稻秸蚯蚓堆制后的物理、化学及微生物特性变化

利用水稻秸秆与畜禽粪便（牛粪、猪粪和鸡粪）等干重混合物（RCD、RPM、RCE）接种蚯蚓（Eisenia foetida）进行堆制,研究堆肥产物的物理、化学及微生物特性变化。结果表明,蚯蚓堆制30 d后,稻秸牛粪、稻秸猪粪堆肥产物MBC含量显著下降; 3种稻秸粪便混合物经蚯蚓堆制后,堆肥产物微生物代谢熵、脱氢酶和碱性磷酸酶活性增加,尤以RCD的变化明显。稻秸牛粪、稻秸猪粪及稻秸鸡粪混合物经蚯蚓堆制后,总固形物平均重量损失分别增加6.45%、4.22%和3.82%; pH值均降低,其中RCD显著降低。蚯蚓堆制有助于提高堆肥产物全氮、全磷和全钾含量,同时使碳氮比降低。水稻秸秆混入部分畜禽粪便经蚯蚓堆制可减少堆肥时间并提高堆肥质量,混入的粪便以牛粪最好,猪粪次之,鸡粪最差。     

氮肥品种和用量对水稻产量和镉吸收的影响研究

采用盆栽试验,研究了Cd污染土壤上,不同氮肥品种和用量对水稻产量和Cd吸收的影响。结果表明,与磷钾配施的4个氮肥处理中,施用尿素处理水稻产量最高,其次为施(NH4)2SO4和NH4Cl处理,施NH4NO3处理水稻产量最低。与施(NH4)2SO4、NH4NO3和尿素处理相比,施NH4Cl处理可显著增加水稻对Cd的吸收,并促进Cd由秸秆向籽粒的转移;而其他3种氮肥对水稻秸秆和籽粒中Cd含量的影响效应相当。适量尿素[0.2g(N)·kg-1]处理能显著降低水稻籽粒Cd含量,而不施尿素和高量尿素处理都显著提高了水稻籽粒中的Cd含量。研究表明,在Cd污染的水稻土上,采用抗Cd污染的水稻品种和优化肥、水管理措施,可使稻米中Cd含量低于国家无公害大米的限量指标。     

抗除草剂转基因作物面临的机遇与挑战及其发展策略

2008年全球抗除草剂转基因作物已占转基因作物总种植面积的80%以上,抗除草剂成为最主要的转基因应用的性状.该技术的成功应用极大地降低了杂草防除成本、增加了安全性和减少了除草剂的残留药害.但是,抗除草剂转基因作物的大规模产业化将导致除草剂市场单一化,从而冲击除草剂产业,还会产生杂草抗药性和基因逃逸等环境安全问题,因此抗除草剂转基因作物面临着挑战.在我国转基因抗除草剂作物还没有实际的商业化,不过由于市场巨大、政策支持等面临良好发展机遇.此外,从抗除草剂基因利用、转基因抗除草剂作物的研究与开发策略等方面进行综述,以期为我国转基因抗除草剂作物的研究与开发提供可能有益的信息.     

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.     

大豆秸秆生物炭对铅锌尾矿污染土壤的修复作用

采用盆栽空心菜的方法,研究了大豆桔杆生物炭对铅锌尾矿污染土壤的修复作用。污染土壤中Cu、Zn、Pb和Cd含量分别为50,400,1 119,3.4mg/kg。结果表明:土壤无论是否受到铅锌尾矿污染,添加3%生物炭(w/w)均能显著提高土壤pH;3%生物炭能够抑制铅锌尾矿污染导致的土壤pH降低。大豆桔杆生物炭对尾矿污染土壤和未污染土壤中重金属有效态的影响不同,与未污染土壤相比,3%生物炭的钝化作用不能抵消铅锌尾矿污染导致的重金属有效态含量的增加。铅锌尾矿污染抑制空心菜生长;施加3%生物炭可以消除铅锌尾矿污染对空心菜生长的抑制作用。生物炭显著降低污染土壤空心菜根部重金属含量,而对地上部分的影响,不同元素表现出不同的特点;3%生物炭能够阻控铅锌尾矿污染土壤中Cu、Zn、Pb和Cd向空心菜地上部迁移富集。大豆桔杆生物炭对空心菜吸收重金属的影响,在铅锌尾矿污染土壤和未污染土壤上表现不同,存在元素之间的拮抗作用以及由于生物炭提高空心菜生物量所产生的稀释作用。在研究设置条件下,与未污染土壤相比,从空心菜生物量和可食部分吸收重金属含量来评价,施加3%大豆桔杆生物炭可以修复铅锌尾矿导致的土壤污染。     

中国粮食主产区参考作物蒸散量演变特征与成因分析

在全球变暖的背景下,参考作物蒸散量（reference crop evapotranspiration,ET0）的改变及其空间分布势必对中国粮食主产区农业水资源规划、农业用水管理等产生重要影响。本文将中国粮食主产区划分为温带湿润半湿润地区（I区）、温带干旱半干旱地区（II区）、暖温带半湿润地区（III区）和亚热带湿润地区（IV区）4个子区域,基于粮食主产区265个站点1961-2013年53a气象数据,采用FAO-56 Penman-Monteith公式计算各站点逐日ET0,利用ArcGIS空间插值、Mann-Kendall趋势检验、敏感性分析和贡献率分析等方法,对该区域ET0的时空分布规律及其成因进行分析。结果表明：（1）近53a来,中国粮食主产区年均ET0为878.9mm,整体呈显著下降趋势,速率为0.47mm·a^-1（P＜0.05）,I、II区和IV区年均ET0分别为741.8、1079.8和924.2mm且均有所减小,但变化趋势并不明显,III区年均ET0为940.2mm,呈极显著下降趋势,速率为1.21mm·a^-1（P＜0.01）。（2）全区及I-IV区ET0最敏感气象因子均为相对湿度,其敏感系数分别为-1.060、-1.232、-0.784、-1.114和-1.009。（3）全区及I-III区对ET0变化贡献最大的气象因子为风速,IV区为相对湿度。（4）风速的减小是造成粮食主产区全区及I-III区ET0减小的首要原因,风速减小和日照时数缩短是造成IV区ET0减小的主要原因。     

CT扫描分析秸秆隔层孔隙特征及其对土壤水入渗的影响

为阐明不同物理形态玉米秸秆建立的隔层对盐碱土壤灌溉水入渗特征的影响机制,该文采用室内模拟试验方法,在距地表40～45 cm处均匀铺设同一隔层厚度(5 cm)段状秸秆(SL)、颗粒状秸秆(SK)与粉末状秸秆(SF),以不埋设秸秆隔层为对照(CK),并利用CT扫描和图像处理技术,定量分析不同形态秸秆隔层内部孔隙度、孔隙大小分布、连通度等孔隙参数及其与灌溉水入渗特征之间的关系。结果表明:与CK处理相比,不同物理形态的玉米秸秆隔层均显著提高了40～45 cm隔层处总孔隙度,其中以SF处理最高,分别较CK、SL与SK处理显著提高了29.25、12.09与12.61个百分点(P 0.05),但SL与SK处理间差异不显著。SF处理在灌溉水入渗各阶段均显著增加了孔隙直径≤1 mm的孔隙度(P 0.05),入渗开始前、结束后分别较SL与SK处理提高了19.18、17.25和9.45、9.41个百分点,从而增大了封闭气体体积,导致灌溉水入渗速率较慢,而SL处理在灌溉水入渗开始前孔隙直径1 mm孔隙度较SK处理提高了1.04个百分点,但在入渗结束后SK处理孔隙直径1 mm孔隙度较SL处理显著提高,这种 1 mm大孔隙的变化导致SK处理出现湿润锋通过秸秆隔层耗时长于SL处理,而湿润锋通过隔层后至土柱底部耗时短于SL处理的现象。相关性分析结果表明:湿润锋通过秸秆隔层用时与入渗开始前、结束后隔层处总孔隙度、≤1 mm直径孔隙度均呈极显著正相关,与入渗前 1 mm直径孔隙度呈极显著负相关(P 0.01),而在入渗结束后这种大孔隙的作用减弱,但≤1 mm孔隙度的阻渗作用依旧显著,孔隙连通度对灌溉水入渗速率的影响较总孔隙度小。可见,不同形态玉米秸秆隔层均影响灌溉水入渗过程,CT扫描技术可作为定量研究秸秆隔层内部孔隙结构及其对灌溉水入渗影响机制的手段,该结果可为筛选和建立盐碱土壤最佳灌溉淋盐效果的物理形态秸秆隔层提供参考。