长年耕作对北方旱作麦田土壤细菌群落结构及理化性质的影响

为探究旱作麦田长期耕作对不同土层细菌群落结构的影响及其与土壤理化性质的关系,于2016~2021年在山西农业大学闻喜旱地小麦试验示范基地开展长期定位试验,研究夏闲期免耕（NT）、深松（ST）和深翻（DP）这3种耕作方式对不同土层土壤理化性质,细菌群落α、β多样性,细菌门和属优势物种及差异物种的影响,并采用PICRUSt2预测其代谢功能.结果表明,旱作麦田连续5a深松和深翻较免耕显著提高了20~40 cm土层土壤含水量,显著降低了0~20 cm土层土壤有机碳含量;深松较深翻显著提高了0~20 cm土层土壤含水量、土壤有机碳、可溶性有机碳和可溶性有机氮含量.深松和深翻较免耕可提高0~40 cm土层土壤细菌群落的α多样性,且深松高于深翻.深松和深翻较免耕显著提高了0~20 cm土层中酸杆菌门、硝化螺旋菌门和20~40 cm土层中酸杆菌门、绿弯菌门、芽单胞菌门、Rokubacteria门、GAL15门和硝化螺旋菌门的相对丰度;显著提高了0~20 cm土层硝化螺旋菌属和20~40 cm土层Rubrobacter属和链霉菌属的相对丰度.深松较深翻显著提高了0~40 cm土层酸杆菌门、芽单胞菌门的相对丰度.冗余分析表明,0~20 cm土层的土壤有机碳、可溶性有机碳和可溶性有机氮含量对放线菌门和牙殖球菌属产生正向效应,且深松下0~40 cm土层的土壤含水量对酸杆菌门、绿弯菌门和芽单胞菌门产生正向效应.PICRUSt2预测结果表明,深松和深翻较免耕显著提高了20~40 cm土层细菌群落的氨基酸代谢和辅酶维生素代谢的相对丰度,但降低了脂质代谢的相对丰度;深松较深翻显著提高了0~40 cm土层细菌群落的氨基酸代谢和0~20 cm土层其他氨基酸代谢的相对丰度.总之,旱地麦田夏闲期深松或深翻均可提高土壤含水量、土壤细菌群落的α多样性及细菌群落的代谢能力,深松还可提高酸杆菌门和芽单胞菌门的相对丰度,并提高细菌群落的氨基酸代谢能力,从而提高了土壤可溶性有机碳、氮含量.     

覆盖条件下旱作春玉米农田土壤细菌群落结构分析

秸秆和地膜覆盖会改变农田土壤碳氮循环等理化条件,而覆盖对参与碳氮循环的土壤微生物的影响还鲜有报道。本研究通过高通量测序,分析了黄土高原旱作玉米农田无覆盖、秸秆覆盖、地膜覆盖下土壤细菌群落组成,探讨了细菌介导的碳氮循环对覆盖的响应。结果表明秸秆覆盖增加了土壤细菌群落丰富度和多样性,且显著增加了分解纤维素的细菌(纤维弧菌属Cellvibrio)及介导固氮(根瘤菌属Rhizomicrobium、Chryseolinea)和硝化过程的细菌(亚硝化螺菌属Nitrosospira)丰度(p0.05);地膜覆盖增加了土壤细菌丰富度,但降低了细菌多样性,且显著增加了介导土壤硝化作用的硝化螺菌属Nitrospira的丰度(p0.05)。本结果为土壤中微生物介导的碳氮循环研究提供了理论依据。     

基于旱地土壤环境风险的农药毒死蜱的施用限值研究

通过开展田间试验,研究毒死蜱在玉米、小麦和大豆3种作物田土壤中的降解及环境风险,基于毒死蜱及其降解产物TCP的残留特征和环境风险,计算毒死蜱施用限值.研究表明玉米田土壤中的毒死蜱残留量大于大豆田和小麦田;毒死蜱在农田土壤中的降解速率随着施用浓度的增加而提高.小麦、大豆、玉米3种作物种植土壤中毒死蜱及TCP的短期和长期生态风险均有差异.玉米、大豆和小麦3种作物农田中,当超过推荐剂量施用毒死蜱,毒死蜱及TCP均具有较高短期风险和长期生态风险,相对于毒死蜱,TCP对土壤的生态风险更高.基于旱地土壤的毒死蜱及TCP的环境风险,通过模型计算农药毒死蜱在大豆田中的施用限值为0.4412 kg·hm^-2,在小麦田中的施用限值为0.5034 kg·hm^-2,在玉米田中的施用限值为0.5487 kg·hm^-2.     

福建赤红壤旱地与红壤旱地水分特性的比较

释放80%的有效水时赤红壤旱地的t值（当释放的土壤有效水占有效水库容的比率为80%时的土壤水吸力值）较小,表明赤红壤旱地持水性较红壤旱地更差,植物更容易受到干旱的协迫。赤红壤旱地贮水库容比红壤旱地小,赤红壤旱地的比水容量达到10-2数量级（难效水）在-10kPa~-30kPa就开始出现,而红壤旱地出现在-30kPa以下,表明赤红壤旱地的失水速度快,保水供水性能弱于红壤旱地。最后,讨论了影响旱地土壤水分性质的因素。     

不同秸秆还田方式对旱地红壤细菌群落、有机碳矿化及玉米产量的影响

为探讨长期不同秸秆还田方式对旱地红壤细菌群落、有机碳矿化及玉米产量的影响,基于中国科学院鹰潭红壤生态实验站设置的不同秸秆还田方式长期定位试验(9 a),选取不施肥(CK)、单施化肥(N)、化肥+秸秆(NS)、化肥+秸秆猪粪配施(NSM)和化肥+生物质炭(NB)这5个处理,通过高通量测序技术研究旱地红壤细菌多样性和群落结构差异,揭示了细菌群落对土壤有机碳矿化和玉米产量的影响机制.结果表明:①不同秸秆还田处理下,红壤化学性质发生显著变化,其中NSM处理对旱地红壤肥力的综合提升效果最好,并显著提高了玉米产量.②相比于CK和N处理,秸秆还田处理均提高了细菌多样性.主成分分析发现,秸秆还田处理改变了土壤细菌群落结构.③秸秆还田处理提高了土壤有机碳矿化能力,NSM处理的土壤有机碳矿化速率和累积矿化量最高.④相关性分析表明土壤AN/AP比值显著改变了细菌群落结构,结构方程模型结果表明,土壤AN/AP比可能通过影响土壤细菌多样性和群落结构,间接提高了土壤有机碳矿化能力和玉米产量.本研究结果为协同提升旱地红壤生物多样性和耕地地力水平,保障健康红壤生态系统和粮食安全提供了科学依据.     

1980—2014年中亚地区植被净初级生产力对气候和CO2变化的响应

中亚干旱区分布着世界80%以上的温带荒漠,受气候变化影响显著。论文首先收集实验观测数据验证了干旱区生态系统模型（AEM）,然后运用AEM开展数值模拟实验量化研究了1980—2014年中亚净初级生产力（NPP）的时空格局,评估了不同环境因子（降水、温度、CO₂）的相对贡献率及其交互效应。结果表明：过去35 a中亚干旱区年均NPP总量为1 125±129 Tg C（1 T=10¹²）或218±25 g C/m²。哈萨克斯坦北部地区年NPP值较高（349±39 g C/m²）,而南疆地区年NPP值较低（123±45 g C/m²）。1980—2014年间,中亚NPP总体呈减少趋势 [-0.71 g C/(m²·a)],南疆极端干旱区的NPP降低最为显著 [-2.05 g C/(m²·a)]。相较于1980—1984年NPP均值,在1985—2014年中亚区域NPP总体降低了118 Tg（-10%）。其中CO₂施肥效应促进NPP增加了99.7 Tg （+8%）,气温升高的正效应促进NPP增加了35.4 Tg（+2%）,而降水减少导致NPP降低了221 Tg（-18%）。研究区内9%的地区的NPP主要控制因子为温度,主要分布在天山和哈萨克斯坦北部等高纬高寒地区。降水主控区面积占整个研究区的69%,主要分布在荒漠平原特别是南疆等植被受水分限制的区域。CO₂主控区占研究区面积的20%,主要分布在天山中山带森林区和低海拔地区等水热条件好的区域。研究表明新疆南部地区是中亚的关键生态脆弱区,其生态安全面临着气候变化的挑战,但21世纪的升温不大可能因刺激自养呼吸而对中亚区域NPP造成显著影响。     

Past desertification processes of Minqin Oasis in arid China

Irrigated farming has affected most natural oases in western China since the Han Dynasty employed advanced agricultural techniques in dryland areas. To date, little is documented about the process through which these oases were modified by human systems. In this study, a multi-disciplinary approach incorporating analysis of historical documents, archaeological field surveys, satellite imagery, and GIS data was used to understand desertification processes in the Minqin Basin in Gansu Province, China, over the historical period. Results suggest that initial reclamation efforts around the Minqin Oasis were launched in the Han Dynasty (220–121 BC) and culminated in the Wei and Jin Dynasty (220–420). During the following 800 years from the Southern and Northern Dynasties (420–581) to the Yuan Dynasty (1271–1368), farmland disappeared and became desert when the region was taken over by nomadic people. The second period of intense development occurred in the Ming Dynasty (1368–1644) and was followed by another more aggressive development in the Qing Dynasty (1644–1911), which resulted in the largest reclaimed area in history. Oases were constantly reclaimed and subsequently abandoned and desertified over the whole historical period. The causes were complex, but the major cause was related to dynastic transition that often resulted in changes in national policies.     

PRECIPITATION RETENTION AND SOIL EROSION UNDER VARYING CLIMATE,LAND USE,AND TILLAGE AND CROPPING SYSTEMS1

ABSTRACT: Nonirrigated crop yields and forage production are limited by low and variable precipitation in the southern Great Plains. Precipitation variation involves production risks, which can be reduced by considering probability of precipitation, precipitation retention, and soil erosion under various production systems. The objective of this study was to probabilistically quantify the impact of precipitation variations, land use, cropping, and tillage systems on precipitation retention and soil erosion. Five 1.6 ha watersheds that had 3 to 4 percent slopes, and similar silt loam soils were selected. One was kept in native grass, and the others were planted into winter wheat (Triticum aestivum L.) under different cropping and tillage systems. Daily runoff and soil erosion were measured at the outlet of each watershed. Precipitation distributions exhibited great seasonal and interannual variations, and precipitation retention distributions resembled those of precipitation. Cropping and tillage systems affected precipitation retention but much less than did precipitation variations. Available soil water storage, which was largely controlled by ET, played an important role in retaining precipitation. This indicates that cropping systems should be adjusted to precipitation patterns, if predictable, for better soil water use. Land use and cropping and tillage systems had a much greater impact on soil erosion than on precipitation retention. Soil erosion risks, which were proportional to the levels of tillage disturbance, were mainly caused by a few large storms in summer, when surface cover was low. This study explored a novel approach for evaluating production risks associated with insufficient precipitation retention and excessive soil erosion for certain crops or cropping systems under assumed precipitation conditions.     

水分调控下旱地土壤中毒死蜱的消解研究

为探讨水分调控下旱地土壤中毒死蜱的消解特性,通过盆栽试验及通径分析方法,研究了不同水分条件下旱地土壤中毒死蜱消解速率及其与土壤性质之间的关系.结果表明:①土壤中毒死蜱的消解速率随时间的延长而逐渐减缓,并且不同水分条件下土壤中毒死蜱的消解速率不同,施药45 d后,5个水分处理（20% FC、40% FC、60% FC、80% FC和100% FC,表示田间持水量依次为20%、40%、60%、80%和100%）下毒死蜱的消解率分别为65.58%~85.56%、70.71%~89.64%、76.30%~95.33%、72.53%~97.60%和70.57%~90.80%,其中以80% FC下的消解速率最快,60% FC下次之.②一级动力学方程能较好地描述土壤中毒死蜱的消解过程（R2>0.88）,消解速率常数（k）最大为0.099 0 d-1.③土壤中毒死蜱的消解速率与w（有机碳）、w（DOC）（DOC为可溶性有机碳）和w（MBC）（MBC为微生物量碳）均呈显著相关.通径分析结果显示,水分条件的改变致使土壤中w（有机碳）、w（DOC）和w（MBC）发生变化,进而对土壤中毒死蜱的消解速率产生较大影响.④大豆、玉米和小麦根际土壤中毒死蜱消解速率均快于非根际土壤,根际土壤中毒死蜱消解速率表现为大豆土壤（0.099 0 d-1）>玉米土壤（0.080 6 d-1）>小麦土壤（0.069 6 d-1）.研究显示,改变土壤水分含量可有效调节土壤中毒死蜱的消解,并为农业生产中毒死蜱的安全施用提供参考依据.      

华北地区旱田土壤氧化亚氮的排放

在１９９１－１９９３年间用封闭罩测定了对照田、施肥田Ｎ２Ｏ的排放量。结果表明，Ｎ２Ｏ通量显示出时、空变化规律。对照田，施尿素田和施混合肥田（尿素加有机肥）Ｎ２Ｏ排放量分别是１．０３±０．４ｋｇＮ／ｈｍ２ａ；１．９１±０．６ｋｇＮ／ｈｍ２ａ和２．１１±１．０ｋｇＮ／ｈｍ２ａ．尿素和混合肥释放Ｎ２Ｏ系数分别为０．２９％和０．３５％。由土壤含水量，土壤温度和速效氮浓度等土壤变量建立了Ｎ２Ｏ排放的统计模式。