沙漠土壤水分的分布规律及其与地形-植被因子的关系,对制定相应的防风固沙措施以及建立科学合理的植物固沙模式有积极的指导作用。     

中国亚热带地区造林对土壤碳周转的影响

Afforestation in China’s subtropics plays an important role in sequestering CO2 from the atmosphere and in storage of soil carbon (C). Compared with natural forests,plantation forests have lower soil organic carbon (SOC) content and great potential to store more C. To better evaluate the effects of afforestation on soil C turnover,we investigated SOC and its stable C isotope (δ13C) composition in three planted forests at Qianyanzhou Ecological Experimental Station in southern China. Litter and soil samples were collected and analyzed for total organic C,δ13C and total nitrogen. Similarly to the vertical distribution of SOC in natural forests,SOC concentrations decrease exponentially with depth. The land cover type (grassland) before plantation had a significant influence on the vertical distribution of SOC. The SOC ?13C composition of the upper soil layer of two plantation forests has been mainly affected by the grass biomass 13C composition. Soil profiles with a change in photosynthetic pathway had a more complex 13C isotope composition distribution. During the 20 years after plantation establishment,the soil organic matter sources influenced both the δ13C distribution with depth,and C replacement. The upper soil layer SOC turnover in masson pine (a mean 34% of replacement in the 10 cm after 20 years) was more than twice as fast as that of slash pine (16% of replacement) under subtropical conditions. The results demonstrate that masson pine and slash pine plantations cannot rapidly sequester SOC into long-term storage pools in subtropical China.     

太白山北坡成土因素及不同土壤垂直带谱的比较

在系统地考察太白山北坡地质、地貌、气候和植被等成土因素的基础上,总结和回顾了用土壤发生分类和土壤系统分类两种分类体系划定的太白山北坡土壤垂直带谱。根据最新的土壤系统分类,太白山北坡的土壤垂直带谱是:暗瘠寒冻雏形土(3500～3767m)———暗沃寒冻雏形土(3300～3500m)———酸性湿润雏形土(2500～3300m)———简育湿润淋溶土(1400～2500m)———简育干润淋溶土(<1400m)。分析、比较表明:两种体系有密切联系,均以成土因素为依据,建立在土壤发生学理论之上;与土壤地理发生分类相比,土壤系统分类用可以度量的诊断层和诊断特性进行土壤分类,不仅能够反映出山地土壤成土因素的垂直变化趋势,而且避免了太白山北坡土壤类型鉴定上的许多歧义。     

Soil nutrients in relation to land use and landscape position in the semi-arid small catchment on the loess plateau in China

Characterizing spatial variability of soil nutrients in relation to site properties, including climate, land use, landscape position and other variables, is important for understanding how ecosystems work and assessing the effects of future land use change on soil nutrients. In order to assess the effects of land use and landscape position on soil nutrients consisting of soil organic matter (SOM), total N (TN), total P (TP), available N (AN) and available P (AP), soil samples were collected in August and October 1998 and July 1999 from three transects in a small catchment on the loess plateau, China. The three transects consisted of typical land use structure from the top to foot of hillslope in the study area: fallow land – cropland – woodland – orchard (T1), fallow land – shrub land – fallow land – cropland – woodland – orchard (T2) and intercropping land – woodland (T3). Significant differences among land uses were found for SOM, TN and AN. Woodland, shrub land and grassland had the higher levels for them compared to fallow land and cropland. Use of soil deterioration index showed that soils deteriorated moderately (−17·05%) under orchard and seriously (ranging from −29·91% to −20·32%) under fallow land, cropland and intercropping land, while soils had no deterioration (−0·74%) under shrubland and (−0·69%) grassland. This study indicated that the cultivated hilly lands must be abandoned before a critical minimum SOM of 0·492%. Soil nutrient responses to landscape positions were variable depending on transect and the location of land use types. The highest levels in SOM, TN and AN were observed at middle slope position on T1, while they occurred at foot slope position on T3. However, an increasing trend from upper slope to foot slope for five nutrients were found on T2.     

黄土高原西部人工灌木生长季土壤水分变异特征

以兰州干旱地区生态植被恢复技术研究与示范基地灌木品种研究小区为试验点,研究了黄土高原西部丘陵区坡面不同灌木下0～200 cm土层土壤水分特征,采用Brown-Forsythe检验方法和变异系数比较不同灌木覆盖下土壤水分含量的差异。结果表明:土壤水分的变化受到坡位、坡向、灌木种类的影响较大。相同土层的土壤水分变异系数基本为阴坡>半阴坡>半阳坡>阳坡。坡上部的土壤水分变化较大,坡中部和坡下部相对较稳定。多数灌木的土壤水分变异系数随着土壤深度的增加而减小,变异系数较大值相对集中在20～80 cm土层。从土壤水分的亏缺量、植物水分亏缺度来看,在植被恢复的过程中,选择荒漠锦鸡儿(Caragana roborovskyi)、甘蒙锦鸡儿(Caragana opulens)、枸杞(Lycium chinense)等耗水量相对较低的植被更加合理。     

黄土丘陵区坡面尺度上不同植被格局下植物群落和土壤性质研究

通过对黄土丘陵沟壑区陕西延安羊圈沟小流域坡面上退耕还林还草后形成的林地(单一种植刺槐人工林)、草地(单一的撂荒草地)、草地-林地-草地(上坡位和下坡位撂荒草地,中坡位种植刺槐人工林)及林地-草地-林地(上坡位和下坡位种植刺槐人工林,中坡位为撂荒草地)四种不同的植被格局下植物物种多样性及土壤理化性质变化的研究,旨在揭示植被恢复过程中,坡面上植被不同的空间配置模式对植物物种的组成及土壤环境变化的影响.研究发现,4种植被格局下植物物种的多样性以单一的撂荒草地坡面最高,人工林的种植一定程度上影响了林下植物物种多样性的恢复,但整个灌木和草本的群落结构4种植被格局之间均未达到极不相似水平.土壤有机碳及总氮含量均以坡面上草地-林地-草地的空间配置格局最高且有机碳存在显著差异,而撂荒草地则在土壤水分的保持及改善土壤pH值上优于其他3种植被格局.     

金沙江干热河谷不同植被坡面土壤水分时空分布特征

于2016年7~12月和2017年4月的旱、雨季期间,以金沙江干热河谷苴那小流域内的银合欢（Leucaena Benth）林地、车桑子（Dodonaea angustifolia）灌丛地和扭黄茅（Heteropogon cantortus）草地为研究对象,通过网格法和土钻法采集并测定了（0~100 cm）土层的土壤含水量,应用经典统计法和地统计学方法分析该区域不同林草植被下坡面土壤水分的动态变化特征。结果表明：（1）研究区土壤含水量总体较低,雨季显著大于旱季,旱、雨季均表现为灌丛地>草地>林地,呈中度至强度变异（0.07~0.28之间）。（2）不同林草植被下旱、雨季土壤水分具有相似的空间自相关性,自相关系数均由正向负转变,但由正向负转变的滞后距离有所不同,且雨季大于旱季,呈中等或强等空间自相关性。（3）不同林草植被下的土壤水分空间结构不同,林地、灌丛地和草地旱雨季最佳拟合模型均为球状模型;相同林草植被下各土层旱、雨季土壤水分的空间分布特征相似,但旱季的分布格局差异更显著,不同林草植被下深层土壤水分分布比表层土壤水分的分布更为复杂,土壤水分呈明显的斑块或条带状分布,含水量高值区和低值区位置不固定。总之不同林草植被类型会改变局部地段土壤水分空间分布,降雨会加强这种差异的趋势,但土壤水分仍具一定空间连续性。     

Impact of Land Cover on Temperature and Moisture Sensitivity of Soil Organic Matter Mineralization in Subtropical Southeastern China

Understanding the temperature and moisture sensitivity of soil organic matter (SOM) mineralization variations with changes in land cover is critical for assessing soil carbon (C) storage under global change scenarios. We determined the differences in the amount of SOM mineralization and the temperature and moisture sensitivity of soils collected from six land-cover types, including an orchard, a cropland, and four forests, in subtropical southeastern China. The responses of SOM mineralization to temperature (5, 10, 15, 20, and 25°C) and moisture (30%, 60%, and 90% of water-holding capacity [WHC]) were investigated by placing soil samples in incubators. Soil C mineralization rate and cumulative C mineralization were higher in orchard and cropland soils than in other forest soils. With increasing temperature, soil C mineralization rates and cumulative C mineralization increased with the rise of WHC. The temperature sensitivity of soil C mineralization was not affected by land-cover type and incubation moisture. All soil temperature treatments showed a similar response to moisture. Cropland soil was more responsive to soil moisture than other soils. Our findings indicate that cropland and orchard soils have a higher ability to emit CO₂ than forest soils in subtropical southeastern China.     

云南省中部3种森林土壤含水率、容重和细根重及其垂直分布

根据27个土壤剖面的405个土壤样品,研究云南中部地区华山松林、旱冬瓜林、云南松林的土壤含水率、容重和细根重及其垂直分布特征。结果表明：3种森林100em深土壤的平均含水率分别是（28．79±11．98）％、（24．66±9．89）％、（14．11±5．84）％,差异极显著;平均容重分别是（1．14±0．20）g／cm3、（1．26±0．18）g/cm3、（1．42±0．12）g／cm3,差异极显著;平均细根重分别为（0．1956±0．2144）g／100cm3、（0．0706±0．1066）g／100cm3、（0．1381±0．2989）g／100cm3,在0．05水平上差异显著。华山松林林下土壤的物理性质最好,旱冬瓜林次之,云南松林最差。3种森林里,随着土壤深度增加,土壤含水率增加,土壤容重和土壤细根重减少。华山松林与云南松林平均容重与平均细根重均显著负相关,旱冬瓜林平均含水率与平均容重显著负相关。华山松林下土壤细根量最大,0～20cm层根系占根系总重量的83％。     

Influencing factors and partitioning of respiration in a Leymus chinensis steppe in Xilin River Basin, Inner Mongolia, China

Based on the static opaque chamber method, the respiration rates of soil microbial respiration, soil respiration, and ecosystem respiration were measured through continuous in-situ experiments during rapid growth season in semiarid Leymus chinensis steppe in the Xilin River Basin of Inner Mongolia, China. Soil temperature and moisture were the main factor affecting respiration rates. Soil temperature can explain most CO2 efflux variations (R2=0.376–0.655) excluding data of low soil water conditions. Soil moisture can also effectively explain most of the variations of soil and ecosystem respiration (R2=0.314–0.583), but it can not explain much of the variation of microbial respiration (R2=0.063). Low soil water content (≤5%) inhibited CO2 efflux though the soil temperature was high. Rewetting the soil after a long drought resulted in substantial increases in CO2 flux at high temperature. Bivariable models based on soil temperature at 5 cm depth and soil moisture at 0–10 cm depth can explain about 70% of the variations of CO2 effluxes. The contribution of soil respiration to ecosystem respiration averaged 59.4%, ranging from 47.3% to 72.4%; the contribution of root respiration to soil respiration averaged 20.5%, ranging from 11.7% to 51.7%. The contribution of soil to ecosystem respiration was a little overestimated and root to soil respiration little underestimated because of the increased soil water content that occurred as a result of plant removal.