秸秆覆盖对沟灌水盐迁移与玉米水分利用效率的影响

为研究河套灌区盐渍化土壤垄背地膜和秸秆覆盖下的沟灌土壤水盐迁移特征,明晰沟灌作物产量及水分利用效率的变化规律,设置垄背秸秆覆盖量分别为0.3（P0.3）、0.6（P0.6）、0.9（P0.9）、1.2kg/m 2 （P1.2）和常规覆膜（DM）、裸地不覆盖（CK）6种处理,于2019年进行沟灌灌水试验,对比分析了不同秸秆覆盖量下玉米生育期前后沟断面土壤水盐分布、作物产量及水分利用效率的变化情况。结果表明：玉米苗期,覆膜和秸秆覆盖处理能显著降低作物无效耗水,保证生育后期对水分的需求;抽雄灌浆期,覆膜增温效应促进了作物生长,DM处理玉米耗水强烈,土壤储水量最低;玉米成熟期,垂直方向土壤水分运动较前期减弱。整体来看,P1.2、P0.9处理蓄水保墒效果较好（P<0.05）。沟灌灌水定额较小、盐分淋洗效果较差,且受土壤蒸发及地下水补给作用,因此造成根系层盐分累积。覆膜和秸秆覆盖处理均能有效抑制盐分聚集,P1.2和P0.9处理生育末期的土壤含盐量较初始含盐量增幅较小,分别为14.10%和24.74%。P0.9和DM处理产量和水分利用效率较CK分别提高20.01%、25.46%和11.32%、15.29%,增幅较大;过量秸秆覆盖造成播期土壤温度偏低,会影响玉米出苗,P1.2处理玉米产量和水分利用效率较DM处理略有降低,但差异不显著（P>0.05）。采用主成分分析法对沟灌秸秆覆盖下土壤保墒抑盐效果、玉米出苗、产量以及水分利用效率等因素进行综合评价,初步确定适宜的沟灌秸秆覆盖模式,建议采用0.9~1.2kg/m 2 的垄背秸秆覆盖量代替常规地膜覆盖,以减小地膜残留带来的环境污染。本研究可为灌区农业栽培提供一定借鉴。     

硝酸改性秸秆水热炭结构表征与铅吸附机制研究

以玉米秸秆为原料,采用不同质量分数（10%和30%）的硝酸溶液在水热炭化前、后对样品进行改性处理,结合理化结构表征以及等温吸附模型、吸附动力学模型的拟合结果,探究了硝酸改性秸秆水热炭对铅离子的吸附机制。结果表明,经硝酸改性处理的秸秆水热炭均会形成丰富的含氧基团,水热炭化前,经HNO3改性的秸秆炭（10%N-JG和30%N-JG）呈现粗糙多孔的表面形貌和发达的中孔结构,并形成了三维无序的大尺寸微晶结构;水热炭化后,经HNO3改性的秸秆炭（JG-10%N和JG-30%N）产生了大量分布均匀、尺寸相近的微孔,并形成了三维有序的小尺寸微晶结构。通过对比发现,10%N-JG和30%N-JG对铅离子吸附效果最优,分别在3.5h和3h达到吸附平衡,理论最大吸附量可达247.51mg/g和280.09mg/g。10%N-JG和30%N-JG均符合准一级、准二级动力学模型以及Freundlich等温吸附模型,说明物理扩散和化学吸附在铅离子吸附过程中的作用同等重要。研究发现,秸秆水热炭主要依靠含氧官能团的化学吸附作用脱除水中的铅离子,其发达的中孔结构更有利于铅离子进入颗粒内部,增大了内部孔道上含氧基团对铅离子的捕捉机率,从而保证了水热炭对铅离子的高效吸附。     

移动式秸秆制粒机作业速度调控系统研究

为了提高移动式秸秆制粒机工作效率,解决玉米秸秆收获过程中作业速度与喂入量不匹配的问题,设计了一种移动式秸秆制粒机作业速度自动调控系统,以实现对秸秆制粒机作业速度的自动调控。该系统由喂入量-期望作业速度自适应变论域模糊控制器与液压马达转速调控系统构成,采用液压系统控制秸秆制粒机作业速度的方式进行调控。通过螺旋输送器功率得到实际喂入量,并根据灰色理论建立喂入量预测模型,以预测值作为变论域模糊控制器的输入;变论域控制器的输出作为液压马达转速调控系统的输入,作业速度PID控制器驱使液压控制系统调节制粒机行走机构改变作业速度,从而使作业速度和喂入量匹配,达到最佳喂入量,起到超前调节的目的。设计了3次试验,分别为模型参数的获取试验、均匀秸秆条件下的稳定性试验、非均匀秸秆条件下跟踪性能试验。试验结果表明,在均匀秸秆条件下,作业速度能够在3m内达到最佳作业状态,超调量小于5%,之后能够保持良好的平稳运行状态,使制粒机以最佳喂入量工作;同样,在非均匀秸秆条件下,作业速度能够以不大于5%的超调量跟踪喂入量的变化。试验证明,本系统能够实时检测作业速度和喂入量,达到作业速度和喂入量相匹配的目的,有效提高了移动式秸秆制粒机的工作效率。     

玉米秸秆分解过程中细菌群落组成演化特征

【目的】土壤中存在着大量的分解秸秆的微生物。研究秸秆分解过程中细菌群落组成的演化规律,对了解和调控农田微生物群体组成以促进秸秆分解具有重要意义。【方法】试验于2014年10月至2015年10月在河南省农业科学院原阳试验基地进行,将成熟期玉米秸秆(茎和叶)烘干,剪成长1~2 cm、宽0.3~1 cm的碎片,称12 g样品(相当于8 t/hm^2)装入15 cm×10 cm的尼龙网包(孔径0.04 mm)内,于10月5日冬小麦出苗后埋置在小麦垄间。分别于埋置后0、1、2、4、7、10和12个月收集秸秆包和土壤样品。测定秸秆样品干物质量和碳氮含量,选择埋置了0、2、4、7和12个月的秸秆及其土壤样品分析细菌丰度及群落组成。【结果】秸秆埋入土壤后的前2个月内分解最快,然后逐步减慢,在1、2、4、7、10和12个月后分别降解了总生物量的19.2%、32.9%、44.2%、52.2%、66.8%和73.8%。秸秆埋入土壤后,秸秆和土壤中细菌丰度均显著增加,分别于第4和7个月达到最高后开始下降。秸秆细菌的丰度指标OTUs、ACE、Chao1和多样性指标Shannon随试验时间的延长逐步增加,而Simpson指数随试验时间延长逐步降低,而土壤中这些指标在试验过程中没有显著变化。与刚埋置秸秆时相比,埋置2个月后的秸秆细菌Bacteroidetes门相对丰度明显增加,主导细菌群为Bacteroidetes和Proteobacteria门。Actinobacteria丰度在埋置2个月后明显降低,然后又随试验时间延长逐步增加。Planctomycetes、Saccharibacteria、Verrucomicrobia、Acidobacteria、Chloroflexi和Gemmatimonadetes丰度在原始秸秆中较低,埋入土壤后随试验时间延长逐步增加。Sphingobacteriia、Gammaproteobacteria、Alphaproteobacteria和Flavobacteriia主导前期细菌纲组成,而Actinobacteria、Anaerolineae和Bacilli纲丰度在后期逐步增加。秸秆分解速率主要受其碳含量影响,秸秆细菌群落组成前期与秸秆碳含量相关,后期与秸秆氮含量相关。随着试验的进展,秸秆细菌群落组成与土壤中的细菌群落组成趋同。【结论】秸秆埋入土壤后前2个月的分解速率最高,随后逐步降低。秸秆分解前期细菌群落由富营养型组分Bacteroidetes和Proteobacteria门和Sphingobacteriia、Gammaproteobacteria、Flavobacteriia和Alphaproteobacteria纲主导,随后被逐步增加的贫营养型组分Actinobacteria、Acidobacteria、Chloroflexi、Saccharibacteria门和Deltaproteobacteria、Actinobacteria纲等代替。秸秆碳氮含量变化是影响秸秆分解及其过程中细菌群落演化的主要原因。     

覆盖方式对旱地马铃薯阶段耗水量特征和产量的影响

为明确不同覆盖方式对旱地马铃薯田土壤耗水、耗水规律、水分利用效率、产量及产量形成的影响,在陇中半干旱农区设置了玉米秸秆带状双行覆盖(SSM2)、玉米秸秆带状单行覆盖(SSM1)、玉米秸秆全覆盖(SFM)、地膜春覆盖(PMS)和地膜秋覆盖(PMA)5种覆盖方式,以传统露地平作为对照(CK)。结果表明:2年试验中,玉米秸秆带状覆盖和地膜覆盖处理土壤贮水消耗量较CK分别增加13.5,14.8 mm。玉米秸秆带状覆盖能显著提高降水对马铃薯耗水贡献率,不同降雨年型内均以SSM2处理贡献率最高,2年分别为95.6%和94.3%。于CK相比,覆盖处理均降低了生育前期(播种-块茎形成期)耗水量,地膜覆盖显著增加了生育中期(块茎形成期-淀粉积累期)耗水量,玉米秸秆带状覆盖显著增加了生育后期(淀粉积累期-收获期)的耗水量。玉米秸秆带状覆盖和地膜覆盖分别能使马铃薯干薯产量增加27.9%和24.2%,干薯水分利用效率提高23.1%和19.3%。综上可知,玉米秸秆带状覆盖处理能显著增加马铃薯生育时期内农田土壤贮水消耗量,并改善马铃薯生育前期和生育后期耗水,减少旱地马铃薯农田无效耗水,能显著提高马铃薯干薯产量和水分利用效率。     

秸秆生物反应堆与菌肥对温室番茄土壤微环境的影响

为研究秸秆生物反应堆、微生物菌肥及两者配套措施对土壤理化性质和微生物功能多样性,以及作物生长的长期影响,试验以传统种植方式为对照(CK,常规栽培),研究了菌肥(T1,微生物菌肥4 kg/667 m2)、内置式秸秆生物反应堆(T2,秸秆(4 t/667 m2)+发酵沟菌剂(8 kg/667 m2)+腐熟猪粪(600 kg/667 m2))及2种措施配套处理(T3,秸秆(4 t/667 m2)+发酵沟菌剂(8 kg/667 m2)+微生物菌肥(4 kg/667 m2)+腐熟猪粪(600 kg/667 m2))对土壤理化性质和微生物功能多样性的影响。结果表明:1)与CK相比,秸秆生物反应堆能够在一定时期内提高土壤含水率;而菌肥能够在一定时期内降低土壤含水率,秸秆生物反应堆能够显著降低土壤酸性和电导率(EC,electrical conductivity)值,缓冲土壤酸化和次生盐渍化;而单施菌肥对土壤酸碱性和EC值没有显著影响。2)秸秆生物反应堆(T2)增加了土壤中有机质的含量和土壤微生物量,降低土壤中速效磷、钾的含量;微生物菌肥(T1)降低了土壤中有机质含量和微生物量,而显著提升了土壤的速效磷、速效钾含量,两种措施配套处理效果则更明显。3)菌肥能够改善土壤微生物对多聚物、碳水化合物和氨基酸的利用效率,而秸秆生物反应堆能够促进土壤微生物对于一部分氨基酸、羧酸类、酚酸类和胺类物质的利用。而2种措施同时使用时,其促进和改善微生物碳代谢能力的作用则更加显著。4)各处理均能够在一定程度上增加各年度番茄产量。综合考虑,认为内置式秸秆生物反应堆和菌肥配套处理(T3)能够更好的改善和修复日光温室连作土壤,增加作物产量,是一种较为有效的农艺措施。     

复合菌剂对玉米秸秆的降解及土壤生态特性的影响

还田玉米秸秆降解过程中施加含有植物内生真菌的复合菌剂,在盆栽条件下研究了该菌剂对还田秸秆的降解作用,对土壤生态以及后季作物小麦生长的影响。结果表明:添加复合菌剂能够促进玉米秸秆的降解,在前30 d时效果最显著,尤其是木质素的降解,两种复合菌剂处理组木质素降解率分别比市购秸秆腐熟剂高117.36%和242.70%;施用菌剂会显著增加小麦生长早期土壤蔗糖酶、脲酶和纤维素酶的活性,增加小麦生长早期土壤微生物数量;改善土壤理化性质,提高小麦成熟后土壤中的全氮、全钾、碱解氮和速效钾的含量;显著改善小麦生长状况,小麦返青拔节期叶片叶绿素含量显著增加,收获小麦单株生物量和单株产量也有所增加。     

The effects of straw return on potassium fertilization rate and time in the rice–wheat rotation

In order to investigate the effects of straw return on potassium (K) fertilizer application rate and time in the rice–wheat rotation, field experiments were conducted at three sites. The results showed that when the K rate was decreased to 70% of the recommended K dosage, crop yields showed no significant decrease. With K fertilization only at rice phase, crop yields showed no marked difference compared with that provided K fertilizer both at wheat and rice seasons. Though the NH₄OAc-extracted K and HNO₃-extracted K differed slightly among the treatments, the soil apparent K balance was negative without K fertilization. With crop straw fully incorporated, the recommended K dosage could be at least reduced by 30% at the experimental sites and the K fertilizer could be applied only at rice phase. A further hypothesis can be made that the best K rate was the amount of K took away by crop grain. In the long run, straw return combined with K fertilization would be an effective method to maintain soil K fertility and productivity.     

Soil nitrogen balance and nitrogen utilization of winter wheat affected by straw management and nitrogen application in the Yangtze river basin of China

Straw incorporation is a useful management practice in sustainable agricultural systems to improve soil fertility and to reduce air pollution from straw burning. A three-year field experiment was conducted under two rice straw managements and four nitrogen (N) application rates in Rugao, China during 2010–2013, to examine whether straw management practices integrated with fertilizer N applications affect crop yield, N balance and N use efficiency in the wheat season of rice-wheat cropping systems. The results showed that straw incorporation had positive effects on plant N uptake and grain yield. This may be attributed to the greater soil water content and lower amount of seasonal rainfall. However, straw incorporation resulted in lower soil inorganic N and more N surplus at the early growth stage. Grain yield had a significant relation with wheat N uptake from sowing to jointing and from jointing to anthesis with straw incorporation. Therefore, our results suggest that in adjusting the ratio of basal and topdressing N fertilizer, it is important for the supply of optimum N to the crop and to maintain grain production with straw incorporation.     

Effects of part and whole straw returning on soil carbon sequestration in C3–C4 rotation cropland

Long‐term no‐tillage management and crop residue amendments to soil were identified as an effective measure to increase soil organic carbon (SOC). The SOC content, SOC stock (SOCs), soil carbon sequestration rate (CSR), and carbon pool management index (CPMI) were measured. A stable isotopic approach was used to evaluate the contributions of wheat and maize residues to SOC at a long‐term experimental site. We hypothesized that under no‐tillage conditions, straw retention quantity would affect soil carbon sequestration differently in surface and deep soil, and the contribution of C3 and C4 crops to soil carbon sequestration would be different. This study involved four maize straw returning treatments, which included no maize straw returning (NT‐0), 0.5 m (from the soil surface) maize straw returning (NT‐0.5), 1 m maize straw returning (NT‐1), and whole maize straw returning (NT‐W). The results showed that in the 0–20 cm soil layer, the SOC content, SOCs, CSR and CPMI of the NT‐W were highest after 14 years of no‐tillage management, and there were obvious differences among the four treatments. However, the SOC, SOCs, and CSR of the NT‐0.5 and NT‐W were the highest and lowest in 20–100 cm, respectively. The value of δ¹³C showed an obviously vertical variability that ranged from –22.01‰ (NT‐1) in the 0–20 cm layer to –18.27‰ (NT‐0.5) in the 60–80 cm layer, with enriched δ¹³C in the 60–80 cm (NT‐0.5 and NT‐1) and 80–100 cm (NT‐0 and NT‐W) layers. The contributions of the wheat and maize‐derived SOC of the NT‐0.5, NT‐1 and NT‐W increased by 11.4, 29.5 and 56.3% and by 10.7, 15.1 and 40.1%, relative to those in the NT‐0 treatment in the 0–20 cm soil layer, respectively. In conclusion, there was no apparent difference in total SOC sequestration between the NT‐0.5, NT‐1, and NT‐W treatments in the 0–100 cm soil layer. The contribution of wheat‐derived SOC was higher than that of maize‐derived SOC.