某电子废弃物拆卸区土壤、水和农作物中砷含量状况研究

为研究电子废弃物拆卸、废旧金属冶炼等是否对周围环境造成砷积累和污染,选取浙江省台州路桥区为调查对象,通过测定在该区采集的水、沉积物、土壤以及稻米和蔬菜中的砷,以了解该地区环境中砷的含量特征和潜在风险,并对土壤-水稻系统砷的分布和吸收转运规律进行了初步分析.结果表明,地表水和地下水砷含量平均值分别为 8.26μg/L和18.52μg/L,部分地下水超过WHO推荐的饮用水标准(10μg/L),但没有超过我国相关环境标准Ⅲ级限值(50μg/L).沉积物砷含量平均值为9.62mg/kg.水田土壤和菜地砷含量平均值分别为7.11mg/kg和6.17mg/kg,均在一级标准范围内,该区农田土壤总体上未受砷的污染.糙米和蔬菜中的砷平均值分别为165.1μg/kg和144.2μg/kg,均未超过我国规定的食品卫生标准.土壤-米糠-糙米中砷含量之间相关性显著.冶炼源周围的土壤和米糠中砷含量较其他源高,可能已经对周围土壤-水稻砷积累产生影响.     

Fate and transport of the β-adrenergic agonist ractopamine hydrochloride in soil–water systems

The feed additive ractopamine hydrochloride was fortified at four concentrations into batch vials containing soils that differed in both biological activity and organic matter(OM).Sampling of the liquid layer for 14 days demonstrated that ractopamine rapidly dissipated from the liquid layer. Less than 20% of the fortified dose remained in the liquid layer after 4 hr,and recoveries of dosed ractopamine ranged from 8 to 18% in the liquid layer at 336 hr. Sorption to soil was the major fate for ractopamine in soil:water systems, i.e., 42%–51% of the dose at14 days. The major portion of the sorbed fraction was comprised of non-extractables; a smaller fraction of the sorbed dose was extracted into water and acetone, portions which would be potentially mobile in the environment. Partitioning coefficients for all soils suggested strong sorption of ractopamine to soil which is governed by hydrophobic interactions and cation exchange complexes within the soil OM. Ractopamine degradation was observed, but to mostly non-polar compounds which had a higher potential than ractopamine to sorb to soil. The formation of volatiles was also suggested. Therefore, despite rapid and extensive soil sorption,these studies indicated a portion of ractopamine, present in manures used to fertilize soils,may be mobile in the environment via water-borne events.     

污灌对蔬菜的生理生态指标及细胞学影响研究

对污灌蔬菜的生态生理指标及细胞学影响的差异进行研究的结果表明,污灌菠菜的叶绿素含量和相对电导率分别是非污灌菠菜的85.30％和161％。污灌菠菜的硝酸盐含量比非污灌菠菜高出10％,污灌大蒜等不正常有丝分裂为11.3％,而非污灌大蒜为0     

Impacts of farmer field schools on productivity of vegetable farming in Indonesia

This study assesses the impact of farmer field schools (FFS) on the productivity of vegetable farming in vegetable‐producing areas of East Java and Bali, Indonesia. The FFS have equipped over 3,000 vegetable farmers with integrated crop management knowledge applicable to chilies and tomatoes. The FFS are expected to enhance farmers’ capacity such that they can increase production. This study employs a difference‐in‐differences (DiD) method to overcome selection bias. A survey of 250 FFS‐graduated farmers and 250 non‐FFS farmers were purposively randomly selected from the overall community of farmers. Focus group discussion was used to support the survey. The results indicate that FFS were successful for enhancing farmers’ capability in vegetable farming. Farmers who participated in FFS have higher productivity than those who did not. Farmers also could adapt and adopt the knowledge gained from FFS as they underwent a process of learning by doing. The impacts of the increase in farmers’ capacity can be more evident if weaknesses during the FFS preparation and implementation can be overcome, to ensure more participation, flexibility to fit different conditions/needs and continuous learning.     

湿式提砷法在处理工业废水及废渣中的应用

采用硫化法去除冶金工业酸性废水中的砷．除砷形成的含砷（ 主要成分 As₂S₃） 废渣用浓硫酸处理,废渣中的砷元素以 As₂O₃ 形式回收,纯度达99.4 ％ ,同时回收副产物硫磺等．试验结果表明,该方法的化学反应速度快,工艺过程稳定,砷的总回收率达95 ％ 以上,除砷效率可达99.99 ％ ．     

耐氨固氮菌对蔬菜作物生长的促进作用研究

研究并探讨了蔬菜作物在施用耐氨固氮菌后的生长、生理反应及增产的效果和原因。试验结果表明： 施用耐氨固氮菌显著增加了蔬菜苗期生物量、叶面积和叶片的叶绿素含量, 同时还增强了植株的根系活力, 并有明显的增产效果。耐氨固氮菌促进增产的作用不仅与其本身的固氮作用有关, 还可能与其分泌出某些生长刺激物 （ 或激素） 有关。     

植物油厂废水处理技术与实践

通过国内某植物油厂废水处理工程实例表明,废水按高低浓度分流处理,采取隔油—厌氧消化—化学混凝—耗氧生化处理工艺,能稳定达到国家要求的排放标准,同时降低工程投资和运行费用。     

宁波市鄞州区农作物农药残留现状与控制对策

对鄞州区种植的稻谷、叶菜类、水果类、豆类、茄果类和块茎类农产品按月进行了411个批次抽样,按照国家相关规定对22个农药项目进行了检测。检测结果发现样本农药项目检出率为0.3%,农产品农药残留合格率97.82%,农药残留检出项目中88.89%是杀虫剂。超出农药残留标准的样本主要是5-10月的青菜,叶菜类超标样本率达到3.72%。农药残留超标样本在平原、滨海地区种植散户中有发现,而在山区各规模农户中均有发现。小学文化程度农户样本农药残留超标率高达4.50%,是大学文化程度农户样本农药残留超标率的6.16倍。为了降低鄞州区农作物农药残留率,提出5方面的控制对策。     

通过式固相萃取/超高效液相色谱-串联质谱法测定蔬菜中18种农药残留

建立了超高效液相色谱-串联质谱(UPLC-MS;MS)快速测定蔬菜中18种农药残留的方法.样品经乙腈提取后,经Oasis PRiME HLB固相萃取柱净化,采用ACQUITY UPLC HSS T3 C18(50 mm×2.1 mm,1.8μm)色谱柱进行分离,以0.1%甲酸水溶液和乙腈作为流动相进行梯度洗脱.采用电喷雾电离源、正离子模式下以多反应监测(MRM)进行定性和定量分析.结果表明,18种农药在0.5—50μg·L^-1范围内线性关系良好(r2>0.995),方法最低检出限为0.4—1.5μg·kg^-1,最低定量限为1.4—5.0μg·kg^-1.在韭菜、芹菜、番茄、白菜基质中,5、10、50μg·kg^-1添加水平下的加标回收率为60.2%—126.9%,相对标准偏差(RSD)为0.4%—21.6%(n=3).     

生物炭对菜地土壤氮平衡及酸碱缓冲能力的影响

针对太湖地区菜地化肥氮投入量较大导致氮淋失严重及土壤酸化的现状,选取太湖地区的菜地土壤,利用盆栽试验连续种植三季小白菜,结合生物炭埋袋回收技术,研究不同化肥氮施用量(以N计,0和110 mg/kg)及生物炭添加量(w为0%、1%、2%和5%)对土壤氮淋失及酸碱缓冲能力的影响. 结果表明:在化肥氮施用量为110 mg/kg条件下,与无生物炭添加相比,生物炭添加量为2%时可使作物对土壤矿质态氮的利用效率提高约1倍(由41%增至81%),因化肥氮施用引起的土壤氮素残留量降低83%;生物炭添加可有效减少48%~65%的土壤氮淋失量,当添加量为1%、2%时,生物炭主要通过削减淋失液中ρ(TN)来降低土壤氮淋失量;添加量为5%时,则主要通过削减淋失液体积来实现. 无论是否添加化肥氮,生物炭均能有效维持土壤原有的pH、w(有机质)及w(盐基离子);促使土壤酸碱缓冲能容量增加22%~37%,致酸速率降低17%~80%,显著提升了土壤的酸碱缓冲能力. 研究显示,在化肥氮施用量为110 mg/kg条件下,生物炭添加量为2%时能对土壤酸化产生较好的缓冲效果.