河北平原表层土壤有机碳和无机碳的分布及碳储量估算

利用多目标区域土壤地球化学调查数据,对河北平原表层土壤中有机碳和无机碳的空间分布进行了研究,计算了无机碳储量并结合有机碳储量的研究结果得到河北平原表层土壤的总碳储量。结果表明:河北平原表层土壤碳在空间分布表现出与土壤类型、地貌,尤其是古河道、湖泊的密切关系,并受到人类活动的影响。表层土壤碳总储量为320.56Mt,碳密度为4.33kg/m2。其中无机碳储量达到145.74Mt,碳密度为1.97kg/m2,以潮土和褐土的碳储量最大,以草甸盐土和潮土的无机碳密度最高。潮土区无机碳主要是发生碳酸盐,而褐土区无机碳主要是岩生无机碳。     

黄土高原表土有机碳和无机碳的空间分布及碳储量

选取位于干旱-半干旱区的黄土高原陕西境内表土样品为研究对象,对其有机碳(Soil organiccarbon,简称SOC)和无机碳的空间分布及陕西省碳储量进行初步研究。结果表明:黄土高原陕西境内有机碳和无机碳的平均值分别为5.41g/kg和17.04g/kg,有机碳的空间分布是自北向南呈现出增加的趋势,这也与所处环境相符,无机碳的空间分布特征沿着纬度呈现自北向南逐渐增加的趋势,特别是北纬36o以北;将每一区域内CaCO3含量的平均值与相对区域的降雨量和温度分别进行一元线性拟合,其拟合系数分别为R=0.338和0.182,碳酸盐含量与降雨量和温度的相关性并不显著。陕西省表土有机碳和无机碳储量分别为0.272Pg和0.856Pg,无机碳储量远大于有机碳储量,这与其所处干旱环境有关。     

甘肃省土壤有机碳储量及空间分布

根据甘肃省第二次土壤普查所得的37个土壤类型、281个典型土壤剖面的理化性质和土壤各类型分布面积,以及1:300万甘肃省纸质土壤图,利用土壤类型法估算了甘肃省土壤有机碳的储量,并借助M ap-G IS软件分析了土壤碳密度的空间分布规律。结果表明:甘肃省土壤有机碳含量约为39.87×108t,占全国储量的4.47%;其中有机碳储量占前5位的土壤类型为亚高山草甸土、高山草甸土、褐土、灰褐土、亚高山草原土,五者之和占全省总储量的39.67%;另外,甘肃省土壤有机碳密度较高,土壤平均碳密度为17.62kg.m-2,高于全国平均水平9.60kg.m-2;泥炭土的有机碳密度最大,高达208.53kg.m-2;粗骨土的碳密度含量最低,为0.73kg.m-2,全省的土壤有机碳密度主要在0~15kg.m-2范围内变动。     

新疆博斯腾湖湖周水体碳和盐离子的空间分布

以博斯腾湖为研究对象,在大湖区周边及开都河取水样和表层土样,分析湖周水体中颗粒有机碳（POC）和溶解有机碳（DOC）在秋季的空间分布特征及其与周围土壤碳及水体盐离子的关系。结果表明：湖周水体中POC浓度的空间变化较大（0.1~1.2 mg•L^-1）,而DOC浓度的变化较小（8.5~12.3 mg•L^-1）。两者在出湖口和入湖口处的浓度均较低,与开都河的浓度相近。与早期相比,博斯腾湖水中无机碳存在由CO₃ ^2-向HCO₃^-转化的现象。回归分析显示,水体中各形态碳与土壤碳之间没有显著的线性关系,表明水体中碳的含量受周围土壤的影响不大。     

塔里木盆地南缘典型绿洲不同土壤类型土壤有机碳含量及矿化特征

以塔里木盆地南缘典型绿洲于田绿洲为靶区,通过野外取样和实验分析,研究干旱区绿洲灌漠土、棕漠土、盐土和风沙土土壤有机碳含量及矿化特征,并探究有机碳矿化能力与土壤理化性质的关系。结果表明:于田绿洲不同类型土壤总有机碳含量依次为灌漠土>棕漠土>盐土>风沙土,灌漠土和棕漠土有机碳含量随土壤剖面深度增加而减少;不同类型土壤有机碳矿化累积量具有显著差异,其中灌漠土有机碳总矿化量最高,达到0.245g·kg~(-1),风沙土最低,仅有0.145g·kg~(-1);各类型土壤有机碳矿化累积量和矿化率均随土壤剖面深度增加而减少;不同类型土壤有机碳矿化累积量与有机碳含量、全氮、速效磷、速效钾呈极显著或显著正相关,而与pH值呈显著负相关。     

黑河上游冰沟流域4种土壤有机碳分布特征与土壤特性的关系

为了探讨黑河上游冰沟流域不同土壤有机碳分布特征与土壤特性的关系,为黑河上游冰沟流域水源涵养研究提供科学依据,采用野外采样,室内分析方法,研究了4种土壤有机碳分布特征及其与土壤特性的关系。结果表明：4种土壤有机碳含量和密度在整个土壤剖面上均表现为：森林灰褐土＞高山灌丛草甸土＞高山草甸土＞山地栗钙土,且垂直分布均随土壤深度增加而减少,说明黑河上游冰沟流域的森林灰褐土比其它土壤更有利于土壤有机碳储存和积累。森林灰褐土0～10 cm土壤有机碳密度为4．54 kg·m-2,略高于我国森林土壤0～10 cm土壤平均碳密度（4．24 kg ·m-2）,说明黑河上游冰沟流域的森林灰褐土区雨量充沛,林下植被丰富,凋落物现存量充足。4种土壤0～10 cm土层有机碳含量是整个土壤剖面土壤有机碳含量的30．69％～37．99％,有机碳密度是整个土壤剖面有机碳密度的29．31％～36．77％,说明黑河上游冰沟流域土壤有机碳含量和有机碳密度在表层具有很强的表聚性,不合理的人为活动引发的水土流失极易造成土壤有机碳储量的减少,应增加黑河上游冰沟流域植被覆盖度,保护生态环境,减少水土流失。4种土壤有机碳、全氮、CEC、田间持水量、团聚体在整个土壤剖面上均随土层深度增加而降低,而土壤容重、pH值在整个土壤剖面上均随土层深度增加而增大。经回归统计分析,4种土壤有机碳含量与土壤田间持水量、团聚体、全氮、CEC之间呈显著的正相关关系,与土壤容重、pH之间呈显著的负相关关系。这种变化规律与多数学者研究结果基本一致。     

山西太岳山不同林分土壤有机碳储量研究

基于山西太岳山系灵空山景区侧柏林、油松林、辽东栎林、辽东栎和油松混交林4种林分调查,通过密集采样和样品分析研究不同林分土壤不同层次(0-10cm、10-20cm、20-30cm、30-50cm、50-100cm)有机碳含量、有机碳密度和有机碳储量及分布特征。结果如下:山西太岳山森林平均1m土层土壤的有机碳储量一般不超过30g·kg-1,调查的四种林分在16.2g·kg-1到29.6g·kg-1;所调查的四种林分的土壤有机碳储量、碳密度随着土层深度递减,其中油松林、侧柏林、辽东栎林30cm以上土壤中有机碳储量占到100cm土层中有机碳储量的85%以上,表层土壤碳储量贡献大;阔叶林碳储量高于针叶林,混交林碳储量高于纯林,辽东栎油松针阔混交林土壤有机碳含量是油松林土壤碳含量的2.4倍,辽东栎林土壤碳储量大约分别是侧柏林、油松林的1.4和1.9倍。因此为增加森林土壤固碳,建议使用混交林并减少人类活动对森林表土层的干扰和破坏。     

土地利用方式对东祁连山土壤表层有机碳的影响

在祁连山东段高寒地区,选取天然草地、退耕自然恢复地、坡耕地和人工草地4种土地利用方式,研究了土地利用方式对土壤表层有机碳含量和有机碳密度的影响.结果表明:在4种土地利用方式中天然草地土壤表层有机碳含量最高,坡耕地和退耕自然恢复地土壤表层有机碳含量较低;土壤表层有机碳密度整体上随着土层加深而逐渐降低,在0～30cm土层土...     

不同类型土壤的有机碳密度特征

赤峰市敖汉旗地处农牧交错带,土壤类型丰富,且人工造林面积较大,各类型土壤不同人工林的碳收支情况有很大差异。本试验在敖汉旗6种类型土壤上各选取3块样地,在所有样方内按"S"型选取5个采样点,以此来研究敖汉旗不同类型土壤有机碳密度分布特征。结果表明:6种类型土壤的有机碳密度为褐土最大,风沙土最小。由于土壤自身性质与坡度和坡位的相互影响,褐土、栗钙土、棕壤的有机碳密度呈现不同的变化趋势。褐土、栗钙土、棕壤有机碳密度均为北坡最大,南坡最小。主成分分析结果显示坡位、坡面和坡度3因素中坡面不作为主成分保留,经回归分析,褐土、栗钙土、棕壤的有机碳密度在P0.05显著水平下的回归方程分别为:Y=25.662 40+1.722 06X_1-0.061 54X_2(R~2=0.853 5)(褐土);Y=24.890 95-3.437 45X_1-0.002 12X_2(R~2=0.899 5)(栗钙土);Y=19.112 05-0.090 72_X1-0.018 44X_2(R~2=0.794 4)(棕壤)。     

贺兰山主要森林类型土壤和根系有机碳研究

土壤有机碳是陆地碳库的重要组成部分,其形成常和植被、气候等环境要素相关。为了解贺兰山地区土壤有机碳状况,2011年对贺兰山东麓青海云杉(Picea crassfolia)、油松(Pinus tabulaeformis)和灰榆(Ulmus glaucescens)林下土壤和根系取样,测定了各自的有机碳含量。结果表明:青海云杉、油松和灰榆林林下土壤平均有机碳含量分别为34.12g/kg、17.83g/kg和15.32g/kg,林下根系有机碳密度分别为869.12g/m2、532.17g/m2和242.68g/m2,林下土体(土壤和根系)有机碳密度分别为17.58kg/m2、9.55kg/m2和4.00kg/m2;林下根系有机碳占林下土体有机碳的比重为4.94%～6.0%。贺兰山青海云杉林下土壤碳储量高于全国森林土壤碳储量平均水平,油松林下碳储量略低于全国森林土壤碳储量平均水平,灰榆林碳储量仅为全国森林土壤碳储量平均水平的36.7%。青海云杉和油松林利于土壤有机碳累积,其林下土壤是贺兰山地区重要的有机碳库。     

土壤侵蚀对土壤理化性质及土壤微生物的影响

通过对黄土丘陵沟壑区侵蚀环境下4种典型坡面上坡顶、坡肩、坡背、坡脚和坡趾5个不同地形部位¹³⁷Cs的含量、土壤理化性质及土壤微生物指标的测定和分析。结果表明:用来表征土壤侵蚀程度的¹³⁷Cs含量与土壤有机碳、全氮、土壤容重、电导率、土壤微生物功能多样性及细菌菌群之间均存在显著的回归关系,土壤有机碳、全氮及土壤容重随着¹³⁷Cs含量的增加呈增加趋势,土壤电导率、土壤微生物功能多样性呈下降趋势,而土壤细菌呈先下降后增加的趋势。土壤侵蚀过程能够直接影响土壤养分在坡面上的空间分布及土壤结构,通过影响土壤性质,改变土壤微生物群落的生长环境和营养物质的含量,从而影响土壤微生物的生长。     

新疆不同植被类型土壤有机碳特征

准确评估不同植被类型的土壤有机碳库,对揭示土壤有机碳在陆地生态系统碳循环中的作用具有重要意义。通过分析新疆地区10种植被类型的土壤有机碳密度(SOCD)的分布特征,估算了该地区的土壤有机碳储量。结果表明:在10个植被类型的0~100 cm土壤剖面中,SOCD垂直分布特征明显,呈逐渐降低趋势。新疆SOCD以针叶林最大,其值为63.86 kg·m~(-2),其他植被类型依次为:草甸、阔叶林、沼泽、草原、灌丛、高山植被、栽培植被、荒漠和无植被类型。土壤有机碳储量最大值分布在草甸中,为4.89 Pg,其他植被类型依次为:荒漠、草原、高山植被、无植被(裸地)、针叶林、栽培植被、阔叶林、灌丛、沼泽。在0~100 cm的土壤层,新疆地区土壤有机碳储量为16.4Pg。     

天山北麓不同土地覆被下土壤有机碳垂直分布特征

利用全国第二次土壤普查数据,对天山北麓不同土地覆被类型下的土壤有机碳分布特征开展研究。结果表明：在0～100 cm土层天山北麓不同土地覆被类型的土壤碳密度差异显著,其均值处于3.65～35.73 kg·m^-2。不同土地覆被类型的土壤碳密度垂直分布差异明显,其中耕地表层(0～20 cm)土壤碳密度占其总量的32.2%,其相邻土层的土壤碳密度占其总量比例的差值较小,最大差值仅为8.1%;高山亚高山草甸、森林和隐域植被表层(0～20 cm)土壤碳密度占其总量的40%以上;荒漠植被、裸地和稀疏植被表层(0~20 cm)土壤碳密度占其总量的比例低于37%,其中裸地与稀疏植被最低,仅为25.4%,其相邻土层土壤碳密度占其总量比例的最大差值低于4.0%。     

黄土高原藓结皮覆盖土壤导水性能和水流特征

生物结皮具有特殊的水文物理性质,为探究其对土壤水分渗透性和水流特征的影响,以黄土高原风沙土和黄绵土上3种典型地表覆盖类型(裸地、藓结皮、藓结皮-草本植物混合)为对象,采用环刀法和染色示踪法对其导水性质与水流特征进行探究。结果表明:藓结皮对2种土壤类型0~5 cm土层土壤理化性质影响较大,与裸地相比土壤容重降低了9.85%~10.00%,土壤黏粒含量增加了1.01~1.29倍,表层有机质含量提高了2.73~3.02倍;藓结皮使0~5 cm土层土壤饱和导水率降低了61.32%~88.89%,而在5~10 cm土层饱和导水率则有明显上升。另外,由于草本植物的影响,藓结皮-草本植物0~5 cm土层与藓结皮土壤相比土壤饱和导水率提高了1.32~6.43倍;黄绵土藓结皮与藓结皮-草本植物的染色面积比均高于裸地,且水分下渗深度增加了10 cm,而风沙土藓结皮与风沙土裸地的染色面积比差异不明显。综上所述,藓结皮和藓结皮-草本植物的存在改变了表层土壤水分渗透性以及水流运动特征和水分下渗深度,影响着黄土高原土壤水分保持和生态恢复。     

Changes in soil properties and erodibility of gully heads induced by vegetation restoration on the Loess Plateau,China

Soil erosion on the Loess Plateau of China is effectively controlled due to the implementation of several ecological restoration projects that improve soil properties and reduce soil erodibility. However, few studies have examined the effects of vegetation restoration on soil properties and erodibility of gully head in the gully regions of the Loess Plateau. The objectives of this study were to quantify the effects of vegetation restoration on soil properties and erodibility in this region. Specifically, a control site in a slope cropland and 9 sites in 3 restored land-use types(5 sites in grassland, 3 in woodland and 1 in shrubland) in the Nanxiaohegou watershed of a typical gully region on the Loess Plateau were selected, and soil and root samples were collected to assess soil properties and root characteristics. Soil erodibility factor was calculated by the Erosion Productivity Impact Calculator method. Our results revealed that vegetation restoration increased soil sand content, soil saturated hydraulic conductivity, organic matter content and mean weight diameter of water-stable aggregate but decreased soil silt and clay contents and soil disintegration rate. A significant difference in soil erodibility was observed among different vegetation restoration patterns or land-use types. Compared with cropland, soil erodibility decreased in the restored lands by 3.99% to 21.43%. The restoration patterns of Cleistogenes caespitosa K. and Artemisia sacrorum L. in the grassland showed the lowest soil erodibility and can be considered as the optimal vegetation restoration pattern for improving soil anti-erodibility of the gully heads. Additionally, the negative linear change in soil erodibility for grassland with restoration time was faster than those of woodland and shrubland. Soil erodibility was significantly correlated with soil particle size distribution, soil disintegration rate, soil saturated hydraulic conductivity, water-stable aggregate stability, organic matter content and root characteristics(including root average diameter, root length density, root surface density and root biomass density), but it showed no association with soil bulk density and soil total porosity. These findings indicate that although vegetation destruction is a short-term process, returning the soil erodibility of cropland to the level of grassland, woodland and shrubland is a long-term process(8–50 years).     

Effects of land-use types on the vertical distribution of fractions of oxidizable organic carbon on the Loess Plateau,China

The oxidizability of soil organic carbon(SOC_) influences soil quality and carbon sequestration. Four fractions of oxidizable organic carbon(very labile(C_1), labile(C_2), less labile(C_3) and non-labile(C_4)) reflect the status and composition of SOC_ and have implications for the change and retention of SOC_. Studies of the fractions of oxidizable organic carbon(OC_) have been limited to shallow soil depths and agroecosystems. How these fractions respond at deep soil depths and in other types of land-use is not clear. In this study, we evaluated the vertical distributions of the fractions of oxidizable organic carbon to a soil depth of 5.0 m in 10 land-use types in the Zhifanggou Watershed on the Loess Plateau, C_hina. Along the soil profile, C_1 contents were highly variable in the natural grassland and shrubland I(C_aragana microphylla), C_2 and C_4 contents were highly variable in the natural grassland and two terraced croplands, respectively, and C_3 contents varied little. Among the land-use types, natural grassland had the highest C__1 and C_2 contents in the 0–0.4 m layers, followed by shrubland I in the 0–0.1 m layer. Natural grassland had the highest C_4 contents in the 1.0–4.5 m layers. Natural grassland and shrubland I thus contributed to improve the oxidizability of SOC_ in shallow soil, and the deep soil of natural grassland has a large potential to sequester SOC_ on the Loess Plateau.     

红砂植被盖度对土壤不同形态碳、氮及细菌多样性的影响

以自然恢复的红砂群落为研究对象,探讨黄土高原红砂植被不同盖度对土壤不同形态碳、氮及细菌多样性的影响,为该地区的人工生态恢复措施提供理论支撑.在兰州市南北两山植被恢复技术研究与示范基地,按照5级盖度分类法设置红砂植被盖度梯度,重点对土壤养分碳氮、微生物量碳氮和细菌多样性开展研究.结果表明:随着植被恢复,土壤有机碳 (SOC)和全氮(TN)、土壤微生物碳 (MBC)和微生物氮(MBN)逐渐提高,并且增加比较快 ,但是当总盖度达到48.73%之后,增加比较缓慢,而且增加的差异不显著.相同的植被盖度对土壤有机碳、全氮和土壤微生物碳、氮的影响趋于一致.土壤细菌多样性随植被盖度有所增加,在植被盖度达到48.73%后多样性维持在彼此接近的水平,尽管微生物多样性群落结构有差异 .在植被稀疏、物种多样性较低的干旱坡地,红砂植被盖度增加明显改善了土壤生态功能, 但是片面追求植被盖度的增加,对土壤特性改善有限.     

绿肥填闲种植对旱作冬小麦农田土壤团聚体有机碳含量的影响

依托黄土塬区4 a绿肥填闲种植田间定位试验,开展不同填闲作物对土壤团聚体组成及各组分有机碳在团聚体中分布影响的研究,为阐明填闲种植措施下土壤有机碳库的物理保护机制提供依据。试验设置4个处理,即冬小麦夏闲期种植长武怀豆(SB)、苏丹草(SG)、怀豆/苏丹草混播(Mix)和裸地休闲(CK)。利用干筛法将全土筛分为>5 mm、2～5 mm、0.25～2 mm和<0.25 mm等4个粒级,分别测定土壤和各粒级团聚体中有机碳和颗粒有机碳含量,进而计算团聚体平均重量直径及有机碳贡献率。结果表明：绿肥种植对土壤团聚体分布有显著影响,各绿肥处理均有利于0～10 cm土层土壤团聚体的形成,但对亚表层土壤团聚结构影响较小。与CK相比,在0～40 cm各土层,SB、SG和Mix处理均显著提高土壤有机碳含量、颗粒有机碳含量及团聚体平均重量直径,提高幅度分别为7.9%、8.0%和7.9%,其中SB更有利于表层土壤有机碳的固存,且土壤有机碳和颗粒有机碳含量之间呈显著正相关关系,这两者与团聚体平均重量直径之间均呈显著负相关关系。不同处理下土壤团聚体各有机碳组分含量存在差异,与CK相比,SB和Mix均显著...     

Effects of different tillage and straw retention practices on soil aggregates and carbon and nitrogen sequestration in soils of the northwestern China

Soil tillage and straw retention in dryland areas may affect the soil aggregates and the distribution of total organic carbon. The aims of this study were to establish how different tillage and straw retention practices affect the soil aggregates and soil organic carbon (SOC) and total nitrogen (TN) contents in the aggregate fractions based on a long-term (approximately 15 years) field experimentin the semi-arid western Loess Plateau, northwestern China. The experiment included four soil treatments, i.e., conventional tillage with straw removed (T), conventional tillage with straw incorporated (TS), no tillage with straw removed (NT) and no tillage with straw retention (NTS), which were arranged in a complete randomized block design. The wet-sieving method was used to separate four size fractions of aggregates, namely, large macroaggregates (LA, >2000 μm), small macroaggregates (SA, 250-2000 μm), microaggregates (MA, 53-250 μm), and silt and clay (SC, <53 μm). Compared to the conventional tillage practices (including T and TS treatments), the percentages of the macroaggregate fractions (LA and SA) under the conservation tillage practices (including NT and NTS treatments) were increased by 41.2%-56.6%, with the NTS treatment having the greatest effect. For soil layers of 0-5, 5-10 and 10-30 cm, values of the mean weight diameter (MWD) under the TS and NTS treatments were 10.68%, 13.83% and 17.65%, respectively. They were 18.45%, 19.15% and 14.12% higher than those under the T treatment, respectively. The maximum contents of the aggregate-associated SOC and TN were detected in the SA fraction, with the greatest effect being observed for the NTS treatment. The SOC and TN contents were significantly higher under the NTS and TS treatments than under the T treatment. Also, the increases in SOC and TN levels were much higher in the straw-retention plots than in the straw-removed plots. The macroaggregates (including LA and SA fractions) were the major pools for SOC and TN, regardless of tillage practices, storing 3.25-6.81 g C/kg soil and 0.34-0.62 g N/kg soil. Based on the above results, we recommend the NTS treatment as the best option to boost soil aggregates and to reinforce carbon and nitrogen sequestration in soils in the semi-arid western Loess Plateau of northwestern China.     

Spatial distribution of water-active soil layer along the south-north transect in the Loess Plateau of China

Soil water is an important compositionof water recyclein the soil-plant-atmosphere continuum. However, intense water exchange between soil-plant and soil-atmosphereinterfacesonly occurs in a certain layer of the soil profile. For deep insight into wateractive layer (WAL, defined as the soil layer with a coefficient of variation in soil water content>10% in a given time domain)inthe Loess Plateau of China,we measuredsoil water content (SWC)in the 0.0-5.0 m soil profile from 86 sampling sites along an approximately 860-kmlong south-north transect during the period 2013-2016. Moreover, a datasetcontainedfourclimatic factors (mean annual precipitation, mean annual evaporation, annual mean temperature and mean annual dryness index) andfivelocalfactors (altitude, slope gradient, land use, clay content and soil organic carbon)ofeachsampling sitewasobtained.Inthisstudy, three WAL indices (WAL-T (the thickness of WAL), WAL-CV (the mean coefficient of variation in SWC within WAL) and WAL-SWC (themean SWC within WAL)) were used to evaluate the characteristics of WAL. The results showed that with increasing latitude, WAL-T and WAL-CV increased firstly and then decreased. WAL-SWC showed an oppositedistribution pattern along the south-north transect compared with WAL-T and WAL-CV. Average WAL-T of the transect was 2.0 m, suggesting intense soil water exchange in the0.0-2.0 m soil layer in the study area. Soil water exchange was deeper and more intense in the middle region than in the southern and northern regions, with the values of WAL-CV and WAL-Tbeing27.3% and 4.3 m in the middle region, respectively. Both climatic (10.1%) and local (4.9%) factors influenced the indices of WAL, with climatic factors having a more dominant effect.Compared with multiple linear regressions, pedotransfer functions (PTFs) from artificial neural network can better estimate theWAL indices. PTFs developed byartificial neural network respectivelyexplained 86%, 81% and 64% of the total variations in WAL-T, WAL-SWC andWAL-CV. Knowledge of WAL iscrucial for understanding the regional water budgetandevaluatingthe stable soil water reserve, regional water characteristics and eco-hydrological processes in the Loess Plateau of China.