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1.
Tillage stimulates soil carbon (C) losses by increasing aeration, changing temperature and moisture conditions, and thus favoring microbial decomposition. In addition, soil aggregate disruption by tillage exposes once protected organic matter to decomposition. We propose a model to explain carbon dioxide (CO2) emission after tillage as a function of the no-till emission plus a correction due to the tillage disturbance. The model assumes that C in the readily decomposable organic matter follows a first-order reaction kinetics equation as: dCsail(t)/dt = −kCsoil(t) and that soil C-CO2 emission is proportional to the C decay rate in soil, where Csoil(t) is the available labile soil C (g m−2) at any time (t). Emissions are modeled in terms soil C available to decomposition in the tilled and non-tilled plots, and a relationship is derived between no-till (FNT) and tilled (FT) fluxes, which is: FT=a1FNT ea2t, where t is time after tillage. Predicted and observed fluxes showed good agreement based on determination coefficient (R2), index of agreement and model efficiency, with R2 as high as 0.97. The two parameters included in the model are related to the difference between the decay constant (k factor) of tilled and no-till plots (a2) and also to the amount of labile carbon added to the readily decomposable soil organic matter due to tillage (a1). These two parameters were estimated in the model ranging from 1.27 and 2.60 (a1) and −1.52 × 10−2 and 2.2 × 10−2 day−1 (a2). The advantage is that temporal variability of tillage-induced emissions can be described by only one analytical function that includes the no-till emission plus an exponential term modulated by tillage and environmentally dependent parameters.  相似文献   

2.
In semiarid Mediterranean agroecosystems, low and erratic annual rainfall together with the widespread use of mouldboard ploughing (conventional tillage, CT), as the main traditional tillage practice, has led to a depletion of soil organic matter (SOM) and with increases in CO2 emissions from soil to the atmosphere. In this study, we evaluated the viability of conservation tillage: RT, reduced tillage (chisel and cultivator ploughing) and, especially, NT (no-tillage) to reduce short-term (from 0 to 48 h after a tillage operation) and mid-term (from 0 h to several days since tillage operation) tillage-induced CO2 emissions. The study was conducted in three long-term tillage experiments located at different sites of the Ebro river valley (NE Spain) across a precipitation gradient. Soils were classified as: Fluventic Xerocrept, Typic Xerofluvent and Xerollic Calciorthid. Soil temperature and water content were also measured in order to determine their influence on tillage-induced CO2 fluxes. The majority of the CO2 flux measured immediately after tillage ranged from 0.17 to 6 g CO2 m−2 h−1 and was from 3 to 15 times greater than the flux before tillage operations, except in NT where soil CO2 flux was low and steady during the whole study period. Mid-term CO2 emission showed a different trend depending on the time of the year in which tillage was implemented. Microclimatic soil conditions (soil temperature and water content) had little impact on soil CO2 emission following tillage. In the semiarid Mediterranean agroecosystems studied, NT had low short-term soil CO2 efflux compared with other soil tillage systems (e.g., conventional and reduced tillage) and therefore can be recommended to better manage C in soil.  相似文献   

3.
Management of crop residues and soil organic matter is of primary importance in maintaining soil fertility and productivity and in minimizing agricultural impact on the environment. Our objective was to determine the effects of traffic and tillage on short-term carbon dioxide (CO2) and water (H2O) fluxes from a representative soil in the southeastern Coastal Plain (USA). The study was conducted on a Norfolk loamy sand (FAO classification, Luxic Ferralsols; USDA classification, fine-loamy siliceous, thermic Typic Kandiudults) cropped to a corn (Zea mays L.) — soybean (Glycine max (L.) Merr) rotation with a crimson clover (Trifolium incarnatum L.) winter cover crop for eight years. Experimental variables were with and without traffic under conventional tillage (CT) (disk harrow twice, chisel plow, field cultivator) and no tillage (NT) arranged in a split-plot design with four replicates. A wide-frame tractive vehicle enabled tillage without wheel traffic. Short-term CO2 and H2O fluxes were measured with a large portable chamber. Gas exchange measurements were made on both CT and NT at various times associated with tillage and irrigation events. Tillage-induced CO2 and H2O fluxes were larger than corresponding fluxes from untilled soil. Irrigation caused the CO2 fluxes to increase rapidly from both tillage systems, suggesting that soil gas fluxes were initially limited by lack of water. Tillage-induced CO2 and H2O fluxes were consistently higher than under NT. Cumulative CO2 flux from CT at the end of 80 h was nearly three times larger than from NT while the corresponding H2O loss was 1.6 times larger. Traffic had no significant effects on the magnitude of CO2 fluxes, possibly reflecting this soil’s natural tendency to reconsolidate. The immediate impact of intensive surface tillage of sandy soils on gaseous carbon loss was larger than traffic effects and suggests a need to develop new management practices for enhanced soil carbon and water management for these sensitive soils.  相似文献   

4.
Soil tillage may influence CO2 emissions in agricultural systems. Agricultural soils are managed in several ways in Brazil, ranging from no tillage to intensive land preparation. The objective of this study was to determine the effect of common soil tillage treatments (disk harrow, reversible disk plow, rotary tiller and chisel plow tillage systems) on the intermediate CO2 emissions of a dark red latosol, located in southern Brazil. Different tillage systems produced significant differences in the CO2 emissions, and the results indicate that the chisel plow produced the highest soil carbon loss during the 15 days period after tillage treatments were performed. Emissions to the atmosphere increased as much as 74 g CO2 m−2, at the end of a 2-week period, in the plot where the chisel plow treatment was applied, in comparison to the non-disturbed plot. The results indicate that the total increase on the intermediate term soil CO2 emissions due to tillage treatments in southern Brazil is comparable to that reported for the more humid and cooler regions.  相似文献   

5.
The objective of this study was to investigate the effect of tillage and cropping system on near-saturated hydraulic conductivity, residue cover and surface roughness to improve soil management for moisture conservation under semiarid Mediterranean conditions. Three tillage systems were compared (subsoil tillage, minimum tillage and no-tillage) under three field situations (continuous crop, fallow and crop after fallow) on two soils (Fluventic Xerochrept and Lithic Xeric Torriorthent). Soil under no-tillage had lower hydraulic conductivity (5.0 cm day−1) than under subsoil tillage (15.5 cm day−1) or minimum tillage (14.3 cm day−1) during 1 of 2 years in continuous crop due to a reduction of soil porosity. Residue cover at sowing was greater under no-tillage (60%) than under subsoil or minimum tillage (<10%) in continuous crop. Under fallow, residue cover was low (10%) at sowing of the following crop for all tillage systems in both soils. Surface roughness increased with tillage, with a high value of 16% and decreasing following rainfall. Under no-tillage, surface roughness was relatively low (3–4%). Greater surface residue cover under no-tillage helped conserve water, despite indications of lower hydraulic conductivity. To overcome the condition of low infiltration and high evaporation when no-till fallow is expected in a cropping sequence, either greater residue production should be planed prior to fallow (e.g. no residue harvest) or surface tillage may be needed during fallow.  相似文献   

6.
Stopping the increase of atmospheric CO2 level is an important task and information on how to implement adjustments on tillage practices could help lower soil CO2 emissions would be helpful. We describe how rotary tiller use on a red latosol affected soil CO2 efflux. The impact of changing blade rotation speed and rear shield position on soil CO2 efflux was investigated. Significant differences among treatments were observed up to 10 days after tillage. Cumulative CO2 efflux was as much as 40% greater when blade rotation of 216 rpm and a lowered rear shield was compared to blade rotation of 122 rpm and raised shield. This preliminary work suggests that adjusting rotary tiller settings could help reduce CO2 efflux close to that of undisturbed soil, thereby helping to conserve soil carbon in tropical environments.  相似文献   

7.
农牧交错带不同农田耕作模式土壤水分特征对比研究   总被引:16,自引:1,他引:16  
通过在农牧交错带———内蒙古自治区太仆寺旗的野外实验研究,在作物(油菜)发育期间,观测了免耕、深松、传统翻耕、翻耕覆盖、浅耕与垄作处理等8种耕作模式的土壤水分特征;在秋收后的农田休闲期,观测了秸秆还田翻耕、深松耕作、传统翻耕、免耕低茬(茬高10cm)和免耕高茬(茬高4 5cm)等5种耕作模式的土壤水分特征。实验结果表明:在实验区,采用不同耕作模式,对田块土壤水分含量有着直接影响。在作物发育期间,垄作处理蓄水保墒能力相对较强,免耕、浅耕蓄水保墒能力相对较差,翻耕覆盖、深松耕作、传统翻耕蓄水保墒能力相对居中;秋收后,免耕高茬蓄水保墒效果最好,深松耕作、传统翻耕蓄水保墒能力居中,秸秆还田翻耕、免耕低茬蓄水保墒效果较差。本文所得结论对农牧交错带旱作农田有效保蓄土壤水分、提高农田土壤水分利用效率和增强农田防风抗蚀能力有积极借鉴意义  相似文献   

8.
Tillage affects the ability of coarse-textured soils of the southeastern USA to sequester C. Our objectives were to compare tillage methods for soil CO2 flux, and determine if chemical or physical properties after 25 years of conventional or conservation tillage correlated with flux rates. Data were collected for several weeks during June and July in 2003, October and November in 2003, and April to July in 2004 from a tillage study established in 1978 on a Norfolk loamy sand (fine-loamy, kaolinitic, thermic Typic Kandiudults). Conventional tillage consisted of disking to a depth of approximately 15 cm followed by smoothing with an S-tined harrow equipped with rolling baskets. Conservation tillage consisted of direct seeding into surface residues. Flux rates in conservation tillage averaged 0.84 g CO2 m−2 h−1 in Summer 2003, 0.36 g CO2 m−2 h−1 in Fall 2003, 0.46 g CO2 m−2 h−1 in Spring 2004, and 0.86 g CO2 m−2 h−1 in Summer 2004. Flux rates from conventional tillage were greater for most measurement times. Conversely, water content of the surface soil layer (6.5 cm) was almost always higher with conservation tillage. Soil CO2 flux was highly correlated with soil water content only in conventional tillage. In conservation tillage, no significant correlations occurred between soil CO2 flux and soil N, C, C:N ratio, pH, bulk density, sand fraction, or clay fraction of the surface 7.5 cm. In conventional tillage, sand fraction was positively correlated, while bulk density and clay fraction were negatively correlated with soil CO2 flux rate, but only when the soil was moist. Long-term conservation tillage management resulted in more uniform within- and across-season soil CO2 flux rates that were less affected by precipitation events.  相似文献   

9.
Depending upon how soil is managed, it can serve as a source or sink for atmospheric carbon dioxide (CO2). As the atmospheric CO2 concentration continues to increase, more attention is being focused on the soil as a possible sink for atmospheric CO2. This study was conducted to examine the short-term effects of crop rotation and N fertilization on soil CO2 emissions in Central Iowa. Soil CO2 emissions were measured during the growing seasons of 2003 and 2004 from plots fertilized with three N rates (0, 135, and 270 kg N ha−1) in continuous corn and a corn–soybean rotation in a split-plot design. Soil samples were collected in the spring of 2004 from the 0–15 cm soil depth to determine soil organic C content. Crop residue input was estimated using a harvest index based on the measured crop yield. The results show that increasing N fertilization generally decreased soil CO2 emissions and the continuous corn cropping system had higher soil CO2 emissions than the corn–soybean rotation. Soil CO2 emission rate at the peak time during the growing season and cumulative CO2 under continuous corn increased by 24 and 18%, respectively compared to that from corn–soybean rotation. During this period, the soil fertilized with 270 kg N ha−1 emitted, on average, 23% less CO2 than the soil fertilized with the other two N rates. The greatest difference in CO2 emission rate was observed in 2004; where plots that received 0 N rate had 31% greater CO2 emission rate than plots fertilized with 270 kg N ha−1. The findings of this research indicate that changes in cropping systems can have immediate impact on both rate and cumulative soil CO2 emissions, where continuous corn caused greater soil CO2 emissions than corn soybean rotation.  相似文献   

10.
Soil carbon (C) losses and soil translocation from tillage operations have been identified as causes of soil degradation and soil erosion. The objective of this work was to quantify the variability in tillage-induced carbon dioxide (CO2) loss by moldboard (MP) and chisel (CP) plowing across an eroded landscape and relate the C loss to soil properties. The study site was a 4 ha wheat (Triticum aestivum L. cv. Marshall) field with rolling topography and five soil types in the Svea-Barnes complex in west central Minnesota (N. Latitude = 45°41′W, Longitude = 95°43′). Soil properties were measured at several depths at a 10 m spacing along north–south (N–S) and west–east (W–E) transects through severely eroded, moderately eroded and non-eroded sites. Conventional MP (25 cm deep) and CP (15 cm deep) equipment were used along the pre-marked transects. Gas exchange measurements were obtained with a large, portable chamber within 2 m of each sample site following tillage. The measured CO2 fluxes were largest with the MP > CP > not tilled (before tillage). The variation in 24 h cumulative CO2 flux from MP was nearly 3-fold on the N–S transect and 4-fold on the W–E transect. The surface soil organic C on the transects was lowest on the eroded knolls at 5.1 g C kg−1 and increased to 19.6 g C kg−1 in the depositional areas. The lowest CO2 fluxes were measured from severely eroded sites which indicated that the variation in CO2 loss was partially reflected by the degradation of soil properties caused by historic tillage-induced soil translocation with some wind and water erosion.

The spatial variation across the rolling landscape complicates the determination of non-point sources of soil C loss and suggests the need for improved conservation tillage methods to maintain soil and air quality in agricultural production systems.  相似文献   


11.
为探讨耕作及轮作方式对农田土壤理化性质和碳组分的影响,设置免耕、传统耕作2种耕作方式,以及小麦-玉米轮作、小麦/玉米间作、小麦-冬油菜-玉米轮作3种种植模式,共形成6个处理,研究结果表明:与传统耕作相比,免耕增加了0~5 cm、5~20 cm土层全氮、全磷、速效磷和含水量,而降低了的土壤pH和土壤容重。免耕小麦/玉米间作(NT.W1/NT.WM.1)处理的土壤容重、含水量、全氮、全磷含量高于NT.WRM3和NT.WM5处理,在不同土层间,土壤全氮、全磷和速效磷含量随着土层深度的增加而降低。土壤碳组分含量总体表现为免耕处理高于传统耕作处理,免耕处理0~5 cm土层土壤有机碳、颗粒有机碳、可溶性有机碳、微生物量碳含量较相应传统耕作分别增加了1.31%~36.57%、2.07%~35.22%、2.38%~4.78%、2.08%~11.68%,在5~20 cm土层,免耕处理土壤有机碳和微生物量碳含量高于传统耕作。在不同免耕处理下,土壤有机碳,颗粒有机碳和微生物量碳含量在0~5 cm、5~20 cm土层总体表现为NT.WM5高于其他免耕处理,相关性分析表明,有机碳、微生物量碳和速效磷呈极显著正相关,容重和有机碳呈极显著负相关。综上所述,免耕小麦/玉米间作利于改善土壤理化性质,小麦-玉米轮作有利于提高土壤有机碳,颗粒有机碳和微生物量碳含量。  相似文献   

12.
[目的]研究宁南山区冬小麦农田休闲期保护性农业措施对土壤水分的影响,为该区降雨资源的高效利用以及保护性农业的可持续发展提供理论依据。[方法]基于不同时期多个保护性农业试验土壤水分数据比较分析。[结果](1)在干旱的情况下,免耕留茬处理能够显著增加土壤表层(0—20cm)含水量。(2)在免耕的情况下,随着秸秆留茬高度的增加,土壤水分呈现增加趋势。(3)在降雨量较大且降雨量具有连续性的情况下,常规耕作处理在土壤表层保蓄了较多的土壤水分(0—20cm),免耕秸秆覆盖处理能够增加土壤20—80cm土壤水分含量。(4)冬小麦休闲期种植豆科作物,降低了土壤水分,其降低幅度与降雨量以及种植密度有关,种植密度越大,对土壤水分的影响越大。[结论]免耕+留茬耕作措施能够提高冬小麦农田休闲期土壤水分含量,覆盖作物降低了休闲期土壤水分含量。  相似文献   

13.
采用开路式土壤碳通量测量系统于2010年3-10月在冬小麦-大豆轮作期对免耕与翻耕田土壤呼吸速率、5cm深土壤温度和湿度进行测定,以研究耕作措施对农田土壤呼吸的影响。结果表明,在冬小麦、大豆生长时段,免耕与翻耕田土壤呼吸速率的季节变化趋势基本一致。冬小麦生长时段免耕与翻耕田土壤呼吸速率的平均值分别为2.50±0.14和2.40±0.29μmol.m-2.s-1,大豆生长时段分别为2.82±0.28和3.50±0.52μmol.m-2.s-1。冬小麦生长时段免耕与翻耕田土壤呼吸无显著差异,但大豆生长时段二者存在显著差异(P<0.05),差异最明显的阶段在大豆开花期(7月下旬-8月中旬)。利用温度影响函数(指数函数)和湿度影响函数(二次函数)耦合的模拟模型进行土壤呼吸与土壤温度和湿度的回归分析,得出免耕条件下土壤温度和湿度可以共同解释25.3%的土壤呼吸变异(R2=0.253,P<0.05),翻耕条件下二者可以共同解释44.0%的土壤呼吸变异(R2=0.440,P<0.01)。可见,一方面,耕作措施对土壤呼吸的影响因种植作物而异,与翻耕相比,免耕显著降低了大豆田土壤呼吸,但对冬小麦田无显著影响;另一方面,免耕下土壤温度和湿度对土壤呼吸的影响比翻耕要小。  相似文献   

14.
玉米-小麦一年两熟保护性耕作体系试验研究   总被引:46,自引:18,他引:46  
采用将夏玉米、冬小麦两季作物作为整体来研究适合华北一年两熟地区保护性耕作技术体系,确定了耕作和覆盖两个因素,包括免耕、深松、耙地、翻耕4种耕作方法,以及100%秸秆覆盖,50%秸秆覆盖和0覆盖3种秸秆覆盖水平。筛选设计了8种保护性耕作和2种传统翻耕共10种体系的试验方案。试验中测定了土壤含水量、容重、地温等参数和根系、产量等作物指标。试验结果表明,我国华北地区实施保护性耕作有利于节约用水,提高水分利用效率,增加作物产量。试验得出最适合的两种保护性耕作体系是:玉米-小麦全程免耕100%秸秆覆盖体系、玉米深松100%秸秆覆盖+小麦免耕100%秸秆覆盖体系。  相似文献   

15.
为探讨保护性耕作和秸秆还田有机结合对春玉米休闲期蓄水保墒效果、生育期土壤水分时空变化、贮水量季节变化、产量及水分利用效率的影响,设置不同耕作方式(免耕、深松、翻耕)结合秸秆还田(100%秸秆还田、秸秆不还田)6个处理组合,2016-2018年在山西晋中连续2年进行定位试验研究。结果表明:(1)春玉米冬闲期不同耕作处理下土壤贮水量差异显著,且随着时间推移贮水量都有降低趋势,免耕和深松处理分别较翻耕土壤贮水量平均增加10.4,9.3 mm。在玉米的整个生育时期,免耕和深松处理土壤贮水量分别比翻耕提高4.8%,1.2%。(2)平均2年土壤含水量大小顺序为免耕>深松>翻耕,各处理平均土壤含水量分别为23.0%,21.8%,21.5%。丰水年不同耕作方式土壤含水量垂直变化在各生育时期差异较大,干旱年其变化的差异较小。(3)免耕与100%秸秆还田组合下玉米产量和水分利用效率最高,2年平均产量和WUE(水分利用效率)分别为12 679.9 kg/hm2和25.8 kg/(hm2·mm),翻耕与100%秸秆还田处理组合最低。无论是否秸秆还田,免耕和深松处理在春玉米冬闲期土壤蓄水保墒效果、生育期土壤水分状况、产量与水分利用效率均优于翻耕处理;在秸秆还田下免耕和深松耕作方式对玉米田水分的集蓄保用有良好的效果,以免耕秸秆还田效果最佳,可在晋中地区春玉米生产中推广应用。  相似文献   

16.
Impacts of periodic tillage on soil C stocks: A synthesis   总被引:1,自引:1,他引:1  
Long-term loss of soil C stocks under conventional tillage and accrual of soil C following adoption of no-tillage have been well documented. No-tillage use is spreading, but it is common to occasionally till within a no-till regime or to regularly alternate between till and no-till practices within a rotation of different crops. Short-term studies indicate that substantial amounts of C can be lost from the soil immediately following a tillage event, but there are few field studies that have investigated the impact of infrequent tillage on soil C stocks. How much of the C sequestered under no-tillage is likely to be lost if the soil is tilled? What are the longer-term impacts of continued infrequent no-tillage? If producers are to be compensated for sequestering C in soil following adoption of conservation tillage practices, the impacts of infrequent tillage need to be quantified. A few studies have examined the short-term impacts of tillage on soil C and several have investigated the impacts of adoption of continuous no-tillage. We present: (1) results from a modeling study carried out to address these questions more broadly than the published literature allows, (2) a review of the literature examining the short-term impacts of tillage on soil C, (3) a review of published studies on the physical impacts of tillage and (4) a synthesis of these components to assess how infrequent tillage impacts soil C stocks and how changes in tillage frequency could impact soil C stocks and C sequestration. Results indicate that soil C declines significantly following even one tillage event (1–11% of soil C lost). Longer-term losses increase as frequency of tillage increases. Model analyses indicate that cultivating and ripping are less disruptive than moldboard plowing, and soil C for those treatments average just 6% less than continuous NT compared to 27% less for CT. Most (80%) of the soil C gains of NT can be realized with NT coupled with biannual cultivating or ripping.  相似文献   

17.
Soil organic matter has recently been implicated as an important sink for atmospheric carbon dioxide (CO2). However, the relative impacts of various agricultural management practices on soil organic matter dynamics and, therefore, C sequestration at spatial scales larger than a single plot or times longer than the typical three year experiment have rarely been reported. Results of maintaining agricultural management practices in the forest-derived soils of the eastern Corn (Zea mays L.) Belt states of Kentucky, Michigan, Ohio and Pennsylvania (USA) were studied. We found annual organic C input and tillage intensity were the most important factors in affecting C sequestration. The impact of rotation on C sequestration was primarily related to the way it altered annual total C inputs. The removal of above-ground plant biomass and use of cover crops were of lesser importance. The most rapid changes in soil organic matter content occurred during the first five years after a management practice was imposed with slower changes occurring thereafter. Certain management practices, e.g. no-tillage (NT), increased the soil's ability to sequester atmospheric CO2. The impact of this sequestration will be significant only when these practices are used extensively on a large percentage of cropland and when the C-building practices are maintained. Any soil C sequestered will be rapidly mineralized to CO2 if the soil organic matter building practices are not maintained.  相似文献   

18.
Numerous investigators of tillage system impacts on soil organic carbon (OC) or total nitrogen (N) have limited their soil sampling to depths either at or just below the deepest tillage treatment in their experiments. This has resulted in an over-emphasis on OC and N changes in the near-surface zones and limited knowledge of crop and tillage system impacts below the maximum depth of soil disturbance by tillage implements. The objective of this study was to assess impacts of long-term (28 years) tillage and crop rotation on OC and N content and depth distribution together with bulk density and pH on a dark-colored Chalmers silty clay loam in Indiana. Soil samples were taken to 1 m depth in six depth increments from moldboard plow and no-till treatments in continuous corn and soybean–corn rotation. Rotation systems had little impact on the measured soil properties; OC content under continuous corn was not superior to the soybean–corn rotation in either no-till or moldboard plow systems. The increase in OC (on a mass per unit area basis) with no-till relative to moldboard plow averaged 23 t ha−1 to a constant 30 cm sampling depth, but only 10 t ha−1 to a constant 1.0 m sampling depth. Similarly, the increase in N with no-till was 1.9 t ha−1 to a constant 30 cm sampling depth, but only 1.4 t ha−1 to a constant 1.0 m sampling depth. Tillage treatments also had significant effects on soil bulk density and pH. Distribution of OC and N with soil depth differed dramatically under the different tillage systems. While no-till clearly resulted in more OC and N accumulation in the surface 15 cm than moldboard plow, the relative no-till advantage declined sharply with depth. Indeed, moldboard plowing resulted in substantially more OC and N, relative to no-till, in the 30–50 cm depth interval despite moldboard plowing consistently to less than a 25 cm depth. Our results suggest that conclusions about OC or N gains under long-term no-till are highly dependent on sampling depth and, therefore, tillage comparisons should be based on samples taken well beyond the deepest tillage depth.  相似文献   

19.
Quality of agricultural soils is largely a function of soil organic matter. Tillage and crop management impact soil organic matter dynamics by modification of the soil environment and quantity and quality of C input. We investigated changes in pools and fluxes of soil organic C (SOC) during the ninth and tenth year of cropping with various intensities under conventional disk-and-bed tillage (CT) and no tillage (NT). Soil organic C to a depth of 0.2 m increased with cropping intensity as a result of greater C input and was 10% to 30% greater under NT than under CT. Sequestration of crop-derived C input into SOC was 22±2% under NT and 9±4% under CT (mean of cropping intensities ± standard deviation of cropping systems). Greater sequestration of SOC under NT was due to a lower rate of in situ soil CO2 evolution than under CT (0.22±0.03 vs. 0.27±0.06 g CO2–C g−1 SOC yr−1). Despite a similar labile pool of SOC under NT than under CT (1.1±0.1 vs. 1.0±0.1 g mineralizable C kg−1 SOC d−1), the ratio of in situ to potential CO2 evolution was less under NT (0.56±0.03) than under CT (0.73±0.08), suggesting strong environmental controls on SOC turnover, such as temperature, moisture, and residue placement. Both increased C sequestration and a greater labile SOC pool were achieved in this low-SOC soil using NT and high-intensity cropping.  相似文献   

20.
[目的]探明不同耕作模式对以生土为构建材料的新增耕地的改良效应,为该类土地的高产高效利用提供科学依据。[方法]于2017年6—9月分别在免耕、深松、翻耕3种耕作处理模式下的玉米地开展定位监测试验,分析耕作模式对土壤紧实度、养分含量以及作物产量的影响。[结果] 0—20 cm土层紧实度在免耕模式下最低,分别较深松和翻耕低约37.49和38.48 kPa/cm~2,且各模式下0—20 cm土层均呈分层紧实的状态。玉米出苗期土壤紧实度最小,喇叭口期紧实度最高。0—40 cm土层有机质、全氮和有效磷含量在深松模式下均最高,分别为免耕的1.20,1.22,1.36倍,是翻耕的1.18,1.08,1.34倍。深松和翻耕模式下的速效钾含量相近,均为免耕的1.09倍。从出苗期到灌浆期,有机质和全氮含量增加,有效磷和速效钾含量减小。深松耕作模式下玉米产量最高,是免耕和翻耕条件下的1.30,1.19倍。[结论]深松耕作模式土壤紧实度适中,能有效增加土壤养分含量,提高作物产量,是新增耕地最理想的耕作改良方式。  相似文献   

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