Biochar Mitigates Salinity Stress in Potato

A pot experiment was conducted in a climate‐controlled greenhouse to investigate the growth, physiology and yield of potato in response to salinity stress under biochar amendment. It was hypothesized that addition of biochar may improve plant growth and yield by mitigating the negative effect of salinity through its high sorption ability. From tuber bulking to harvesting, the plants were exposed to three saline irrigations, that is 0, 25 and 50 mm NaCl solutions, respectively, and two levels of biochar (0 % and 5 % W/W) treatments. An adsorption study was also conducted to study the Na⁺ adsorption capability of biochar. Results indicated that biochar was capable to ameliorate salinity stress by adsorbing Na⁺. Increasing salinity level resulted in significant reductions of shoot biomass, root length and volume, tuber yield, photosynthetic rate (A_n), stomatal conductance (g_s), midday leaf water potential, but increased abscisic acid (ABA) concentration in both leaf and xylem sap. At each salinity level, incorporation of biochar increased shoot biomass, root length and volume, tuber yield, A_n, g_s, midday leaf water potential, and decreased ABA concentration in the leaf and xylem sap as compared with the respective non‐biochar control. Decreased Na⁺, Na⁺/K⁺ ratio and increased K⁺ content in xylem with biochar amendment also indicated its ameliorative effects on potato plants in response to salinity stress. The results suggested that incorporation of biochar might be a promising approach for enhancing crop productivity in salt‐affected soils.     

南果梨周年干物质与氮磷钾积累动态

【目的】明确南果梨干物质积累特征和氮磷钾养分周年动态积累规律,为南果梨优化施肥量和施肥时期提供依据。【方法】以12年生南果梨树为试材,采用田间采样和树体分解方法,分别于萌芽后10 d(萌芽期)、 30 d(花期)、 65 d(幼果膨大期)、 100 d(果实膨大或新稍停止生长期)、 130 d(果实着色前)、 155 d(果实采收期)、 185 d(采收后)、 210 d(落叶前)8个生育期,选干周和树高一致的3株树,将树体连根从土壤中挖出,分出果实、 叶片、 枝条、 主干、 主根、 侧根、 须根,各器官单独称重,并取200 g左右的鲜样按清水、 洗涤剂、 清水、 1%盐酸、 3次去离子水冲洗、 杀青、 烘干后,电磨粉碎过0.15 mm筛,测定样品中氮、 磷、 钾含量。【结果】1)南果梨周年生育期内,树体干物质当年净积累量为18.4 kg/plant,干物质累积速率出现两次累积高峰,分别是幼果膨大期(0.15 kg/d)和采收期(0.11 kg/d)。2)南果梨树体总氮周年积累量为154.0~301.0 g,新生器官为0~116.2 g,果实膨大期达到最高;多年生器官氮积累量为154.0~194.8 g,落叶前达到最高。3)南果梨树体总磷周年积累量为17.1~37.2 g,果实着色前最高。其中新生器官为13.7 g,果实采收期最高;多年生器官为17.1~24.9 g,果实转色期最高。4)南果梨树体总钾周年积累量为27.9~174 g。新生器官钾为97.3 g,采收期最高;多年生器官钾为27.6~76.6 g,落叶前最高。5)产量大约为17 t/hm2的12年生南果梨从萌芽到落叶前树体当年氮磷钾的单株净累积量分别为146.2、 20.1、 146.1 g,折合1000 kg果实经济产量需吸收氮(N)、 磷(P)、 钾(K)5.4、 0.7、 5.4 kg。【结论】南果梨周年干物质单株积累总量为41.4 kg,当年净积累量为19.7 kg。南果梨干物质积累主要集中在花期到果实膨大期和果实转色到落叶前,分别占47.3% 和47.5%。南果梨从萌芽到落叶前氮、 磷、 钾的单株净累积量分别为146.2、 20.1、 146.1 g,每1000 kg果实经济产量需吸收氮(N)、 磷(P)、 钾(K)5.4、 0.7、 5.4 kg。从开花到果实膨大期和从果实着色到采收后30天对氮吸收分别占总氮累积量的39.0%和49.0%,而磷、 钾的累积从萌芽到开花较快,到果实膨大期磷的累积达67.4%,钾的累积达65.1%,果实膨大期是干物质和氮磷钾积累的关键时期。     

Response of labile organic C and N pools to plastic film removal from semiarid farmland soil

To examine the effects of plastic film removal on grain yield and soil organic matter (SOM), a spring maize (Zea may L.) field experiment was conducted for 5 yr at Changwu Agricultural and Ecological Experimental Station of Northwest China. Compared with traditional plastic film mulching during entire growing stages (FM), plastic film removal at the silking stage (RM) resulted in a 6.3% higher average maize yield. Under the RM treatment, soil organic carbon and total nitrogen significantly increased after the 5‐yr cultivation in the 0‐ to 20‐cm layer. Significant increases in extractable organic C (EOC), KMnO₄‐oxidizable C (KMnO₄‐C) and C management index (CMI) in the 0‐ to 20‐cm layer, and light fraction organic C and EOC in the 20‐ to 40‐cm layer were observed in response to plastic film removal after the 1‐yr treatment; the responses were more significant after 5 yr. Under the RM treatment, significant increases in microbial biomass C, light fraction organic N, extractable organic N, KMnO₄‐C and CMI were also observed after five years in the 20‐ to 40‐cm layer. Moreover, KMnO₄‐C and EOC were much more sensitive than other labile SOM fractions to the application of RM, even after only 1 yr of cultivation. Therefore, compared with mulching for the whole growing season, plastic film removal at the maize silking stage is an effective option for increasing yields and enhancing SOM concentration and soil sustainability in the regions with semiarid monsoon climates that have sufficient rainfall during maize reproductive stages.     

特优航2号在龙海的产量表现及高产栽培技术

介绍了特优航2号参加福建省区试、生产试验以及在龙海示范种植的表现。调查了特优航2号不同产量水平的产量构成,明确有效穗与产量的相关最密切,对产量直接通径系数最高,对产量贡献率最大;其次为每穗总粒数,有效穗与每穗总粒数对产量的贡献率占4个构成因素总贡献率的86.39%。据此提出特优航2号高产栽培技术。     

优化施肥对春小麦产量、氮素利用及氮平衡的影响

2009 ～ 2010年,在宁夏引黄灌区分别以宁春11号和宁春16号小麦为供试作物,利用田间试验研究了优化施肥(OPT)和习惯施肥(CON)对春小麦产量、氮素吸收利用和土壤硝态氮累积的影响,表观评估了土壤—小麦体系氮素平衡.结果表明,相对于CK处理,OPT和CON都显著提高春小麦籽粒产量地上部生物量,并促进籽粒N和地上...     

微藻水热液化有机相最佳回收工艺研究

以微拟球藻为原料,研究微藻水热液化过程中多种参数对水热液化后有机物回收率的影响,包括温度、时间、溶剂比和pH等,从而获得微藻水热液化后有机物的最佳回收工艺条件。结果显示,在室温下进行有机相回收,保证回收溶剂比为20∶1(溶剂/水相不溶物;v/wt)、停留时间为10min、回收pH7,即可达到最佳回收效果。最佳条件下水热液化有机相的回收率为34%左右,且不同的回收温度和pH值对回收的有机相组分均会产生影响。     

拔节期氮肥运筹对不同滴灌量下冬小麦光合特性及产量的影响

为探明拔节期氮肥运筹对不同滴灌量下冬小麦光合特性及产量的影响,在大田滴灌技术条件下,以‘新冬41号’为试验材料,研究4种拔节期氮肥运筹处理[N0(0 kg/hm²)、N1(90 kg/hm²)、N2(180 kg/hm²)、N3(270 kg/hm²)]对3种不同滴灌量[W1(1500 m³/hm²)、W2(3000 m³/hm²)、W3(3450 m³/hm²)]下冬小麦叶绿素含量（SPAD值）、叶面积指数(LAI)、叶片光合特性及产量的影响。结果表明,在3种滴灌量下各氮肥处理冬小麦拔节至乳熟期叶片SPAD值均呈“先增后降”的变化规律,最大值均在灌浆期;LAI呈现“先增后降”的变化规律,在孕穗期达最大。在同一施氮水平下,滴灌量增加,叶片的净光合速率(Pn)、蒸腾速率(Tr)、气孔导度(Gs)均增加,而胞间CO₂浓度(Ci)则降低。滴灌量较低时（W1处理）,增加拔节期施氮量能有效提高滴灌冬小麦的有效穗数、穗粒数、千粒重、产量和收获系数;水分充足时（W2、W3处理）,增加拔节期施氮量反而不利于产量的提高。综合考虑各项产量指标及氮肥利用效率得出,在滴灌量3000 m³/hm²条件下,拔节期施氮量180 kg/hm²时,滴灌冬小麦籽粒产量较高,氮肥利用率最大,可供生产参考。     

黑木耳简单快速组织分离新法

利用酒精、镊子对黑木耳耳片进行组织分离,方法方便、快捷,分离成功率100%。     

覆膜滴灌玉米产量和农艺性状相关性分析

为明确在覆膜滴灌条件下玉米品系(种)主要农艺性状与产量的关系,应用DPS软件对15个玉米杂交品系(种)的主要农艺性状和产量性状进行相关性、灰色关联度等分析,结果表明:籽粒重、穗重、产量的变异系数较大;玉米产量与生育期、籽粒水分含量、穗重、籽粒重呈显著正相关关系;聚类分析可将参试的15个品系(种)划分为3类,第Ⅲ类表现良好,值得进行推广种植。灰色关联度分析表明,玉米籽粒重、穗重、生育期、籽粒水分含量等性状是影响玉米产量的主导因素,在玉米高产育种中,应以其为主攻目标,提高玉米后代的有效选择,加速高产育种进程。     

种植密度对滴灌马铃薯生长、产量的影响

为了了解耕培土滴灌条件下种植密度对马铃薯生长、产量以及水分利用效率的影响.试验共设密度分别为7.28×10⁴ 株/hm²(RS25),6.67×10⁴ 株/hm²(RS35),5.55×10⁴ 株/hm²(CK)3个处理.结果表明:随着种植密度的增加,株高、茎粗、干物质积累量以及商品薯率均有降低的趋势;产量、水分利用效率随种植密度的增加表现出先增大后减少,其中RS35处理产量和水分利用效率均表现最高,分别达到47 325 kg/hm²和12.05 kg/m³;在马铃薯品质方面,种植密度对马铃薯粗蛋白含量的影响不具有统计学意义;淀粉和维生素C随着密度的大幅增加而降低,其中RS25处理的淀粉较CK降低了5.57%,RS25处理的维生素C较CK降低了7.96%,同时RS35与CK处理不具有统计学意义.综上所述,种植密度为6.67×10⁴ 株/hm²的RS35处理马铃薯高产优质,且水分利用效率最高,为黑龙江地区滴灌马铃薯较为适宜的种植密度.