Effect of the number of tractor passes on soil rut depth and compaction in two tillage regimes

The initially high level of soil compaction in some direct sowing systems might suggest that the impact of subsequent traffic would be minimal, but data have not been consistent. In the other hand on freshly tilled soils, traffic causes significant increments in soil compaction. The aim of this paper was to quantify the interaction of the soil cone index and rut depth induced by traffic of two different weight tractors in two tillage regimes: (a) soil with 10 years under direct sowing system and (b) soil historically worked in conventional tillage system. Treatments included five different traffic frequencies (0, 1, 3, 5 and 10 passes repeatedly on the same track). The work was performed in the South of the Rolling Pampa region, Buenos Aires State, Argentina at 34°55′S, 57°57′W. Variables measured were (1) cone index in the 0–600 mm depth profile and (2) rut depth. Tyre sizes and rut depth/tyre width ratio are particularly important respect to compaction produced in the soil for different number of passes. Until five passes of tractor (2WD), ground pressure is responsible of the topsoil compaction. Until five passes the tyre with low rut depth/tyre width ratio reduced topsoil compaction. Finally, the farmer should pay attention to the axle load, the tyre size and the soil water content at the traffic moment.     

Wheel traffic impact on soil conditions as influenced by tillage system in Central Anatolia

The increased limiting effects of soil compaction on Central Anatolian soils in the recent years demonstrate the need for a detailed analysis of tillage system impacts. This study was undertaken to ascertain the effects of seven different tillage systems and subsequent wheel traffic on the physical and mechanical properties of typical Central Anatolian medium textured clay loam soil (Cambisol), south of Ankara, Turkey. Both tillage and field traffic influenced soil bulk density, porosity, air voids and strength significantly except the insignificant effect of traffic on moisture content. Traffic affected the soil properties mostly down to 20 cm. However, no excessive compaction was detected in 0–20 cm soil depth. The increases of bulk density following wheel traffic varied between 10–20% at 0–5 cm and 6–12% at 10–15 cm depth. In additions, traffic increased the penetration resistance by 30–74% at 0–10 cm and 7–33% at 10–20 cm. Less wheel traffic-induced effects were found on chisel tilled plots, compared to ploughed plots. Soil stress during wheel passage was highly correlated with soil strength. Also, both tillage and traffic-induced differences were observed in mean soil aggregate sizes, especially for mouldboard ploughed plots. The obtained data imply that chisel+cultivator-tooth harrow combination provides more desirable soil conditions for resisting further soil compaction.     

Soil compaction produced by tractor with radial and cross-ply tyres in two tillage regimes

The aim of this paper was to quantify soil compaction induced by tractor traffic on two tillage regimes: conventional tillage and direct drilling. Traffic was simulated with one pass of a conventional 2WD tractor, using four configurations of cross-ply rear tyres: 18.4–34, 23.1–30, 18.4–38 and 24.5–32, and four configurations of radial tyres 18.4R34, 23.1R 30, 18.4R 38 and 24.5R 32, with two ballast conditions used in each configuration. The experiment was conducted in the east of the Rolling Pampa region, Buenos Aires State, Argentina at 34°25′S, 59°15′W; altitude 22 m above sea level. Rut depth after traffic and soil bulk density and cone index in a 0–450-mm profile were measured before and after traffic. Considering topsoil level, in two tillage regimes, all treatments induced significant values of soil compaction as compared to the control plot without traffic. Subsoil compaction increased as total axle load increased and was independent of ground pressure. For the same tyre configuration, radial tyre caused less soil compaction than the cross-ply.     

绿肥压青粉垄保护性耕作对土壤水分入渗及其后延效应的影响

研究绿肥压青下粉垄耕作稻田土壤水分入渗规律对完善稻田保护性耕作体系具有重要意义。2016-2017年,在广西农业科学院试验田设置粉垄保护性耕作与单免保护性耕作两种耕作模式,并设不施肥、常规施肥、单倍绿肥压青和双倍绿肥压青4种施肥处理,然后分别于早稻、晚稻收获后用土壤紧实度仪及单环入渗法测量稻田土壤紧实度及稳定入渗速率,并于晚稻水稻收获后用环刀法测定土壤容重,以了解绿肥压青下粉垄保护性耕作对当季稻田土壤入渗的影响,并就其对后季稻田的后延效应影响进行研究。结果表明,绿肥压青下粉垄保护性耕作对当季和后季稻田0-15cm土壤紧实度的影响不明显,但是可以显著降低15-30cm土壤紧实度。同时显著降低了当季及后季土壤表层及耕层的稳定入渗率,使土壤入渗能力降低,提高了土壤容重,降低了土壤孔隙度,使土壤密实。绿肥压青下粉垄保护性耕作可显著降低后季稻田土壤稳定入渗率和紧实度,对土壤结构及水分入渗的后延效应明显。     

Remediation of subsoil compaction and compaction effects on corn N availability by deep tillage and application of poultry manure in a sandy-textured soil

Subsoil compaction may reduce the availability and uptake of water and plant nutrients thereby lowering crop yields. Among the management options for remediating subsoil compaction are deep tillage and the selection of crop rotations with deep-rooted crops, but little is known of the effects of applications of organic amendments on subsoil compaction. The objectives of this study were to determine the effects of subsoil compaction on corn yield and N availability in a sandy-textured soil and to evaluate the use of deep tillage and surface applications of poultry manure to remediate subsoil compaction. A field experiment planted to corn (Zea mays L.) was conducted from 2000 to 2001 on a Reelfoot fine sandy loam (fine-silty, mixed thermic Aquic Argiudolls) formed in silty alluvium located in southeast Missouri near the Mississippi River. Treatments were arranged in a factorial design with three levels of subsoil compaction and subsoiling and four rates (averaging 0, 6, 11 and 18 Mg ha⁻¹) of poultry manure. Subsoil tillage to a depth of 30 cm had multiple effects, including overcoming a natural or tillage-induced dense layer or pan and increasing volumetric soil water content and crop N uptake, especially in the 2001 cropping year with low early season precipitation. N recovery efficiency (NRE) was significantly higher in the subsoil treatment compared to the highest compaction treatment in 2001. No significant interactions between manure rates and compaction and subsoiling treatments were observed for corn grain and silage yields, N uptake and NRE. Average increases in corn grain yields over all manure rates due to subsoil tillage of compacted soil were 2002 kg ha⁻¹ in 2000 and 3504 kg ha⁻¹ in 2001. Application of poultry manure had a consistent positive effect on increasing grain yields and N uptake in 2000 and 2001 but did not significantly alter measured soil physical properties. The results of this study suggest that deep tillage and applications of organic amendments are management tools that may overcome restrictions in both N and soil water availability due to subsoil compaction in sandy-textured soils.     

The evaluation of agricultural machines field trafficking intensity for different soil tillage technologies

Fields trafficking by wheeled farm machines results often in unfavourable soil compaction. In order to monitor trafficking intensity under different soil tillage technologies, every machine was equipped with a DGPS signal receiver before the entrance into the field under conventional, minimum and zero tillage technology. Positioning data was automatically logged every 2 s and the dimensions of tyres (mainly width) and wheel spacing were marked for every machine. Trajectories of farm machines trafficking and wheel tracks covering 1 ha area are shown for different technologies evaluated during one growing season. The results document that up to 95.3% of the total field area was run-over with a machine at least once during a year, when using conventional tillage. Up to 72.8% or 55.7% of the total field area was run-over when using minimum tillage and direct seeding, respectively. It was calculated that 145.6% of covered area can be run-over repeatedly for conventional tillage, 44.8% for minimum tillage and 18.4% only for direct seeding.     

Wheel traffic and tillage effects on runoff and crop yield

Traffic and tillage effects on runoff, soil water and crop production under rainfall were investigated over a period of 6 years on a heavy clay vertosols (vertisols) in Queensland, Australia. A split plot design was used to isolate traffic effects, while the cropping program and treatments were broadly representative of extensive grain production practice in the northern grain region of Australia. Treatments subject to zero tillage and stubble mulch tillage each comprised pairs of 90 m² plots, from which runoff was recorded. A 3 m wide controlled traffic system allowed one of each pair to be maintained as a non-wheeled plot, while the complete surface area of the other received a single annual wheeling treatment from a working 100 kW tractor.

Mean annual runoff from controlled traffic plots was 81 mm (36.3%) smaller than that from wheeled plots, while runoff from zero tillage was reduced by 31 mm (15.7%). Traffic and tillage effects appeared to be cumulative, so the mean annual runoff from controlled traffic and zero tillage plots, representing best practice, was 112 mm (47.2%) less than that from wheeled stubble mulch plots, representing conventional cropping practice. Rainfall infiltration into controlled traffic zero tillage soil was thus 12.0% greater than into wheeled stubble mulched soil. Rainfall/runoff hydrographs show that wheeling produced a large and consistent increase in runoff, whereas tillage produced a smaller increase. Treatment effects were greater on dry soil, but were still present in large and intense rainfall events on wet soil.

Plant available water capacity (PAWC) in the 0–500 mm zone increased by 10 mm (11.5%) and mean grain yields increased by 337 kg/ha (9.4%) in controlled traffic plots, compared with wheeled plots. Mean grain yield of zero tillage was 2–8% greater than that of stubble mulch plots for all crops except for winter wheat in 1994 and 1998. Increased infiltration and plant available water were probably responsible for increased mean grain yields of 497 kg/ha (14.5%) in controlled traffic zero tillage, compared with wheeled stubble mulch treatments. Dissipation of tractive and tillage energy in the soil is the apparent mechanism of deleterious effects on the soils ability to support productive cropping in this environment. Controlled traffic and conservation tillage farming systems appear to be a practicable solution.     

Phosphorus: a limiting factor for restoration of soil fertility in a newly reclaimed coal mined site in Xuzhou,China

Massive exploration of coal in China has resulted in a significant loss of agricultural land throughout the country. To relieve this increasing shortage, reclamation of abandoned coal mine areas has been prioritized. This study aims to identify the limiting factor(s) affecting the restoration of the soil fertility in a coal-mined area. The work was carried out in a typical area, the Xuzhou coalfield in northern Jiangsu province. Soil fertility parameters showed that the tested soil was very poor, especially in phosphorus. By using soil-pot experiments, it was demonstrated that application of nitrogen and potassium, but without phosphorus fertilizers, did not result in increase in crop yields, while the rational application of organic and inorganic fertilizers improves soil fertility significantly as shown by yields of rice, wheat and green vegetables. By comparing the effectiveness of different treatments, soil phosphorus was identified as the limiting factor in restoring the fertility of this newly reclaimed land. Study on the soil phosphorus speciation further revealed that Ca₂-P was the main source of variation in the supplying capacity of soil phosphorus, whereas Ca₁₀-P remained unchanged. © 1998 John Wiley & Sons, Ltd.     

Evaluation of bulk density of Albaqualf soil under different tillage systems using the volumetric ring and computerized tomography methods

The volumetric ring and the computerized tomography (CT) techniques were applied to study soil bulk density, in order to understand the compaction of an Albaqualf soil (Planosol) of the Rio Grande do Sul State, Southern Brazil (latitude 31°52′00″S and Longitude 52°21′24″W). Among six different tillage systems and crop rotations the greatest soil bulk density was measured for the continuous irrigated rice crop system and the lowest for the no-tillage treatment under rye grass straw. The CT method enabled the measurement of bulk density variations in the soil profile and indicated critical zones not observed by the volumetric ring method that measures only the mean sample soil bulk densities. A meaningful correlation between soil bulk densities measured by both methods was found, although the CT method presented more reliable results in comparison to the volumetric ring method. A 3% variation in bulk density was observed due to method intrinsic errors, probably also correlated to different samples sizes.     

Effects of tillage method on soil physical properties, infiltration and yield in an olive orchard

The long-term effects of two different tillage systems, conventional (CT) and no tillage (NT), were studied in an olive orchard in Santaella (Southern Spain) for 15 years. In both tillage systems, two distinct zones developed in the orchard in relation to soil physical properties; one underneath the tree canopy, and the other in the rows between trees. Surface soil organic matter content, bulk density, cone index, macroscopic capillary length and hydraulic conductivity showed significant differences between tillage systems and positions. After 15 years, the NT treatment achieved greater bulk density and cone index values than CT. This compaction reduced the infiltration rate of NT soil with respect to CT, particularly in the rows between trees. Despite that reduction, the NT soil retained a moderate infiltration potential. That may be explained by the high infiltration rates and macroporosity of the zone beneath the tree, the temporary effects of tillage on infiltration and probably by the self-repair of soil structure in the Vertisol studied. Yield was not affected by tillage except in one year with very low precipitation, where NT significantly yielded more than CT. The reduction in infiltration in NT must have been compensated by unknown factors that improve the tree water supply in drought years.     

Vulnerability of Bavarian silty loam soil to compaction under heavy wheel traffic: impacts of tillage method and soil water content

Soil compaction caused by traffic of heavy vehicles and machinery has become a problem of world-wide concern. The aims of this study were to evaluate and compare the changes in bulk density, soil strength, porosity, saturated hydraulic conductivity and air permeability during sugar beet (Beta vulgaris L.) harvesting on a typical Bavarian soil (Regosol) as well as to assess the most appropriate variable factors that fit with the effective controlling of subsequent compaction. The field experiments, measurements and laboratory testing were carried out in Freising, Germany. Two tillage systems (conventional plough tillage and reduced chisel tillage) were used in the experiments. The soil water contents were adjusted to 0.17 g g⁻¹ (w₁), 0.27 g g⁻¹ (w₂) and 0.35 g g⁻¹ (w₃).Taking the increase in bulk density, the decrease in air permeability and reduction of wide coarse pore size porosity (−6 kPa) into account, it seems that CT (ploughing to a depth of 0.25 m followed by two passes of rotary harrow to a depth 0.05 m) of plots were compacted to a depth of at least 0.25 m and at most 0.40 m in high soil water (w₃) conditions. The trends were similar for “CT w₁” (low soil water content) plots. However, it seems that “CT w₁” plots were less affected than “CT w₃” plots with regard to bulk density increases under partial load. In contrast, diminishments of wide coarse pores (−6 kPa) and narrow (tight) coarse pores (−30 kPa) were significantly higher in “CT w₁” plots down to 0.4 m. Among CT plots, the best physical properties were obtained at medium soil water (w₂) content. No significant increase in bulk density and no significant decrease in coarse pore size porosity and total porosity below 0.2 m were observed at medium soil water content. The soil water content seemed to be the most decisive factor.It is likely that, CS (chiselling to a depth of 0.13 m followed by two passes of rotary harrow to a depth 0.05 m) plots were less affected by traffic treatments than CT plots. Considering the proportion of coarse pore size porosity (structural porosity) and total porosity, no compaction effects below 0.3 m were found. Medium soil water content (w₂) provides better soil conditions after traffic with regard to wide coarse pore size porosity (−6 kPa), air permeability (at 6 and 30 kPa water suction), total porosity and bulk density. Proportion of wide coarse pores, air permeability and bulk density seems to be suitable parameters to detect soil compaction under the conditions tested.     

玉米秸秆全量深翻还田对高产田土壤结构的影响

为达到玉米生产耕层最适深度(22 cm)和耕层最适土壤容重(1.1~1.3 g×cm~(-3)),解决内蒙古平原灌区耕层浅、犁底层坚硬且厚的农田土壤结构问题,分别选用连续1、2、3、4年秸秆深翻还田定位试验地,秋收后玉米秸秆全量粉碎深翻还田,秸秆年均还田量为20 034.97 kg×hm-2,形成秸秆深翻还田1~4年的4个试验处理(SF1-SF4),以不深翻秸秆还田的处理为对照(CK),研究土壤容重、土壤坚实度、土壤团聚体及其稳定性、土壤肥力及p H随不同年限秸秆深翻还田的变化规律。结果表明:1)SF1-SF4处理0~40 cm土层,土壤容重和土壤坚实度比CK显著减小。2)0~20 cm土层,SF4处理0.25 mm团聚体比例(R0.25)、几何平均直径(GWD)和平均重量直径(MWD)均比CK显著减小;SF1处理土壤团聚体破坏率(PAD)比CK显著降低9.56%,不稳定指数(SWA)随深翻年限增加而显著降低;团聚体分形维数SF4比CK显著增大7.30%。3)20~40 cm土层,SF1和SF2处理R0.25比CK分别显著增加13.69%和17.83%;SF2处理的MWD和GWD分别比CK显著增加23.92%和53.38%;SF1-SF4处理的PAD比CK显著降低,且SF2显著高于SF1和SF3;而SF1-SF4的SWA比CK显著增加,且随秸秆深翻年限的增加呈逐渐升高趋势;团聚体分形维数SF2比CK显著降低7.39%。4)土壤有机质含量SF1-SF4比CK显著增加,且SF2-SF4处理显著大于SF1;速效氮、速效磷和速效钾SF1-SF4比CK显著增加,土壤p H SF3、SF4比CK显著降低。总之,深翻秸秆还田1~4年对0~40 cm土层土壤影响显著;深翻秸秆还田2年适合土壤犁底层结构的改良,深翻秸秆还田3年和4年适合土壤耕层结构的改良。玉米秸秆全量深翻还田既能达到耕作土壤的目的,同时也增加了土壤有机质,降低土壤团聚体破坏率和土壤水稳性团聚体的不稳定系数,利于培肥耕层土壤。     

Assessing the agronomic benefit of noninversion tillage for improving soil structure following winter grazing of cattle and sheep

Severe treading damage to soils often occurs when cattle and sheep graze standing forage crops during winter. Soil recovery is a long process that may take several months if not years. Noninversion tillage can speed up the recovery process by improving drainage and air diffusion. This research assessed the ongoing benefit of noninversion tillage for improving soil structure relative to non‐tillage. This assessment was made following a land‐use transition from winter forage cropping to re‐establishment of seasonal pasture that was rotationally grazed by cattle or sheep. Prior to commencement of this study, the research site had poor soil structure due to four consecutive years of cattle and sheep grazing of winter forage crops [macroporosity (0–100 mm) <0.075 and 0.113 m³/m³ under cattle and sheep, respectively]. Tillage was effective in increasing soil macroporosity to ca. 0.175 m³/m³ under both grazing classes, which was significantly higher than nontilled soils (ca. 0.140 m³/m³, 0–100 mm depth). Improvements gained from tillage generally did not persist longer than 18 months. Average annual pasture production in tilled plots was 22.1 and 20.9 tons of dry matter per hectare (t DM/ha) for respective cattle‐ and sheep‐grazed plots, while in the nontilled plots, it was 19.1 and 18.6 t DM/ha, respectively. Results indicate noninversion tillage can provide an immediate increase in the porosity of compacted soils and improve pasture growth. However, processes involved in the formation of resilient soil aggregates are curtailed if subsequent grazing events coincide with high moisture content that causes recompaction.     

Least limiting water range and crop yields as affected by crop rotations and tillage

Crop rotation and the maintenance of plant residues over the soil can increase soil water storage capacity. Root access to water and nutrients depends on soil physical characteristics that may be expressed in the Least Limiting Water Range (LLWR) concept. In this work, the effects of crop rotation and chiselling on the soil LLWR to a depth of 0.1 m and crop yields under no‐till were studied on a tropical Alfisol in São Paulo state, Brazil, for 3 yr. Soybean and corn were grown in the summer in rotation with pearl millet (Pennisetum glaucum, Linneu, cv. ADR 300), grain sorghum (Sorghum bicolor, L., Moench), congo grass (Brachiaria ruziziensis, Germain et Evrard) and castor bean (Ricinus comunis, Linneu) during fall/winter and spring, under no‐till or chiselling. The LLWR was determined right after the desiccation of the cover crops and before soybean planting. Soil physico‐hydraulic conditions were improved in the uppermost soil layers by crop rotations under zero tillage, without initial chiselling, from the second year and on, resulting in soil quality similar to that obtained with chiselling. In seasons without severe water shortage, crop yields were not limited by soil compaction, however, in a drier season, the rotation with congo grass alone or intercropped with castor resulted in the greatest cover crop dry matter yield. Soybean yields did not respond to modifications in the LLWR.     

基于Hydrus-1D的黄河泥沙充填复垦土壤夹层结构优化

中国东部矿区煤粮复合区面积大,因采煤沉陷积水,导致大面积的耕地破坏,采煤沉陷地复垦成为中国亟待解决的问题,黄河泥沙夹层式充填复垦技术对实现采煤沉陷地复垦具有积极意义.为优化黄河泥沙充填复垦夹层式土壤剖面设计,该研究采用Hydrus-1D模拟分析了在充填复垦土壤总厚度一定的情况下,不同夹层厚度、位置和数量对重构土壤入渗和...     

土壤翻耕对坡地水分转化与产流产沙特征的影响

坡耕地严重的水土流失是导致黄土高原土壤质量退化与生态环境恶化的重要原因。采用模拟降雨的方法研究了翻耕与压实对休闲黄绵土坡耕地水分转化与产流产沙特征的影响。结果表明，(1)与压实相比，土壤翻耕导致入渗率下降40%～60%，产流强度增加1至3倍，降雨向土壤水分的转化率降低50％以上。(2)翻耕条件下流失径流的平均含沙量增加近70％，坡地产沙量增加3倍，径流流失量增加1倍，因此对坡地实行免耕休闲可以有效减轻水土流失、遏制坡地土壤质量退化的态势。(3)降雨过程中，随着产流时间的延长，坡地产沙量呈加速增加的趋势，而且增加速度显著快于坡面径流，因此采取适当措施延长初始产流时间、减少产流量以及提高降雨向土壤水分的转化率均可有效减少坡地土壤流失量。     

翻耕与压实对坡地土壤溶质迁移过程的影响

采用田间模拟降雨试验方法,研究地表翻耕与压实处理对坡地产流产沙及溶质迁移特征的影响。结果表明：与压实处理比较,翻耕坡地初始产流时间延长近3倍,降雨向土壤水转化率提高10％以上,产沙量增加67％;翻耕处理明显降低溶解态磷（DP）和泥沙浸提态磷（SEP）的流失量,但磷素流失形态（DP与SEP的比值）并未显著变化,始终以颗粒态形式流失为主;翻耕处理显著改变了溴的流失形态,溶解态溴（Br）与泥沙浸提态溴（SBr）流失量比值减少了72％;翻耕处理提高了溴（或硝态氮）的淋失概率,增大污染地下水体的潜在危险。因此,合理配置坡地免耕或翻耕措施,有机结合其他农艺耕作措施,对减少坡地水土及养分流失具有重要实践意义。     

Axle load and tillage effects on the shrinkage characteristics of a Mollic Ochraqualf in northwest Ohio

Cracking due to soil shrinkage is a complex process whose effect on soil properties, crop growth and water quality are not adequately understood. The intensity of cracking depends on soil characteristics and management. The effect of three axle loads and three tillage methods on shrinkage characteristics and cracking behavior were studied for a heavy-textured lake bed soil in northwest Ohio. The three axle load treatments were 0, 10 and 20 Mg, and the three tillage treatments were no till (NT), chisel plowing (CP) and moldboard plowing (MP). Cracking area increased from 1.75% in July to 12.27% in September, was maximum in the NT treatment, and increased with increase in axle load. The no till and 30 Mg axle load caused significantly higher cracking than other axle load and tillage treatment combinations. Shrinkage of compressed soil cores under laboratory conditions showed that a bulk density of 1.5 Mg/m³ had the lowest total shrinkage volume. A combination of no till and heavy axle load increased the cracking area and accentuated adverse effects on soil structure.     

中国东部丘陵矿区复垦土地利用结构优化研究

该文以受华丰矿开采影响的小河西村为例,在SPSS软件的支持下,利用复垦前后不同土地利用类型的生态足迹、景观多样性、产值等指标,运用多目标规划法对我国东部丘陵矿区复垦土地利用结构进行了优化分析。结果显示,利用生态足迹法、景观多样性指数和多目标规划得出的复垦土地结构与复垦前比,不仅经济效益明显提高,生态赤字明显降低,生态环境明显改善,而且景观多样性指数增加,能促进生态、经济和社会目标的实现,也必将缓和长期以来形成的矿山与周边农民的矛盾,并能调动矿山和村集体复垦积极性,推动矿区和周边农村和谐发展。     

不同覆盖方式对新复垦区土壤水热及春玉米产量的影响

随着城市化进程的加速发展,我国净耕地面积持续减少,合理开发利用潜在土地资源,对于保障我国粮食安全具有重要意义。为了探讨不同覆盖耕作方式对新复垦区土壤水热及作物生长的影响,通过2018年和2019年连续两年田间试验,研究了传统耕作(CK)、地膜覆盖(FM)、秸秆深埋(BS)和秸秆深埋+地膜覆盖(F+S) 4种处理对土壤水分、温度和春玉米生长及产量的影响。结果表明:2018年,F+S、BS、FM处理玉米生育期内0～20cm及20～40 cm土层平均土壤含水率分别较CK增加24.4%、16.5%、12.6%及9.1%、3.2%、3.7%。2018年玉米苗期, 0～100 cm土壤蓄水量表现为FMF+SCKBS,明显表现为有覆膜处理(F+S和FM)的土壤蓄水量高于不覆膜处理(BS和CK)。2019年玉米苗期,土壤蓄水量则表现为F+SBSFMCK。与CK相比,春玉米全生育期不同覆盖耕作处理条件下各土层(5～25 cm)土壤温度均有所提高,具体表现为F+SFMBSCK,各处理土壤温度随土层深度表现为降低趋势。以表层5 cm土壤温度增幅最大,覆盖耕作处理的增温效应在全生育期表现为前期明显而后期弱化。各处理株高变化趋势一致,在播种后70d左右达到峰值,随后出现小幅度下降并最终保持稳定。试验期,株高和叶面积均表现为地表有覆膜的处理高于未覆膜处理(P0.05)。2018年, F+S、BS和FM处理玉米产量均显著高于CK(P0.05),2018年和2019年,各处理产量分别较CK增加17.0%、13.5%、6.6%和30.5%、23.9%、3.8%。产量构成逐步回归分析结果表明,穗长对产量的影响最大,产量与穗行数和百粒重呈正相关关系。秸秆深埋+地膜覆盖处理(F+S)可以综合发挥二者优势,有效调节土壤水热状况,改善土壤环境,促进作物生长发育,从而获得较高的产量,可作为新复垦区春玉米适宜的种植管理方式。