中国玉米生产-消费体系养分流动分析

采用物质流和养分流相结合的分析方法, 沿玉米生产的肥料投入到玉米消费过程, 研究氮、 磷养分流动; 以2004 年为例, 分析了中国玉米生产消费过程中氮、磷养分流动特点和资源的利用效 率。2004 年玉米生产投入化肥氮(N) 549.6×104t、磷( P2O5) 211.2×104t; 共收获养分氮(N) 342.9×104t、 磷( P2O5) 139.4×104t, 其中75%的氮和68%的磷被利用, 最终进入家庭的氮占22.3%, 磷为15.0%; 秸 秆中氮的还田率只有47%, 磷的较高, 在80%左右, 可见秸秆还田是归还土壤磷的有效措施。玉米 生产要消耗大量的资源, 2004 年生产1t 玉米养分, 消耗的化肥氮、磷养分相当于煤5.2t、磷矿资源 12.1t。因此, 优化玉米整个生产与消费体系中养分的流动, 对于提高养分资源利用效率和减少资源 浪费具有重要作用。     

Phenotypic nutrient up-take differences in an alley cropping system in semi-arid Machakos, Kenya

ＩｎｔｒｏｄｕｃｔｉｏｎＩｎｔｈｅＦｉｆｔｈＦｒａｍｅｗｏｒｋＰｒｏｇｒａｍｍｅｏｆｔｈｅＥｕｒｏｐｅａｎＣｏｍｍｉｓｓｉｏｎ(ＥＣ,1999),ｕｎｄｅｒ“ｔｏｏｌｓｆｏｒｓｕｓｔａｉｎａｂｌｅｄｅｖｅｌｏｐｍｅｎｔ”,ｔｈｅｒｅｗａｓｒｅｃｅｎｔｌｙａｓｐｅｃｉａｌｃａｌｌｆｏｒｐｒｏｐｏｓａｌｓｆｏｒ“Ｔｅｃｈｎｏｌｏｇｉｅｓｆｏｒｓｕｓｔａｉｎａｂｌｅｐｌａｎｔａｎｄａｎｉｍａｌｐｒｏｄｕｃｔｉｏｎ:ｂｕｉｌｄｉｎｇｂｌｏｃｋｓｆｏｒｉｍｐｒｏｖｅｍｅｎｔ(ｆｏｒｓｍａｌｌｓｃａｌｅｏｒｅｎｖｉｒ…     

玉米铝（Al）胁迫研究初报

通过试验和分析，研究Ａｌ胁迫下的玉米生物性状和主要生理特性，明确活性铝浓度与玉米根系特征及地上部农艺性状之间存在极显著或显著的反比相关；活性铝的存在，降低玉米茎叶Ｎ、Ｐ、Ｋ等养分含量，提高叶片脯氨酸累积量；脯氨酸含量可作为玉米耐Ａｌ性的生理指标．     

丛枝菌根真菌与重金属的相互作用对玉米根际微生物数量和磷酸酶活性的影响

以玉米为供试植物 ,研究了砂培条件下不同丛枝菌根真菌 (Acaulosporalaevis,Glomuscaledonium ,Glomusmanihotis)与不同浓度重金属 (铜和镉 )的相互作用对菌根侵染率、孢子数、根际微生物数量和磷酸酶活性的影响 .在不同浓度的铜和镉中 ,G .caledonium的侵染率均最高 ,且随重金属浓度的增加而变化较小 ,而它的孢子数在这 3种接种处理中最低 .低量的铜 (0 .0 5mg/kg)可显著地减少不接种、接种A .laevis和G .manihotis的细菌数量 ,却能显著地增加接种处理的真菌数量 .当溶液中铜的浓度大于 0 .2mg/kg时 ,接种处理的真菌数量小于不接种处理的真菌数量 .铜或镉的浓度不同时放线菌数量均有接种远大于不接种 ,其中接种之间放线菌数量相差不大 ,且随重金属浓度增大而变化较小 .无论是不同浓度的铜还是不同浓度的镉的接种处理常有利于增加磷酸酶活性 .重金属浓度低时 ,细菌和真菌数量、磷酸酶活性变化较大 ,高浓度时变化较小 .图 7参 15     

玉米自交系吸收利用磷素的差异及其相关性

大田选取11份玉米自交系，在两个供磷水平下研究了玉米自交系籽粒产量基因型差异及吸收效率、利用效率与磷效率的相关关系。试验结果表明：在磷胁迫的条件下，不同玉米自交系不仅产量存在较大的差异，而且对磷的响应度也不相同，产量最高的基因型中宗2号为最低的忻9005的5．15倍，将这些品种在二磷水平下以产量进行磷效率双向划分可以分为4种类型：双高效型(太411、KH12、58、中宗2号)；高磷高效型(187)；低磷高效型(冀257)；双低效型(478、冀35、XL12、忻9005、H21)，成熟期吸收、利用效率与磷效率的关系表明，在同一供磷条件下，11份自交系吸收、利用效率均有显著的差异，在两个供磷水平下，吸收效率与磷效率存在显著的正相关关系，而利用效率仅在高磷条件下与磷效率存在正相关性，表明在低磷水平下，成熟期磷效率主要由吸收效率决定，在高磷水平下，磷效率是吸收效率和利用效率共同作用的结果。图2表1参7。     

纳米材料对玉米磷营养的影响初探

利用纳米材料处理水浇灌玉米(Zeamays),探讨了纳米材料对玉米磷营养的影响;用纳米材料处理水浸提磷矿粉,验证了纳米材料处理水对磷矿粉溶解性的促进作用。用纳米材料处理水浇灌玉米植株,可提高玉米的株高、茎粗以及生物量,使玉米植株地上部的氮磷钾的总量提高,同时可以提高植株中磷的含量7%~10%。取磷矿粉放于纳米材料处理水中,振荡、过滤,测定过滤液中的水溶性磷的含量,纳米材料可使磷矿粉浸提液中水溶性磷的含量较对照高20%~70%。利用纳米材料处理水提高磷矿的有效性,为提高磷的有效性、充分利用低品位磷矿提供了一条新的途径。     

盐胁迫下玉米幼苗ABA和GABA的积累及其相互关系

盐胁迫下玉米幼苗内源脱落酸(abscisicacid,ABA)和γ-氨基丁酸(gamma-aminobutyricacid,GABA)含量增加,且ABA的积累先于GABA.用100μmol/L外源ABA和150mmol/LNacl处理使玉米幼苗内源GABA含量增加,NaCl和ABA同时处理时,对玉米幼苗GABA积累的诱导表现加合效应.ABA生物合成抑制剂氟草酮预处理后使盐胁迫诱导的GABA含量增加幅度减小,说明在盐胁迫下ABA调节GBAA积累.NaCl和ABA处理均刺激谷氨酸脱羧酶(GAD)的活性,推测盐胁迫下ABA通过调控GAD的活性而导致GABA积累.图6参18     

Field scale interaction and nutrient exchange between surface water and shallow groundwater in the Baiyang Lake region, North China Plain

Fertilizer input for agricultural food production, as well as domestic and industrial surface water pollutants in the North China Plain, increases pressures on locally scarce and vulnerable water resources. In order to: (a) understand pollutant exchange between surface water and groundwater, (b) quantify nutrient loadings, and (c) identify major nutrient removal pathways by using qualitative and quantitative methods, including the geochemical model PHREEQC, a one-year study at a wheat (Triticum aestivum L.) and maize (Zea mays L.) double cropping system in the Baiyang Lake area in Hebei Province, China, was undertaken. The study showed a high influence of low-quality surface water on the shallow aquifer. Major inflowing pollutants into the aquifer were ammonium and nitrate via inflow from the adjacent Fu River (up to 29.8 mg/L NH₄-N and 6.8 mg/L NO₃-N), as well as nitrate via vertical transport from the field surface (up to 134.8 mg/L NO₃-N in soil water). Results from a conceptual model show an excess nitrogen input of about 320 kg/ha/a. Nevertheless, both nitrogen species were only detected at low concentrations in shallow groundwater, averaging at 3.6 mg/L NH₄-N and 1.8 mg/L NO₃-N. Measurement results supported by PHREEQC-modeling indicated cation exchange, denitrification, and anaerobic ammonium oxidation coupled with partial denitrification as major nitrogen removal pathways. Despite this current removal capacity, the excessive nitrogen fertilization may pose a future threat to groundwater quality. Surface water quality improvements are therefore recommended in conjunction with simultaneous monitoring of nitrate in the aquifer, and reduced agricultural N-inputs should be considered.     

煤矸石堆放场周围玉米作物中苯并(a)芘污染特征

以焦作矿区演马矿煤矸石堆放场周围农田玉米为研究对象,对玉米中苯并(a)芘污染特征进行了分析研究.在矸石堆周围布设三条采样线采集玉米样品,玉米样品经提取、浓缩、净化处理后采用高效液相色谱(HPLc)法对其中苯并(a)芘含量进行检测分析.结果表明,研究区玉米作物叶子中苯并(a)芘污染水平较高,达46.7%,茎和籽均未出现苯并(a)芘污染现象,且玉米各部位苯并(a)芘含量与距矸石堆距离呈反比.进一步指出矿区企业应加强对周围环境生态的预防保护,以确保企业的可持续发展.     

Concentration and dissipation of chlorantraniliprole and thiamethoxam residues in maize straw,maize, and soil

To study the dissipation rates and final residual levels of chlorantraniliprole and thiamethoxam in maize straw, maize, and soil, two independent field trials were conducted during the 2014 cropping season in Beijing and Anhui Provinces of China. A 40% wettable powder (20% chlorantraniliprole?+?20% thiamethoxam) was sprayed onto maize straw and soil at an application rate of 118 g of active ingredient per hectare (g a.i.ha^?1). The residual concentrations were determined by ultra-high-performance liquid chromatography–tandem mass spectrometry. The chlorantraniliprole half-lives in maize straw and soil were 9.0–10.8 and 9.5–21.7 days, respectively. The thiamethoxam half-lives in maize straw and soil were 8.4–9.8 and 4.3–11.7 days, respectively. The final residues of chlorantraniliprole and thiamethoxam in maize straw, maize, and soil were measured after the pesticides had been sprayed two and three times with an interval of 7 days using 1 and 1.5 times the recommended rate (72 g a.i. ha^?1 and 108 g a.i. ha^?1, respectively). Representative maize straw, maize, and soil samples were collected after the last treatment at pre-harvest intervals of 7, 14, and 28 days. The chlorantraniliprole residue was below 0.01 mg kg^?1 in maize, between 0.01 and 0.31 mg kg^?1 in maize straw, and between 0.03 and 1.91 mg kg^?1 in soil. The thiamethoxam residue concentrations in maize, maize straw, and soil were <0.01, <0.01, and 0.01–0.03 mg kg^?1, respectively. The final pesticide residues on maize were lower than the maximum residue limit (MRL) of 0.02 mg kg^?1 after a 14-day pre-harvest interval. Therefore, a dosage of 72 g a.i. ha^?1 was recommended, as it can be considered safe to human beings and animals.