集中排水甘蔗地酸性硫酸盐土壤酸化的减缓

Recent research results suggest that acidification of acid sulfate soils may be inhibited in well-drained estuarine floodplains in eastern Australia by the absence of natural creek levees,The lack of natural levees has allowed the inuudation of the land by regular tidal flooding prior to the construction of flood mitigation work.Such physiographical conditions prevent the development of pre-draingae pyrite-derived soil acidifica-tion that possibly occurred at many levee-protected sites in eastern Australian estuarine floodplains during extremely dry spells.Pre-drainage acidification is considered as an important condition for accumulation of soluble Fe and consequently,the creation of favourable environments for catalysed pyrite oxidation.Under current intensively drained onditions,the acid materials produced by ongoing pyrite oxidation can be rapidly removed from soil pore water by lateral leaching and acid buffering,resulting in low concentrations of soluble Fe in the pyritic layer,which could reduce the rate of pyrite oxidation.     

几种利用方式下酸性硫酸盐土的环境风险及其连锁效应

研究并比较了不同利用方式下酸性硫酸盐土酸形态和铝形态的结构特征,分析了硫形态与酸形态、酸形态与铝形态之间的相关性。研究发现,酸性硫酸盐土的不同利用类型中,土壤酸度由大到小依次为:鱼塘塘基、荒稻田>稻田>荒旱地>改良稻田>蔗田>红树林迹地;活性铝含量由高到低依次为:荒旱地>鱼塘塘基、荒稻田>稻田>改良稻田>蔗田>红树林迹地。土壤酸度和铝形态含量的层间差异较为显著,多数随深度增加呈逐渐上升的趋势。酸性硫酸盐土中的硫形态—酸—铝形态之间有明显的连锁关系。     

Molecular Monitoring of SRB Community Structure and Dynamics in Batch Experiments to Examine the Applicability of in situ Precipitation of Heavy Metals for Groundwater Remediation (15 pp)

Background, Aims and Scope   Sulfate-reducing bacteria (SRB) are known for their capacity to reduce and precipitate heavy metals (HM) as metal sulfides, offering the opportunity to create an in situ reactive zone for the treatment of heavy metal-contaminated groundwater, a process called in situ metal precipitation (ISMP). The applicability of the ISMP technology first has to be investigated at a laboratory scale before going into an on site application. The evaluation and optimization of the ISMP process is facilitated when physical/chemical analysis techniques are combined with molecular tools that specifically monitor the abundance, diversity and dynamics of the indigenous sulfate reducing microbial community. In this study, batch experiments were conducted in order to investigate the feasibility of ISMP as a groundwater remediation strategy for an industrial site contaminated with elevated levels of Zn, Cd, Co and Ni. Methods   The potential of different types of carbon source/ electron donor (lactate, acetate, methanol, ethanol, Hydrogen Release Compound?, molasses) to stimulate the sulfate reduction and metal precipitation activity of the naturally present (or indigenous) SRB community was explored. In addition, the effect of amending vitamin B12 and yeast extract was evaluated. The ISMP process was monitored by combining analytical analyzes of process parameters (SO42-concentration, heavy metal concentrations, pH, Eh) with molecular tools such as SRB subgroup and genus specific PCR, denaturing gradient gel electrophoresis (DGGE), and phylogenetic analysis of clone sequences, based on either the 16S rRNA or the dsr (dissimilatory sulfite reductase) gene. Results and Discussion   The efficiency of different carbon-sources to stimulate the ISMP process followed the order HRC 〉 molasses 〉 methanol 〉 lactate 〉 ethanol 〉 acetate. Within 10 weeks, the highest sulfate and metal removal efficiencies ranged from 85% to 99%. Addition of yeast extract boosted the ISMP process, whereas vitamin B12 negligibly affected SRB activity. Analysis of the sulfate reducing population by SRB subgroup and genus specific PCR demonstrated that members of the genus Desulfosporosinus dominated in all batch tests, while 16S rDNA DGGE profiles additionally revealed the presence in the microbial communities of non-sulfate reducing bacteria within the family Clostridium and the -proteobacteria. The dsrB-based DGGE profiles allowed us to assess the diversity and dynamics of the sulfate reducing community and added to a better understanding of the effects of different batch conditions on the ISMP process. Remarkably, all dsrB sequences affiliated with the dsrB gene sequence cluster found in Desulfotomaculum, which received their xenologous dsrB gene from the -proteobacteria. Conclusions   The batch experiments, which aimed at stimulating the activities of the indigenous SRB communities, demonstrated that these communities were present and that their activities could be used to obtain efficient in situ precipitation of the contaminating heavy metals. This opens the possibility to test this concept in the future as an on site demonstration as part of the groundwater strategy for the heavy metal contaminated site. Although batch setups are suitable for preliminary feasibility studies for ISMP, they do not reflect the in situ situation where sulfate and heavy metal and metalloid polluted groundwater are supplied continuously. A sulfate reducing strain JG32A was isolated from whose 16S rRNA gene affiliated with the genus Desulfosporosinus, while its dsrB gene sequence clustered with Desulfotomaculum dsrB gene sequences, which received their xenologous dsr genes from -proteobacteria. Therefore we hypothesize that the batch experiments enrich members of the Desulfosporosinus genus that possess a non-orthologous dsrB gene. Recommendation and Perspective   The next step towards an on site pilot test for ISMP will be the setup of a series of column experiments, with process conditions that are selected based on the above mentioned results. This will allow to define optimal ISMP process conditions and to test its long-term efficacy and sustainability before going into an on site bioremediation application. By applying the described molecular tools together with physical-chemical analyzes, it can be investigated whether the same SRB community is enriched and which type of C-source is most effective in promoting and sustaining its growth and sulfate-reduction activity.     

Redox potential of bulk soil and soil solution concentration of nitrate,manganese, iron,and sulfate in two Gleysols

While the reduction of nitrate‐N, Mn(III,IV), Fe(III), and sulfate‐S in soil has been studied intensively in the laboratory, field research has received only limited attention. This study investigated the relationship between redox potential (E_H) measured in bulk soil and concentrations of nitrate, Mn²⁺, Fe²⁺, and sulfate in the soil solution of two Gleysols differing in drainage status from the Marsh area of Schleswig‐Holstein, Northern Germany. The soils are silty‐sandy and developed from calcareous marine sediments. Redox potentials were monitored weekly with permanently installed Pt electrodes, and soil solution was obtained biweekly by ceramic suction cups from 10, 30, 60, and 150 cm depth over one year. Median E_H at 10, 30, 60, and 150 cm depths was 470, 410, 410, and 20 mV in the drained soil and 500, 480, 30, and –170 mV in the undrained soil, respectively. A decrease in E_H below critical values was accompanied in the soil solutions (pH 7.4 to 7.8) by disappearance of nitrate below 0 to 200 mV, appearance of Mn²⁺ below 350 mV, and Fe²⁺ below 0 to 50 mV. Both metals disappeared from soil solution after aeration. In the sulfide‐bearing environment of the 150 cm depth of the undrained soil, however, the sulfate concentrations were highest at such E_H values at which sulfate should be unstable. This discrepancy was reflected in the fact that at this depth bulk soil E_H was about 400 mV lower than soil solution E_H (250 mV). When investigating the dynamics of nitrate, Mn, and Fe in soils, bulk soil E_H provides semi‐quantitative information in terms of critical E_H ranges. However, in sulfidic soil environments the interpretation of E_H measured in bulk soil is uncertain.     

硫酸铜蓄积对日本蟳4种组织细胞超微结构的影响

通过蓄积毒性试验,研究了安全质量尝试（0.5mg.L-1）硫酸铜（CuSO45H2O）对日本蟳（Charybdis japonica）4种组织细胞（肌肉、鳃、肝胰脏和心脏）超微结构的影响。结果表明CuSO45H2O主要损伤的组织是鳃和肝胰脏,其次是心脏和肌肉。鳃细胞的损害表现为鳃丝水肿,细胞器溶解,角质层变薄,线粒体、内质网的肿胀、解体;肝胰脏细胞的主要损害特征为肝管微绒毛减少,线粒体水肿解体,内质网扩张,细胞核空泡化,核膜水肿和脂肪滴增加;心脏细胞的毒理变化为线粒体内嵴肿胀、瓦解,肌原纤维不规则,内质网溶解。安全浓度的CuSO45H2O经过16d蓄积后虽然没有导致日本蟳死亡,但已经对其体内组织细胞的超微结构产生了不同程度的影响。

     

阿维菌素等三种常规渔药对卡拉白鱼的急性毒性

采用半静态法,研究了三种常规渔药阿维菌素、三氯异氰脲酸和硫酸铜对卡拉白鱼(Chalcalburnus chal coides aralensis)急性毒性效应。结果表明:阿维菌素对卡拉白鱼24、48、72、96 h的半致死浓度分别为6.25、4.66、3.66和2.82 mg/L,安全浓度为0.77 mg/L;三氯异氰尿酸对卡拉白鱼24、48、72、96 h的半致死浓度分别为3.22、2.49、2.19、1.79 mg/L,安全浓度为0.45 mg/L;硫酸铜对卡拉白鱼24、48、72、96 h的半致死浓度分别为5.56、3.96、2.03、1.74 mg/L,安全浓度为0.6 mg/L。三种药物对卡拉白鱼毒性高低依次为:硫酸铜三氯异氯尿酸阿维菌素。三种常规渔药的安全浓度近于或高于生产中常用泼洒浓度,可放心使用。     

黑荆木材及其KP、CTMP的纤维形态研究

研究表明黑荆木材１—３年生密度为０．５９—０．６５ｇ／ｃｍ３，５—１０年生为０．７２ｇ／ｃｍ３；１—７年生木材成分变化不大，纤维素在４５％以上，半纤维素在２５％以下，木素在２１％以下。比较６年生黑荆木材及其ＫＰ、ＣＴＭＰ的纤维形态，纤维长度在０．７６ｍｍ以上的，木材为７２．０４％、Ｋｐ为７２．２２％、ＣＴＭＰ为８２．５８％；平均纤维长度木材为０．８５６ｍｍ、ＫＰ为０．８４５ｍｍ、ＣＴＭＰ为１．１６５ｍｍ；纤维宽度在１２一２４μｍ，木材为９２．６２％、ＫＰ为９２．８６％、ＣＴＭＰ为３４．６３％；平均纤维宽度木材为１５．６μｍ、ＫＰ为１５．８μｍ、ＣＴＭＰ为３０．７μｍ；长宽比木材为５４．９、ＫＰ为５３．３、ＣＴＭＰ为３７．９。     

超滤—离子层析法精制猪硫酸软骨素

采用超滤—离子层析法精制猪硫酸软骨素,离子对反相高效液相色谱法测定其含量,红外吸收光谱法测定其结构.研究了超滤液温度、超滤压力、超滤液pH对猪硫酸软骨素精制时膜通量和得率的影响.结果表明:超滤—离子层析技术可应用于精制猪硫酸软骨素.猪硫酸软骨素超滤的工艺条件:以微孔滤膜处理原料液,超滤膜的截留分子量10 kD,超滤压力0.25MPa,超滤温度25℃,溶液pH为9.产物纯度为95.74％,产率为80.15％.该方法精确度和准确度都较高,可用于猪硫酸软骨素的精制.     

Biofortification of onion bulb with selenium at different levels of sulfate

In this research experiment, two commercial onion cultivars (Allium cepa L., cvs. Dorrcheh and Cebolla Valenciana) were grown in sand culture and exposed to two levels of selenium (Se) (0 and 25?µM) and two levels of sulfate (1 and 3?mM). According to the results obtained, addition of 25?µM Se in combination with 3?mM sulfate was not only effective in significant increase of onion bulb yield, but it significantly increased Se concentration of bulb. By considering the average consumption of onion in central Iran, the daily intake of Se via consumption of Se-biofortified onion is estimated to be 68.4–77.2?µg in spring and summer and 72.6–117.1?µg in fall and winter. These amounts of daily intakes of Se is higher than the sufficient levels of Se recommended by world health organization (WHO) but less than the maximum tolerable level of Se (400?µg Se per day) for human.     

澳洲酸性硫酸盐土壤的特征、问题及管理

Acid sulfate voile (ASS), widely distributed in Australia. This has only been recognised recently when intensive rmearch on ASS has been done in this country. This paper reviews aspects concerning a) the distribution and acid potential, b) controls on acidic status, and c) problems and management of ASS in Australia. It is believed that the Australian experience may be useful for other countries where potential problems from ASS exist but insufficient attention was paid to them.