Soil hydrology and CO2 release of peat soils     

Gerd Wessolek  Kai Schwrzel  Manfred Renger  Robert Sauerbrey  Christian Siewert 《植物养料与土壤学杂志》2002,165(4):494-500

A simple model to predict soil water components and the CO₂ release for peat soils is presented. It can be used to determine plant water uptake and the CO₂ release as a result of peat mineralization for different types of peat soils, various climate conditions, and groundwater levels. The model considers the thickness of the root zone, its hydraulic characteristics (pF, Ku), the groundwater depth and a soil‐specific function to predict the CO₂ release as a result of peat mineralization. The latter is a mathematical function considering soil temperature and soil matric potential. It is based on measurements from soil cores at varying temperatures and soil water contents using a respiricond equipment. Data was analyzed using nonlinear multiple regression analysis. As a result, CO₂ release equations were gained and incorporated into a soil water simulation model. Groundwater lysimeter measurements were used for model calibration of soil water components, CO₂ release was adapted according long‐term lysimeter data of Mundel (1976). Peat soils have a negative water balance for groundwater depth conditions up to 80—100 cm below surface. Results demonstrate the necessity of a high soil water content i.e. shallow groundwater to avoid peat mineralization and soil degradation. CO₂ losses increase with the thickness of the rooted soil zone and decreases with the degree of soil degradation. Especially the combination of deep groundwater level and high water balance deficits during the vegetation period leads to tremendous CO₂ losses.  相似文献   

Long‐term carbon loss and CO2‐C release of drained peatland soils in northeast Germany     

B. Kluge  G. Wessolek  M. Facklam  M. Lorenz  K. Schwärzel 《European Journal of Soil Science》2008,59(6):1076-1086

Peatlands are common in many parts of the world. Draining and other changes in the use of peatlands increase atmospheric CO₂ concentration. If we are to make reliable quantitative predictions of that effect, we need good information on the CO₂ emission rates from peatlands. The present study uses two different methods for predicting CO₂‐C release of peatland soils: (i) a 40‐year field investigation of balancing organic carbon stocks and (ii) short‐term CO₂‐C release rates from laboratory experiments. To estimate long‐term losses of peat, and its resulting C input to the atmosphere, we combined highly detailed maps of surface topography and its changes, and the organic C contents and bulk densities of a drained peatland from different years. Short‐term CO₂‐C release rates were measured in the laboratory by incubating soil samples from several soil horizons at various temperatures and soil moistures. We then derived nonlinear CO₂‐C production functions, which we incorporated into a numerical simulation model (HYDRUS). Using HYDRUS, we calculated daily soil water components and CO₂‐release for (i) real‐climate data from 1950 to 2003 and (ii) a climate scenario extending to 2050, including an increase in temperature of 2°C and 20% less rainfall during the summer half year, i.e. from April to September inclusive. From our field measurements, we found a mean annual decrease of 0.7 cm in the thickness of the peat. Large losses (> 1.5 cm year^?1) occurred only during periods when groundwater levels were low (i.e. a deep water‐table). The annual CO₂‐C release results in a mean loss from the peat of about 700 g CO₂‐C m^?2, mostly as a direct contribution to the atmosphere. Both methods produced very similar results. The model scenarios demonstrated that CO₂‐C loss is mainly controlled by the groundwater (i.e. water‐table) depth, which controls subsurface aeration. A local climate scenario estimated a c. 5% increase of CO₂‐C losses within the next 50 years.  相似文献   

反渗条件下排水沟与农田水盐交换关系     

李山  罗纨  贾忠华  潘延鑫  武迪  张登科 《农业工程学报》2015,31(2):94-101

因干旱和半干旱下游灌区地势较低,排水出路不畅,排水系统往往成为承泄区外来水(上游灌溉退水和排水)的蓄水场所,使排水沟水位高于农田地下水位,反渗补给农田地下水,作物利用部分排水以后,如何维持农田良性的水盐平衡成为下游灌区一个迫切需要解决的科学问题。该文基于农田水盐平衡原理,以陕西一半干旱区下游灌区为例,在实测资料的基础上,首先利用田间水文模型DRAINMOD模拟了排水沟蓄水条件下,农田水位变化情况,然后计算分析了农田与排水沟的水盐交换关系。结果表明:在一个完整的种植年内单位长度排水沟上累计承接区外来水量为9.3 m3,减去流出水量,累计蓄积区外来水量为5.5 m3,农田单位面积上反渗累计补给田间地下水量为49.2 mm;累计农田排水量仅为2.3 mm。与作物蒸散发相比,现状条件下补给量虽然较小,但对维持和补给农田地下水起到了一定的作用。所产生的补给作用虽然增加了排水沟内盐分向田间地下水中的运动,但作物利用地下水过程中根区没有出现严重的盐分累积,对田间地下水盐分浓度影响也不大。所以,通过合理调控措施,充分利用区外来水,可以提高水资源利用效率。但排水系统长期运行条件下,高水位对农田水盐平衡的影响尚需进一步研究。  相似文献   

Influence of water table level and soil properties on emissions of greenhouse gases from cultivated peat soil     

Ö. Berglund  K. Berglund 《Soil biology & biochemistry》2011,43(5):923-9958

A lysimeter method using undisturbed soil columns was used to investigate the effect of water table depth and soil properties on soil organic matter decomposition and greenhouse gas (GHG) emissions from cultivated peat soils. The study was carried out using cultivated organic soils from two locations in Sweden: Örke, a typical cultivated fen peat with low pH and high organic matter content and Majnegården, a more uncommon fen peat type with high pH and low organic matter content. Even though carbon and nitrogen contents differ greatly between the sites, carbon and nitrogen density are quite similar. A drilling method with minimal soil disturbance was used to collect 12 undisturbed soil monoliths (50 cm high, Ø29.5 cm) per site. They were sown with ryegrass (Lolium perenne) after the original vegetation was removed. The lysimeter design allowed the introduction of water at depth so as to maintain a constant water table at either 40 cm or 80 cm below the soil surface. CO₂, CH₄ and N₂O emissions from the lysimeters were measured weekly and complemented with incubation experiments with small undisturbed soil cores subjected to different tensions (5, 40, 80 and 600 cm water column). CO₂ emissions were greater from the treatment with the high water table level (40 cm) compared with the low level (80 cm). N₂O emissions peaked in springtime and CH₄ emissions were very low or negative. Estimated GHG emissions during one year were between 2.70 and 3.55 kg CO₂ equivalents m⁻². The results from the incubation experiment were in agreement with emissions results from the lysimeter experiments. We attribute the observed differences in GHG emissions between the soils to the contrasting dry matter liability and soil physical properties. The properties of the different soil layers will determine the effect of water table regulation. Lowering the water table without exposing new layers with easily decomposable material would have a limited effect on emission rates.  相似文献   

Soil chemistry versus environmental controls on production of CH₄ and CO₂ in northern peatlands     

J. B. Yavitt  C. J. Williams  & R. K. Wieder 《European Journal of Soil Science》2005,56(2):169-178

Rates of organic carbon mineralization (to CO₂ and CH₄) vary widely in peat soil. We transplanted four peat soils with different chemical composition into six sites with different environmental conditions to help resolve the debate about control of organic carbon mineralization by resource availability (e.g. carbon and nutrient chemistry) versus environmental conditions (e.g. temperature, moisture, pH). The four peat soils were derived from Sphagnum (bog moss). Two transplant sites were in mid‐boreal Alberta, Canada, two were in low‐boreal Ontario, Canada, and two were in the temperate United States. After 3 years in the field, CH₄ production varied significantly as a function of peat type, transplant site, and the type–site interaction. All four peat soils had very small rates of CH₄ production (< 20 nmol g^?1 day^?1) after transplant into two sites, presumably caused by acid site conditions (pH < 4.0). One peat soil had small CH₄ production rates regardless of transplant site. A canonical discriminant analysis revealed that large rates of CH₄ production (4000 nmol g^?1 day^?1) correlated with large holocellulose content, a large concentration of p‐hydroxyl phenolic compounds in the Klason lignin, and small concentrations of N, Ca and Mn in peat. Significant variation in rates of CO₂ production correlated positively with holocellulose content and negatively with N concentrations, regardless of transplant site. The temperature response for CO₂ production varied as a function of climate, being greater for peat formed in a cold climate, but did not apply to transplanted peat. Although we succeeded in elucidating some aspects of peat chemistry controlling production of CH₄ and CO₂ in Sphagnum‐derived peat soils, we also revealed idiosyncratic combinations of peat chemistry and site conditions that will complicate forecasting rates of peat carbon mineralization into the future.  相似文献   

Temperature, water content and wet-dry cycle effects on DOC production and carbon mineralization in agricultural peat soils     

Alex T. Chow  Kenneth K. Tanji  Randy A. Dahlgren 《Soil biology & biochemistry》2006,38(3):477-488

Agricultural peat soils in the Sacramento-San Joaquin Delta, California have been identified as an important source of dissolved organic carbon (DOC) and trihalomethane precursors in waters exported for drinking. The objectives of this study were to examine the primary sources of DOC from soil profiles (surface vs. subsurface), factors (temperature, soil water content and wet-dry cycles) controlling DOC production, and the relationship between C mineralization and DOC concentration in cultivated peat soils. Surface and subsurface peat soils were incubated for 60 d under a range of temperature (10, 20, and 30 °C) and soil water contents (0.3-10.0 g-water g-soil⁻¹). Both CO₂-C and DOC were monitored during the incubation period. Results showed that significant amount of DOC was produced only in the surface soil under constantly flooded conditions or flooding/non-flooding cycles. The DOC production was independent of temperature and soil water content under non-flooded condition, although CO₂ evolution was highly correlated with these parameters. Aromatic carbon and hydrophobic acid contents in surface DOC were increased with wetter incubation treatments. In addition, positive linear correlations (r²=0.87) between CO₂-C mineralization rate and DOC concentration were observed in the surface soil, but negative linear correlations (r²=0.70) were observed in the subsurface soil. Results imply that mineralization of soil organic carbon by microbes prevailed in the subsurface soil. A conceptual model using a kinetic approach is proposed to describe the relationships between CO₂-C mineralization rate and DOC concentration in these soils.  相似文献   

Aspects of peat conservation and water management     

Manfred Renger  Gerd Wessolek  Kai Schwrzel  Robert Sauerbrey  Christian Siewert 《植物养料与土壤学杂志》2002,165(4):487-493

An extended water regime model was used for calculating the evapotranspiration, groundwater recharge, and peat mineralization (CO₂ and N release) for various fen locations with grassland utilization in dependence on the groundwater level. The results show that an increasing groundwater level leads to a strong decline of the actual evapotranspiration E_t. For example, increasing the groundwater level from 30 to 120 cm diminishes the E_t by up to 230 mm a^—1. A positive groundwater recharge only takes place at groundwater levels of 90 cm and more. At smaller distances the capillary rise into the rooting zone during the summer months is greater than the water seepage during the winter months, so that a negative groundwater recharge‐balance is reached in the course of a year. The CO₂‐ and the N‐release, as well as the annual decline in peat thickness, increase significantly with rising groundwater levels. The results show, that varying the groundwater level can influence the water regime and the peat mineralization significantly. The lower the groundwater level the less is the peat decomposition. The demand for a groundwater level as small as possible is, however, limited by an agricultural utilization of the fens. Choosing the optimum groundwater level should consider the aims (1) peat mineralization, (2) gas emission (CO₂, CH₄, N₂O), and (3) crop production. If a grassland utilization is supposed to be made possible and all three aims above are given equal importance, the groundwater level should be maintained at 30 cm. At this distance, about 90 % of the optimum plant output can be reached. The peat mineralization can be reduced to 30 to 40 % of the maximum peat mineralization. The gas emission amounts to 50—60 % of the maximum value.  相似文献   

基于DRAINMOD模型估算灌区浅层地下水利用量及盐分累积     

李山  罗纨  贾忠华  潘延鑫  武迪  张登科 《农业工程学报》2015,31(22):89-97

在灌溉季节,尤其是下游灌区,农田地下水位较高,作物可就地利用部分浅层地下水,从而减少灌溉需水量,达到节水减排的双重目的。大田作物对浅层地下水利用量的估算是合理制定灌溉淋洗制度及控制土壤盐碱化的前提,但其估算存在一定困难。该文假设当农田灌溉、排水等水文气象条件一致时,某一作物对浅层地下水的利用量等于该田块有、无作物(即裸地)2种情况下造成地下水位差异的水量。据此,首先建立了浅层地下水利用量的计算模型,并以某一半干旱灌区为例,利用田间水文模型-DRAINMOD模拟出有、无作物2种条件下农田地下水位变化过程,然后,计算了棉花、小麦轮作期内对浅层地下水的利用量;在此基础上,进一步分析了浅层地下水利用条件下土壤剖面的盐分平衡。结果显示,该文提出的计算模型能够较好的反映大田实际情况;研究时段内,田间地下水埋深平均值为2.1 m,单位面积上作物利用浅层地下水量为305.8 mm,主要发生在作物生长阶段,其中棉花生长季内地下水利用量约为160 mm。盐分平衡计算结果显示,浅层地下水的利用使得水位以上土壤剖面盐分含量增加,但1 m以内根区土壤盐分在降雨和灌溉作用下得到一定的淋洗,未超出作物耐盐极限,不会对产量造成显著影响。研究成果可为相关灌区制定合理的灌溉制度及提高水资源利用效率提供科学依据。  相似文献   

CO₂ emission from soils under different uses and flooding conditions     

M.E. Guntiñas  M.C. Leirós 《Soil biology & biochemistry》2009,41(12):2598-2601

The emission of CO₂ from Galician (NW Spain) forest, grassland and cropped soils was studied in a laboratory experiment, at different temperatures (10-35 °C) and at moisture contents of 100% and 160% of the field capacity (FC) of each soil (the latter value corresponds to saturated conditions, and represents between 120% and 140% of the water holding capacity, depending on the soil). In the forest soil, respiration in the flooded samples at all temperatures was lower than that at 100% field capacity. In the agricultural (grassland and cropped) soils the emission was higher (particularly at the highest incubation temperatures) in the soils wetted to 160% of the field capacity than in those wetted to 100% of the field capacity. In all cases the emission followed first order kinetics and the mineralization constants increased exponentially with temperature. In the forest soil, the Q₁₀ values were almost the same in the soils incubated at the two moisture contents. The grassland and cropped soils displayed different responses, as the Q₁₀ values were higher in the soils at 160% than in those at 100% of field capacity. In addition, and particularly at the highest temperatures, the rate of respiration increased sharply 9 and 17 days after the start of the incubation in the grassland and in the cropped soil, respectively. The above-mentioned anomalous response of the grassland and cropped soils under flooding conditions may be related to the agricultural use of the soils and possibly to the intense use of organic fertilizers in these soils (more than 150 kg N ha⁻¹ year⁻¹ added as cattle slurry or manure, respectively, in the grassland and cropped soils). The observed increase in respiration may either be related to the development of thermophilic facultative anaerobic microbes or to the formation during the incubation period of a readily metabolizable substrate, possibly originating from the remains of organic fertilizers, made accessible by physicochemical processes that occurred during incubation under conditions of high moisture.  相似文献   

Translocation of soils to stimulate climate change: CO₂ emissions and modifications to soil organic matter     

M. Rey    E. Guntiñas    F. Gil-Sotres  M. C. LeirÓs  & C. Trasar-Cepeda 《European Journal of Soil Science》2007,58(6):1233-1243

The effect of climate change on CO₂ emissions was studied on undisturbed soil monoliths (40‐cm diameter, 25‐cm high), which were translocated to warmer zones than their place of origin. Thirty‐two months after the translocation, a climatic factor deduced from the moisture content of the soil and from the effective mean temperature (temperatures in excess of 5°C) revealed that translocation increased the potential of the climate to enhance the biological processes by between 73% and 26% compared with what the soil would support in its place of origin. At the end of the study, the transported soils had lost a large proportion of both total carbon and nitrogen (between 20 and 45%). During the experiment, the CO₂ emissions from the soils, measured under field conditions, were quite variable, but were usually greater than from soils in situ. The variation in labile C in the soil throughout the experiment was calculated from a first‐order kinetic equation for organic matter decay. The relative CO₂ emissions, expressed in terms of the labile carbon fraction in the soils, were clearly greater in those translocated soils that underwent the most intensive climate change, which indicates that the variations in emissions over time are basically a function of the size of the labile organic matter pool.  相似文献   

灌溉排水耦合调控稻田水分转化关系   总被引：2，自引：1，他引：2  

和玉璞  张建云  徐俊增  洪大林  杨士红 《农业工程学报》2016,32(11):144-149

该文利用装配有地下水位自动控制系统的蒸渗仪,分析节水灌溉与旱地控制排水技术耦合调控对于稻田水分转化关系的影响。结果表明,灌排耦合调控在小幅减少水稻产量的同时,显著减少了稻田灌溉水量、地下排水量及水稻蒸发蒸腾量,最终显著增加了水稻水分生产效率。与常规灌排稻田相比,灌排耦合调控稻田水稻产量减少1.9%,灌溉水量、地下排水量及水稻蒸发蒸腾量分别显著减少41.7%、49.9%及24.9%,水分生产效率增加30.5%。随着控灌稻田排水控制限的提高,稻田灌溉水量、地下排水量及水稻蒸发蒸腾量减少,水稻产量保持稳定,使得水稻水分生产效率进一步增加。提高控灌稻田的排水控制限,减缓了稻田土壤水分的衰退速度,并增加稻田地下水位低于排水控制限的比例,稻田灌溉次数与发生地下排水的时段均减少,使得控灌稻田灌溉水量与地下排水量下降,两者综合作用下控灌稻田水稻蒸发蒸腾量减少。在采用控制灌溉模式的基础上,适当提高稻田排水控制限,可以较好地实现水稻生产中水分的高效利用,研究结果可为优化稻田水管理模式提供依据。  相似文献   

松嫩平原土壤水分动态的研究   总被引：1，自引：0，他引：1  

周有才  赵洪书 《土壤学报》1979,16(3):302-305

松嫩平原地域辽阔,位于北纬44°30'-50°。冬季严寒,漫长而少雪,夏季湿热,短促多雨。年平均气温1-4℃,土地冻结深度1.8-3.0米,是我国最北部的季节性冻土区。由于一年中冻土存在的时间达7-12个月之久,形成了土壤水分动态的特殊类型,既不同于非冻结区,也不同于永久性冻结区。本文着重探讨松嫩平原低部季节性冻土的土壤水分动态规律和特点。  相似文献   

Differences in the activity and bacterial community structure of drained grassland and forest peat soils     

Luka Ausec  Barbara Kraigher  Ines Mandic-Mulec   《Soil biology & biochemistry》2009,41(9):1874-1881

The microbial activity and bacterial community structure were investigated in two types of peat soil in a temperate marsh. The first, a drained grassland fen soil, has a neutral pH with partially degraded peat in the upper oxic soil horizons (16% soil organic carbon). The second, a bog soil, was sampled in a swampy forest and has a very high soil organic carbon content (45%), a low pH (4.5), and has occasional anoxic conditions in the upper soil horizons due to the high water table level. The microbial activity in the two soils was measured as the basal and substrate-induced respiration (SIR). Unexpectedly, the SIR (μl CO₂ g⁻¹ dry soil) was higher in the bog than in the fen soil, but lower when CO₂ production was expressed per volume of soil. This may be explained by the notable difference in the bulk densities of the two soils. The bacterial communities were assessed by terminal restriction fragment length polymorphism (T-RFLP) profiling of 16S rRNA genes and indicated differences between the two soils. The differences were determined by the soil characteristics rather than the season in which the soil was sampled. The 16S rRNA gene libraries, constructed from the two soils, revealed high proportions of sequences assigned to the Acidobacteria phylum. Each library contained a distinct set of phylogenetic subgroups of this important group of bacteria.  相似文献   

Effects of Soil Water Repellency on Moisture Patterns in a Degraded Sapric Histosol     

Edyta Hewelke  Jan Szaty&#x;owicz  Tomasz Gnatowski  Ryszard Oleszczuk 《Land Degradation \u0026amp; Development》2016,27(4):955-964

An understanding of soil moisture content variability is fundamental in hydrological studies of peat soils, whose preservation depend on water‐related processes. Dehydration of fens and adapting them for agricultural production have contributed to the degradation of peat soils. The goal of this study was to determine how the critical soil moisture content (CSMC) and soil water repellency (SWR) affect soil moisture patterns in a degraded peat‐muck soil profile. SWR was measured under laboratory conditions using the water drop penetration time test, and then the CSMC was assessed. An investigation of moisture patterns was based on soil moisture data collected over short distances in a grass‐covered peat‐muck soil profile on seven dates. Observed differences in moisture patterns demonstrate that the CSMC can be used for the prediction of preferential flow occurrences in peat‐muck soils. Lower values of the CSMC and lower levels of SWR persistence in muck layers than in peat layers indicate that degradation of peat soils improves their wettability. The relatively low values of CSMC and the low shrinkage potential in the muck layer suggest that preferential water flow in the degraded organic soils can occur when heavy rains are preceded by long periods of summer drought. Copyright © 2014 John Wiley & Sons, Ltd.  相似文献   

Influence of load on shrinkage behavior of peat soils     

Ryszard Oleszczuk  Klaus Bohne  Jan Szatylowicz  Tomasz Brandyk  Tomasz Gnatowski 《植物养料与土壤学杂志》2003,166(2):220-224

The shrinkage of the peat soils that accompanies the soil moisture changes is an important feature of such soils and has strong influence on their physical attributes and soil water management. The relationships between soil moisture and volume are often described using shrinkage characteristic curves by relating void ratio (volume of voids per unit volume of solids) to moisture ratio (volume of water per volume of solids). For conversion of soil volume changes into cracks volume and subsidence, a dimensionless shrinkage geometry factor is used. The paper presents results of volumetric shrinkage behavior and the geometry factor at various loads in sedge and alder peat soils. The measurements were conducted on undisturbed soil samples without applying a load and with loads corresponding to field overburden. The shape of the shrinkage characteristics of such soils were completely different from those of clay soils. The application of loads did not significantly influence the shrinkage characteristics curve. The applied load strongly influenced on relationship between shrinkage geometry factor and the moisture ratio, showing higher values of subsidence and lower values of crack volume in comparison with unloaded conditions.  相似文献   

Driving factors of temporal variation in agricultural soil respiration     

Yang Wang  Manfred Bölter  Qingrui Chang  Rainer Duttmann  Annette Scheltz  James F. Petersen 《Acta Agriculturae Scandinavica, Section B - Plant Soil Science》2013,63(7):589-604

Investigations of diurnal and seasonal variations in soil respiration support modeling of regional CO₂ budgets and therefore in estimating their potential contribution to greenhouse gases. This study quantifies temporal changes in soil respiration and their driving factors in grassland and arable soils located in Northern Germany. Field measurements at an arable site showed diurnal mean soil respiration rates between 67 and 99 mg CO₂ m^–2 h^–1 with a hysteresis effect following changes in mean soil temperatures. Field soil respiration peaked in April at 5767 mg CO₂ m^–2 day^–1, while values below 300 mg CO₂ m^–2 day^–1 were measured in wintertime. Laboratory incubations were carried out in dark open flow chambers at temperatures from 5°C to 40°C, with 5°C intervals, and soil moisture was controlled at 30%, 50%, and 70% of full water holding capacity. Respiration rates were higher in grassland soils than in arable soils when the incubating temperature exceeded 15°C. The respiration rate difference between them rose with increasing temperature. Monthly median values of incubated soil respiration rates ranged from 0 to 26.12 and 0 to 7.84 µg CO₂ g^–1 dry weight h^–1, respectively, in grassland and arable land. A shortage of available substrate leads to a temporal decline in soil respiration rates, as indicated by a decrease in dissolved organic carbon. Temporal Q₁₀ values decreased from about 4.0 to below 1.5 as temperatures increased in the field. Moreover, the results of our laboratory experiments confirmed that soil temperature is the main controlling factor for the Q₁₀ values. Within the temperature interval between 20°C and 30°C, Q₁₀ values were around 2 while the Q₁₀ values of arable soils were slightly lower compared to that of grassland soils. Thus, laboratory studies may underestimate temperature sensitivity of soil respiration, awareness for transforming laboratory data to field conditions must therefore be taken into account.  相似文献   

黑土不同土地利用方式下受水分有效性调节的土壤CO2排放的温度敏感性     

HAN Xiao-Zeng  LI Hai-Bo  W. R. HORWATH 《土壤圈》2013,23(5):636-650

The quantification of soil CO2 efflux is crucial for better understanding the interactions between driving variables and C losses from black soils in Northeast China and for assessing the function of black soil as a net source or sink of atmospheric CO2 depending upon land use.This study investigated responses of soil CO2 efflux variability to soil temperature interactions with diferent soil moisture levels under various land use types including grassland,bare land,and arable(maize,soybean,and wheat)land in the black soil zone of Northeast China.The soil CO2 effluxes with and without live roots,defined as the total CO2 efflux(FtS)and the root-free CO2 efflux(FrfS),respectively,were measured from April 2009 to May 2010 using a static closed chamber technique with gas chromatography.The seasonal soil CO2 fluxes tended to increase from the beginning of the measurements until they peaked in summer and then declined afterwards.The mean seasonal FtS ranged from 20.3±7.8 to 58.1±21.3 mg CO2-C m-2h-1 for all land use types and decreased in the order of soybean land>grassland>maize land>wheat land>bare land,while the corresponding values of FrfS were relatively lower,ranging from 20.3±7.8 to 42.3±21.3 mg CO2-C m-2h-1.The annual cumulative FtS was in the range of 107-315 g CO2-C m-2 across all land uses types.The seasonal CO2 effluxes were significantly(P<0.001)sensitive to soil temperature at 10 cm depth and were responsible for up to 62% of the CO2 efflux variability.Correspondingly,the temperature coefcient Q10 values varied from 2.1 to 4.5 for the seasonal FtS and 2.2 to 3.9 for the FrfS during the growing season.Soil temperature interacting with soil moisture accounted for a significant fraction of the CO2 flux variability for FtS (up to 61%) and FrfS (up to 67%) via a well-defined multiple regression model,indicating that temperature sensitivity of CO2 flux can be mediated by water availability,especially under water stress.  相似文献   

The Effect of Contrasting Moistening Regimes on CO<Subscript>2</Subscript> Emission from the Gray Forest Soil under a Grass Vegetation and Bare Fallow     

V. O. Lopes de Gerenyu  I. N. Kurganova  D. A. Khoroshaev 《Eurasian Soil Science》2018,51(10):1200-1213

The effect of contrasting moisture regimes on the CO₂ emission from the gray forest soils (Haplic Luvisols (Loamic, Cutanic, Humic)) under a grass vegetation and bare fallow was studied in a field simulation experiment in June–September, 2015 (Moscow region). Two short soil droughts (53 and 34 days) and a long one (94 days) were simulated on plots isolated from precipitation. A variant with regular irrigation, where the soil moisture was maintained 60–70% of their water holding capacity, was used as a control. Over the whole observation period, the CO₂ emissions from the soils studied decreased by a factor of 1.8 compared to the control only in the variant with the grass vegetation under prolonged drought. During the first hours after irrigation of the dry plots, the soil respiration intensified due to the “Birch effect”. The magnitude of this effect was 84–104% in the soils under the grass vegetation and 114–133% in the fallow areas. Owing to this phenomenon, the total CO₂ emission from the soils subjected to two short droughts was equal to the CO₂ flux under regular moistening for the grass plots and exceeded it by almost 1.3 times for the fallow plots as compared to the control. However, the share of extra CO₂ flux induced by moistening of the dry soils did not exceed 8–10% of the total CO₂ emission over the whole observation period.  相似文献   

盐碱地咸水灌溉枸杞种植条件下土壤盐分变化     

DOU Chao-Yin  KANG Yao-Hu  WAN Shu-Qin  HU Wei 《土壤圈》2011,21(4):539-548

In order to utilize the wasted saline-sodic soils under shallow groundwater condition,a 3-year field study was carried in a field cropped with Lycium barbarum L.and irrigated by drip irrigation with saline groundwater under the water table depth of 30-40 cm in the northern Yinchuan Plain,China.Effects of cropping duration (one,two,and three years) on soil salinity,soil solution composition,and pH in three adjacent plots were investigated in 2008.Results showed that a high irrigation frequency maintained high soil water potential and subsequently facilitated infiltration and downward movement of water and salt in the crop root zone.Salt accumulated on the edges of the ridges,and soil saturated-paste electrical conductivity (ECe) was higher in the edge.Concentrations of Na+,Ca2+,Mg2+,Cl-,and SO42- in the soil increased with the soil depth as did the ECe,while HCO3- and pH had a relative uniform distribution in soil profile.As planting year increased,the ECe and soil salts in the field had a decreasing tendency,while in the root zone they decreased immediately after irrigation and then remained relatively stable in the following growing seasons.HCO3- and pH had little change with the planting year.Results suggested that the application of drip irrigation with saline water could ameliorate saline-sodic soil and provide a relatively feasible soil environment for the growth of salt-tolerant plant Lycium barbarum L.under the saline-sodic soils with shallow groundwater.  相似文献   

Uneven moisture patterns in water repellent soils   总被引：2，自引：0，他引：2  

Louis W. Dekker  Coen J. Ritsema 《Geoderma》1996,70(2-4):87-99

In the Netherlands, water repellent soils are widespread and they often show irregular moisture patterns, which lead to accelerated transport of water and solutes to the groundwater and surface water. Under grasscover, spatial variability in soil moisture content is high due to fingered flow, in arable land vegetation and microtopography play a dominant role. Examples are given of uneven soil moisture patterns in water repellent sand, loam, clay and peat soils with grasscover, and in cropped water repellent sandy soils. In addition, the influence of fungi on inducing soil moisture patterns is illustrated as well.  相似文献