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1.
A plastic-covered ridge and furrow rainfall harvesting (PRFRH) system combined with mulches was designed to increase water availability to crops for improving and stabilizing agricultural production in the semiarid Loess region of northwest China. The system was built by shaping the soil surface with alternate ridges and furrows along the contour. The plastic-covered ridges served as a rainfall harvesting zone and furrows as a planting zone. Some materials were also used to mulch the furrows to increase the effectiveness of the harvested water. This system can make better utilization of light rain by harvesting rainwater through the plastic-covered ridge. The field experiment (using corn as an indicator crop) showed that grain yields in the PRFRH system with mulches in 1998 and 1999 were significantly higher than the controls, with an increase of 4010–5297 kg per ha (108–143%). In most treatments, the water use efficiencies (WUE) were in excess of 2.0 kg m−3. The WUE values of corn in this system were 1.9 times greater than the controls in 1998 and 1.4 times greater than the controls in 1999. The plastic-covered ridge led to a yield increase of 3430 kg per ha (92%) in 1998 and of 1126 kg per ha (21%) in 1999 compared with the uncovered ridge. On average, the additional mulches in the furrow brought about a yield increase of 8–25%. Based on the results of this study and other researches, this technique can increase corn grain yield by 60–95% in drought and average years, 70–90% in wet years, and 20–30% in very wet years. The PRFRH system had the potential to increase crop yield and produced greater economic benefit, therefore it could be used in regions dominated by light rainfall of low intensity where crops generally fail due to water stress.  相似文献   

2.
In semi-arid areas, crop growth is greatly limited by water. Amount of available water in soil can be increased by surface mulching and other soil management practices. Field experiments were conducted in 2005 and 2006 at Gaolan, Gansu, China, to determine the influence of ridge and furrow rainfall harvesting system (RFRHS), surface mulching and supplementary irrigation (SI) in various combinations on rainwater harvesting, amount of moisture in soil, water use efficiency (WUE), biomass yield of sweet sorghum (Sorghum bicolour L.) and seed yield of maize (Zea mays L.). In conventional fields without RFRHS, gravel-sand mulching produced higher biomass yield than plastic-mulching or straw-mulching. In plastic-mulched fields, an increasing amount of supplemental irrigation was needed to improve crop yield. There was no effect of RFRHS without plastic-covered ridge on rainwater harvesting when natural precipitation was less than 5 mm per event. This was due to little runoff of rainwater from frequent low precipitation showers, and most of the harvested rainwater gathered at the soil surface is lost to evaporation. In the RFRHS, crop yield and WUE were higher with plastic-covered ridges than bare ridges, and also higher with gravel-sand-mulched furrows than bare furrows in most cases, or straw-mulched furrows in some cases. This was most likely due to decreased evaporation with plastic or gravel-sand mulch. In the RFRHS with plastic-covered ridges and gravel-sand-mulched furrows, application of 30 mm supplemental irrigation produced the highest yield and WUE for sweet sorghum and maize in most cases. In conclusion, the findings suggested the integrated use of RFRHS, mulching and supplementary irrigation to improve rainwater availability for high sustainable crop yield. However, the high additional costs of supplemental irrigation and construction of RFRHS for rainwater harvesting need to be considered before using these practices on a commercial scale.  相似文献   

3.
The ridge and furrow farming of rainfall concentration (RC) system is being promoted to increase water availability to crops for improving and stabilizing agricultural production in the semiarid Loess region of northwest China. In the system, plastic-covered ridges serve as rainfall harvesting zones and furrows serve as planting zones. In recent years, however, the current RC practices are still confined to rural family units for very limited supplemental irrigation purposes. To adopt this system for large-scale use in the semiarid region and bring it into full play, it is necessary to test the befitting rainfall range for RC farming. A field study (using corn as an indicator crop) combined with rainfall simulation was designed to determine the effects of RC practices on soil water content, crop yield and water use efficiency (WUE) under three rainfall levels (230 mm, 340 mm and 440 mm) during the growing seasons of 2006 and 2007. The results indicated that with the rainfalls ranging within 230-440 mm, RC system can increase soil water content in 0-100 cm and temperature conditions in the topsoil (0-10 cm) in furrows by 5-12% and 0.7-1 °C, respectively. The corn seedlings emerged 1-2 days earlier, the developmental stages generally occurred earlier, and the plant height and total dry matter all significantly increased (P < 0.05). In 2006, compared to conventional flat (CF) practice, the grain yield and WUE in the RC system increased by 75.4% and 73.3%, respectively at 230 mm rainfall, and by 36.7% and 40.2%, respectively at 340 mm rainfall, but there was no significant difference between the RC440 and CF440 patterns. In 2007, the grain yield and WUE were 82.8% and 77.4%, respectively higher in the RC230 plots than in the CF230 plots, 43.4% and 43.1%, respectively higher in the RC340 plots than in the CF340 plots, and 11.2% and 9.5%, respectively higher in the RC440 plots than in the CF440 plots. Combining yield and WUE, it could be concluded that the optimal rainfall upper limit for RC system is below 440 mm rainfall in the experiment. In the case of corn, the adoption of RC practice in the 230-440-mm rainfall area will make the system more attractive during the whole growth period and offer a sound opportunity for sustainable farming under semiarid climate.  相似文献   

4.
In the northwestern Loess Plateau of China, low precipitation results in poor crop yields, with a great fluctuation from year to year. The adoption of gravel-sand mulching has shown improvements in the growth of crops such as watermelon. The ridge and furrow rainwater harvest system (RFRHS) has been shown as an easy and efficient way to collect rainwater. A field experiment was conducted from 2007 to 2009 at Gaolan, Lanzhou, Gansu, China, to measure the effects of RFRHS, plastic mulch and gravel-sand mulch combinations on soil temperature, evapotranspiration (ET), water use efficiency (WUE) and watermelon yield. There were eight treatments: (1) flat gravel-sand mulched field, (2) RFRHS with a sand mulched furrow, entire plastic mulch and the ratio 1:1 of ridge and furrow, (3) RFRHS with a sand mulched furrow, entire plastic mulch and the ratio 4:3 of ridge and furrow, (4) RFRHS with a sand mulched furrow, entire plastic mulch and the ratio 5:3 of ridge and furrow, (5) RFRHS with a sand and plastic mulched furrow, bare ridge and the ratio 4:3 of ridge and furrow, (6) RFRHS with an entire plastic mulch and the ratio 4:3 of ridge and furrow, (7) conventional ridge planting with a plastic mulched ridge, and (8) flat gravel-sand mulched field plus 23 mm supplementary irrigation. Soil temperature for RFRHS with a gravel-sand plus plastic mulched furrow was slightly lower than that of flat gravel-sand mulch. The RFRHS caused a significant increase in watermelon yield and WUE. The increase in watermelon yield and WUE was greatly influenced by the ratio of ridge and furrow when RFRHS was combined with gravel-sand mulch. Watermelon yield was highest for the 1:1 ratio, and WUE was highest for the 5:3 and 1:1 ratios of ridge:furrow, and these were significantly greater than that of flat gravel-sand mulch, without or with irrigation. The use of ridge with plastic film mulch increased the beneficial effect of RFRHS on yield. The watermelon yield and WUE for non-plastic-mulched ridge were even lower than that of flat gravel-sand mulch. In summary, the findings suggest that RFRHS with gravel-sand mulched furrow plus plastic film mulch, and 1:1 ratio of ridge:furrow, would facilitate the use of limited rainfall most efficiently in improving watermelon yield, by reducing ET and increasing WUE in this semiarid region.  相似文献   

5.
A rainwater harvesting system on slopes using contour furrows with plastic-covered transverse ridges designed to be used in small rainfall dominated areas of the semiarid loess region of China has been tested from 2001 to 2004. The system consisted of constructing contour furrows on the loess slope at a distance of 5 m with plastic-covered transverse ridges built in the furrows between shrubs of Caragana korshinskii. There were three treatments in the study: (1) plastic-covered ridge with gravel-mulched furrows (T1), (2) plastic-covered ridge with bare furrows (T2), and (3) control (no ridge and no contour furrow) (T3).

The experimental results indicated that runoff from the natural loess slope was small and variable, and only produced from a few rainfall events with high intensity. Runoff efficiency averaged 13.8, 4.5, 1.4, and 0.4% in 2001, 2002, 2003, and 2004, respectively. However, the plastic-covered ridges accumulated runoff from most rainfall events, particularly from the light rains less than 5 mm. So the natural loess slope between the furrows and the plastic-covered ridges in the furrows can complement each other, i.e., the plastic-covered ridges induce runoff from small rainfall to the planted area, and the natural loess slope between the furrows concentrate runoff from heavy rainfall, thus improving rain use efficiency. The total runoff collected from both the natural loess slope and the plastic-covered ridges to the planted area in the furrows was 231, 143, 88, and 59 mm in 2001, 2002, 2003, and 2004, respectively. Soil moisture storage in the 200-cm deep soil layer was obviously higher for T1 and T2 than for T3, and C. korshinskii showed a significant improvement in growth for the T1 and T2 treatments. Therefore the combination of contour furrows and plastic-covered ridges as rainwater harvesting system may have a great potential development in the small rainfall dominated arid regions of China.  相似文献   


6.
为探寻种植方式与灌水模式对糯玉米生长及产量的影响,选择试验区域玉米生产中常用的3种种植方式[DM(全膜双垄宽窄行沟播)、C(全膜双垄等行距沟播)、CK(裸地平作)]和两种灌水模式{I0[播种期(75%~85%)θf、苗期-拔节前期(65%~75%)θf、拔节后期-孕穗期(70%~80%)θf、孕穗期-开花期(70%~80%)θf]和I1[播种期(75%~85%)θf、拔节后期-孕穗期(75%~85%)θf]}进行组合,对不同处理下糯玉米的株高、叶面积指数、籽粒产量及水分利用效率差异进行了研究。结果表明:相同灌水水平下,全膜双垄沟播能够使糯玉米的株高、叶面积指数、籽粒产量及水分利用效率显著提高;宽窄行种植对株高的提高作用不明显,对叶面积指数、籽粒产量及水分利用效率提升效果显著;I0与I1相比对糯玉米株高和叶面积指数提高明显,对产量和水分利用效率提升不明显。因此,全膜双垄宽窄行沟播是本研究条件下最适宜糯玉米生长的种植模式。  相似文献   

7.
The ridge and furrow rainfall harvesting (RFRH) system with mulches is being promoted to increase water availability for crops for higher and stable agricultural production in many areas of the Loess Plateau in northwest China. In the system, plastic-covered ridges serve as rainfall-harvesting zones and stone-, straw- or film-mulched furrows serve as planting zones. To adopt this system more effectively, a field study (using corn as an indicator crop) was conducted to determine the effects of different ridge:furrow ratios and supplemental irrigation on crop yield and water use efficiency (WUE) in the RFRH system with mulches during the growing seasons of 1998 and 1999.The results indicated that the ridge:furrow ratios had a significant effect on crop yield and yield components. The 120:60 cm ridge and furrow (120 cm wide ridge and 60 cm wide furrow) system increased yield by 27.9%, seed weight per head by 14.8%, seed number per head by 7.4% and 1000-seed weight by 4.7%, compared with the 60:60 cm ridge and furrow (60 cm wide ridge and 60 cm wide furrow) system. No differences in WUE were found between the two ratio systems. For corn and winter wheat, the optimum ridge:furrow ratio seems to be 1:1 in the 300-mm rainfall area, 1:2 in the 400-mm rainfall area and 1:4 in the 500-mm rainfall area. The optimum ridge:furrow ratio seems to be 1:3 for millet in the 300-mm rainfall area, although it is unnecessary to adopt RFRH practice in regions with more than 400 mm rainfall. The most effective ridge size for crop production seems 60 cm in the Loess Plateau. Implementing supplemental irrigation in the RFRH system is also a useful way to deal with the temporal problem of moisture deficits. In the case of corn, supplemental irrigation at its critical growth stage can increase both grain yield and WUE by 20%. The combination of in situ RFRH system with supplemental irrigation practice will make the RFRH system more attractive.  相似文献   

8.
垄沟灌溉种植对玉米光合特性及产量的影响   总被引:3,自引:0,他引:3  
通过田间试验,以传统种植模式平作为对照,研究了垄沟灌溉种植系统对玉米相对叶绿素质量浓度(SPAD)、光合特性和产量的影响。结果表明,垄沟种植系统能增加玉米的相对叶绿素质量浓度、光合速率和水分利用效率;垄沟系统种植玉米和对照组的光合速率日变化均呈"单峰型"曲线;60cm垄宽的垄沟种植系统的玉米叶片水分利用效率和产量最高。  相似文献   

9.
为了阐明不同沟向与沟灌方式下作物根区土壤温度的变化规律,通过垄作玉米田不同点位处的根区地温观测,研究了南北沟向和东西沟向下交替隔沟灌溉(AFI)和常规沟灌(CFI)田的地温变化。结果表明,东西沟向时AFI在湿沟、垄位和干沟处0~20cm土温分别高于南北沟向0~4.60、0~5.37、0~6.57℃;同一沟向条件下,AFI的平均土温比CFI提高了0.02~7.00℃,且AFI在非灌水区域的土温比灌水区域高0.23~6.20℃。东西沟向AFI的作物根区土温最高,提高了根区土壤热能,以其通过栽培方式或灌溉方式的改变调节田间光热环境以适应不同作物的生长需求。  相似文献   

10.
垄沟种植模式对玉米种植的过程有着非常高的应用价值,可以直接对玉米的生长与产量产生影响,例如,与传统的种植模式相比较,在玉米的株高、功能叶面积、相对叶绿素含量、干物质量、产量等方面有着显著的提升,促进了玉米植株的健康成长。本文首先介绍了垄沟种植模式的理论基础,了解该模式的工作原理及相对优势。然后结合陕南地区的土地条件与气候条件,选择陕西省渭河流域的三级阶地作为试验地完成相关实验设计。最后,根据垄沟种植模式对玉米生长及产量的影响来分析垄沟种植模式在陕南地区的价值。  相似文献   

11.
【目的】探究夏玉米根系分布、水分利用效率及产量对沟灌种植下不同秸秆覆盖方式的动态响应。【方法】在河套灌区开展不同耕作模式的小区试验,试验设常规垄覆膜沟灌(FM)、垄覆秸秆沟灌(FLJ)、沟覆秸秆沟灌(FGJ)、垄沟覆秸秆沟灌(FLGJ)4个处理。研究了夏玉米各土层的根长密度、作物耗水量、产量及其相关指标,【结果】沟灌种植模式下不同秸秆覆盖方式显著(P<0.05)影响夏玉米根系分布、产量和水分利用效率,通过沟覆秸秆沟灌可改善夏玉米根系分布,提高水分利用效率,达到高产。沟覆秸秆促进了垄上大于40 cm土层根系发育,根长密度较FM处理增加128.1%,显著提高沟里大于20 cm土层根长密度,促进对深层土壤水分养分吸收利用,提高产量。与FM处理相比,FGJ和FLGJ处理的水分利用效率显著提高了51.9%和54.3%,增产9.3%和9.0%,但FGJ处理的收获指数显著高于其他处理(P<0.05),为0.48。【结论】沟灌种植模式下沟覆秸秆FGJ处理改善深层根系分布效果较好,显著提高夏玉米水分利用效率及产量。  相似文献   

12.
为阐明隔沟交替灌溉(AFI)对土壤磷质量分数及其形态的影响,以常规沟灌(CFI)为对照,研究了CFI、AFI二种灌溉方式下垄位、沟位土壤全磷、速效磷和有机磷、无机磷各组分的变化情况。AFI垄位全磷质量分数显著小于CFI,其垄位、沟位速效磷质量分数都分别显著低于CFI的垄位和沟位,分别降低了14.7%、23.1%。AFI...  相似文献   

13.
垄作沟播喷灌技术是集垄作沟播与喷灌技术为一体的节水栽培技术.以不同灌水定额各设4个处理(灌水定额分别为24 mm、30 mm、36 mm、42 mm,灌水5次),以常规覆膜喷灌为对照(灌水定额42 mm,灌水5次).通过测定不同灌水处理下垄作沟播油葵根系生长及分布特征等指标,分析了不同灌水处理对油葵根系纵向、横向生长及...  相似文献   

14.
西北雨养区全膜双垄沟播技术与配套机具研究进展分析   总被引:3,自引:0,他引:3  
全膜双垄沟播技术抗旱增产,在我国西北旱区大面积推广应用,实现与提升其全程机械化作业水平主要包括对覆膜种床构建、膜上播种、残膜回收及种植作物收获技术与配套机具的研究。在分析西北旱区全膜双垄沟播技术应用概况、技术模式和实施效应的基础上,重点阐述了全膜双垄沟相关机械化起垄覆膜、膜上精量播种、种植作物收获及残膜回收关键技术特点及典型机具。结合实际生产应用中出现的问题与需求,在分析归纳现阶段全膜双垄沟播技术农艺、农机存在问题的基础上,从加强全膜双垄沟播技术农机农艺融合、持续开展基础研究与配套机具性能优化、创建全膜双垄沟全程机械化技术体系等方面展望了未来研究方向。提出研发经济高效全膜双垄沟全程机械化作业装备和农机农艺深度融合是创建全膜双垄沟全程机械化技术体系的关键,也是进一步形成科学合理的全膜双垄沟播技术,实现全膜双垄沟生产系统高效、节本增效的发展方向。  相似文献   

15.
为探讨北方寒旱区玉米机播技术配套的农艺措施,以哈尔滨地区为研究区域,研究了4种种植模式(垄作覆膜、沟作覆膜、垄作秸秆覆盖及传统种植)对玉米生长特性及根系时空分布的影响。结果表明,该地区玉米前期生长抑制主导因子为温度条件,垄作覆膜措施最优;后期主导因子为水肥条件,垄作秸秆覆盖措施最优。此外,覆膜措施倾向于形成浅层集中根系,秸秆覆盖措施易形成深层均匀分布根系。综合分析,北方寒旱区玉米机播技术配套的农艺措施宜选用秸秆覆盖措施,利于优化群体质量和提高整体产量水平。  相似文献   

16.
Field experiments were carried out over a 2-year period on a loamy soil plot under corn in Montpellier (south-east France). The effectiveness of improved irrigation practices in reducing the adverse impact of irrigation on the environment was assessed. Different irrigation and fertiliser treatments were applied to identify the best irrigation and fertilisation strategy for each technique (furrow and sprinkler) to ensure both good yields and lower NO3- leaching. No significant differences in corn yield and NO3- leaching were found for the climatic scenario of 1999 between sprinkler and furrow irrigation during the irrigation season. Following the rainy events occurring after plant maturity (and the irrigation season), differences in N leaching were observed between the treatments. The study shows that both the fertiliser method, consisting of applying a fertiliser just before ridging the furrows, and the two-dimensional (2D) infiltration process, greatly influence the N distribution in the soil. N distribution seems to have a beneficial impact on both yield and N leaching under heavy irrigation rates during the cropping season. But, under rainy events (particularly those occurring after harvesting), the N, stored in the upper part of the ridge and not previously taken up by plants, can be released into the deeper soil layers in a furrow-irrigated plot. In contrast, the 1D infiltration process occurring during sprinkler irrigation events affects the entire soil surface in the same way. As a result the same irrigation rate would probably increase N leaching under sprinkler irrigation to a greater extent than under furrow-irrigation during an irrigation period. In order to assess the robustness of these interpretations derived from soil N-profile analysis, a modelling approach was used to test the irrigation and fertilisation strategies under heavy irrigation rates such as those occurring at the downstream part of closed-end furrows. The RAIEOPT and STICS models were used to simulate water application depths, crop yield and NO3- leaching on three measurement sites located along the central furrow of each treatment. The use of a 2D water- and solute-transport model such as HYDRUS-2D enabled us to strengthen the conclusions derived from the observations made on the N distribution under a cross-section of furrow. This model helped to illustrate the risk of over-estimation of N leaching when using a simplified 1D solute-transport model such as STICS.  相似文献   

17.
The effects of supplemental irrigation, sand columns and blocked furrows on soil water distribution and barley yield were studied on arid soils affected by surface crusts. The sand columns were 50 mm diameter, 600 mm deep, and filled with sand of 0.375 mm mean diameter. The blocked furrows were trenches about 250 mm deep, 300 mm wide, and 6 m long established perpendicular to the slope direction. Sand column and furrow treatments significantly increased soil water storage compared with natural or control treatments. Soil water storage significantly increased by about 210% and 230% near the center of the sand column and the furrow treatments, respectively, relative to the control treatment. For sand column treatments, soil water storage decreased linearly with distance from the center of the sand column to about 2.5 m, while for the furrow treatment soil water storage decreased logarithmically to a distance of about 1.0 m, beyond which the soil water storage was not significantly different from the natural or control treatments. The furrow and sand column treatments significantly increased the water application efficiency, seasonal consumptive use and barley grain and straw yields compared with natural and control treatments. Increasing furrow spacing increased the catchment area and consequently crop production per furrow, but decreased crop production per unit total (cultivated and catchment) area. Decreasing sand column spacing reduced surface runoff and increased soil water storage and consequently barley grain and straw yields. Supplemental irrigation is essential for grain production in limited rainfall areas. Soil management is also required to overcome the problems of the soil surface crusting and the low permeability of subsurface soil layers for maximum rainwater efficiency, and for optimal crop production with minimum supplemental irrigation water. Where agricultural land is not limited, furrowed soil surfaces appear to be the most suitable technique for barley grain production. Sand columns with sprinkler irrigation might be more suitable for growing barley as forage crop where agricultural land is limited. Received: 19 October 1998  相似文献   

18.
Increasing water and fertilizer productivity stands as a relevant challenge for sustainable agriculture. Alternate furrow irrigation and surface fertigation have long been identified as water and fertilizer conserving techniques in agricultural lands. The objective of this study was to simulate water flow and fertilizer transport in the soil surface and in the soil profile for variable and fixed alternate furrow fertigation and for conventional furrow fertigation. An experimental data set was used to calibrate and validate two simulation models: a 1D surface fertigation model and the 2D subsurface water and solute transfer model HYDRUS-2D. Both models were combined to simulate the fertigation process in furrow irrigation. The surface fertigation model could successfully simulate runoff discharge and nitrate concentration for all irrigation treatments. Six soil hydraulic and solute transport parameters were inversely estimated using the Levenberg–Marquardt optimization technique. The outcome of this process calibrated HYDRUS-2D to the observed field data. HYDRUS-2D was run in validation mode, simulating water content and nitrate concentration in the soil profiles of the wet furrows, ridges and dry furrows at the upstream, middle and downstream parts of the experimental field. This model produced adequate agreement between measured and predicted soil water content and nitrate concentration. The combined model stands as a valuable tool to better design and manage fertigation in alternate and conventional furrow irrigation.  相似文献   

19.
Local infiltration tests on 1.5 m long blocked furrows were carried out on a loam soil to assess N fertiliser leaching under furrow irrigation where ridging operations entails placing nitrogen on the upper part of the ridge. This article focuses on the impact of flow depths, or water application depth (WAD), on nitrogen movement in seven 1.5-m long blocked furrows. For a first irrigation event, a WAD greater than or equal to 240 mm, significantly reduced the heterogeneity of the N concentration profiles measured at the top of the ridge and beneath the furrow. The virtually homogeneous N soil distribution with depth permitted the determination of the nitrogen balance throughout the season using soil samples obtained at the beginning and end of the season as well as the determination of nitrogen present in the crop tissue. This is not possible when there is a heterogeneous N soil profile at the end of the irrigation season, as observed under moderate WAD conditions. In addition, a substantial WAD delivered during the first irrigation event, and at a period where the plant N requirements are high, does not affect crop yield potential.  相似文献   

20.
针对宁南山区春季降雨少、低温不利于马铃薯出苗,而作物生育中后期高温胁迫限制马铃薯块茎形成导致减产等问题,于2016年设置垄覆地膜沟内覆盖塑料地膜(DM)、玉米秸秆(JG)、生物降解膜(SM)、麻纤维地膜(MM)、液态地膜(YM)及沟不覆盖(BM),以传统平作为对照(CK),研究沟垄覆盖模式对土壤温度、土壤水分、旱作马铃薯生长及块茎产量的影响.结果表明:处理DM,SM,MM和YM马铃薯生育期耕层土壤温度表现出增温效应,而处理JG和BM表现为降温效应,其中处理DM增温效果和处理JG降温效果最佳.处理YM,JG对马铃薯生长前期保水效果较好,分别较CK显著提高13.3%,27.0%,而处理JG,DM对生育中后期的保墒效果较佳,分别较CK显著提高22.4%,13.2%.处理JG可显著促进马铃薯生长,其增产效果最为显著,DM次之,分别较CK增产47.8%,44.8%,其他处理较CK差异不具有统计学意义.可见,在宁南山区实施垄覆地膜沟覆秸秆模式可调控土壤水热环境,对旱作马铃薯生长及增产效果最佳.  相似文献   

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