不同超富集、富集植物-玉米间作模式对玉米中镉吸收、转运的影响研究

为了研究Cd污染条件下,玉米分别与苋菜、黑麦草、龙葵间作对重金属Cd吸收和转运的特点,从而选择适宜与玉米间作的富集植物,同时达到修复重金属Cd污染土壤的目的。该文以镉(Cd)污染的河南棕壤黏土为供试土壤,通过盆栽试验,基于玉米各器官中Cd含量、富集系数、转运系数、土壤有效态Cd含量的变化,研究了间作苋菜、黑麦草、龙葵对玉米各器官Cd的积累特性的影响及其迁移转运机制。结果表明：(1)龙葵、苋菜、黑麦草间作使得玉米地上部Cd含量显著性降低(P<0.05),其中以籽粒中Cd含量的下降最为显著。间作苋菜、黑麦草、龙葵,玉米籽粒中Cd含量分别下降了67.6%、75.7%和79.9%。(2)间作苋菜、黑麦草、龙葵使得玉米的富集系数较单作处理下玉米的富集系数分别下降了49.3%、39.7%和68.5%,且差异达到显著水平。(3)与苋菜、黑麦草间作相比,间作龙葵的玉米转运系数分别下降了27.5%、24.2%,且差异均达到显著水平。通过对人体每天摄入Cd量的安全值计算得出间作后土壤中Cd全量应低于2.26 mg·kg-1,土壤有效态Cd含量低于0.88 mg·kg-1。该污染农田在间作模式下,食用玉米Cd暴露对居民健康不存在风险。间作苋菜、黑麦草、龙葵能够抑制玉米对Cd的吸收,同时阻控玉米地上部Cd向地上部的转移,尤其是向籽粒转移。通过间作苋菜、黑麦草、龙葵,不仅降低了主栽作物玉米的Cd累积量,实现玉米安全、优质种植,同时也达到了修复污染土壤的目的。     

黔西北土法炼锌区典型植物体内重金属的积累研究

本文测定了黔西北土法炼锌引起的重金属严重污染地区的自然植被及其根部土壤的重金属.土壤重金属形态用连续提取法区分为有效态和强结合态,结果发现植物体内的重金属含量与土壤中有效态的重金属含量成正比.所分析的4种植物体内的Pb、Zn、Cd含量为Zn＞Pb＞Cd.接骨草(Sambucus Chinensis)和柳叶苦荬菜(Ixeris gracilis)富集、运输重金属元素的能力很强,是对污染区生态重建颇有前景的植物.     

污水灌溉区包气带中重金属元素空间分布特征——以太原市某污水灌溉区为例

在距离灌渠不同距离的包气带中钻孔取样,测定了33个土壤样品中的pH值和Ba、Cr、Cu、Fe、Mn、Ni、Pb、Zn、土壤有机质的质量分数,对这8种重金属元素在土壤样品中的质量分数进行数据统计和空间分析。结果显示:①重金属元素Cr、Cu、Ni、Pb和Zn主要来源于污水,Fe、Mn和Ba除来源于污水外,还有一部分来源于土壤母质;②Cu、Cr、Pb、Zn和Ni的空间分布差异大,变异系数可达75.22%,主要富集表层0~0.3 m深度处和黏土层(黏土层起始深度在1.2~1.5 m,厚度40 cm)中,Fe、Mn和Ba在垂向上主要呈平均分布,空间分布的变异系数为19.09%~33.10%;③包气带中重金属元素平均含量超过当地土壤背景值的3~8倍,已经在包气带表层0~0.3 m深度处和黏土层中积累,而且Ba、Cu、Fe、Mn、Ni、Zn等重金属元素已经迁移到潜水层。     

喀斯特石漠化治理措施对土壤颗粒有机碳与团聚体有机碳的影响

文章以耕地为对照,分析不同石漠化治理措施（花椒林和次生林）对土壤0~20 cm土层有机碳(SOC)、颗粒有机碳(POC)、矿物结合有机碳(MOC)和团聚体有机碳的影响,探讨POC、MOC与SOC、团聚体有机碳的关系。结果表明:与耕地相比,花椒林和次生林均不同程度提高SOC、POC、MOC和团聚体有机碳含量。0~10 cm土层次生林SOC含量和各粒径团聚体有机碳含量均显著高于耕地和花椒林,在10~20 cm土层无显著差异;0~20 cm土层花椒林和次生林土壤POC含量显著高于耕地,MOC无显著差异。POC/SOC范围为20.38%~45.27%,花椒林和次生林显著高于耕地。相反,MOC/SOC为耕地显著高于花椒林和次生林 。退耕为花椒林和次生林后,SOC含量的增加主要以POC含量增加为主。次生林和花椒林>2 mm粒径对SOC贡献率显著高于耕地,但0.25~2 mm粒径、0.053~0.25 mm粒径和 < 0.053 mm粒径对SOC贡献率显著低于耕地。其相关分析表明:POC、MOC与SOC、团聚体有机碳的关系均呈正相关,表现为次生林 > 花椒林 > 耕地。退耕恢复为花椒林和次生林后,SOC、POC和MOC增加量与团聚体有机碳增加量显著相关,其以次生林的相关性较强。石漠化治理措施改变SOC物理组分及其组成以及它们之间的关系,从而促进有机碳的积累。      

Interactive effect of cadmium and zinc on chromium uptake in spinach grown in Vertisol of Central India

A pot culture experiment was conducted to study impact and interaction of multi-metals on growth, yield and metals uptake by spinach (variety All Green). Three levels of each chromium (0, 50 and 100 mg/kg), cadmium (0, 1 and 2 mg/kg) and zinc (0, 10 and 20 mg/kg) in combinations (total treatments 3 × 3 × 3 = 27) were applied in a Vertisol (5 kg). The results showed that increasing the concentration of chromium, cadmium and zinc in soil enhanced the respective metal concentrations in spinach root and shoot. When cadmium at 2 mg/kg along with chromium at 100 mg/kg soil was applied, chromium concentration and uptake were decreased in root and shoot. Meanwhile, zinc application had no significant effect on chromium uptake and concentration in spinach biomass. From the results, it was concluded that cadmium at higher dose had an antagonistic effect over chromium. On the other hand, in chromium, cadmium and zinc combinations particularly at their higher levels, a competition among each other was found. Therefore, the findings could be used as guidelines for controlling and management of heavy metals pollution in farmland.     

Heavy metal sources in Sultan Marsh and its neighborhood,Kayseri, Turkey

Sultan Marsh (Turkey) is one of the largest wet lands of the Middle East and Europe. The aim of this study was to determine average concentrations of heavy metals, variations of the obtained values in a large scale, geogenic and anthropogenic sources of the pollution and effects of the pollution on the environment in Sultan Marsh. To these aims, a total of 176 surface soil samples (0–10 cm depth) were collected from 80 ha land in Sultan Marsh. Using a bench-top Spectro-Xepos X-ray fluorescence spectrometer, we analyzed all samples to determine the near-total concentrations of 26 chemical elements. Basic and multivariate statistics were used for statistical analyses. GIS mapping, a powerful tool for identifying possible sources of pollutants, was used to classify and identify the elements. Relatively high concentrations of the elements Fe, Pb, Zn, Sb, W, Mo, Co, Cu, Hg, Ni, Cr, Mn and Cd were found in Sultan Marsh, surrounding rocks (geogenic sources), mines of Fe and Pb/Zn, industrial facilities, residential and agricultural areas and major traffic routes (anthropogenic sources).     

Effects of humic acid on heavy metal uptake by herbaceous plants in soils simultaneously contaminated by petroleum hydrocarbons

The effects of humic acid (HA) on heavy metal uptake by herbaceous plants in soil simultaneously contaminated with heavy metals and petroleum hydrocarbons were investigated. The results showed that HA reduced readily soluble and exchangeable forms of heavy metals in the contaminated soil but increased their plant-available forms. Potential bioavailability and leachability factors became larger than 1 after adding HA to the soil, except for those of Ni, suggesting that more heavy metals could be potentially phytoavailable for plant uptake. Furthermore, HA increased the accumulation of Pb, Cu, Cd, and Ni in the shoots and roots of selected plants. The greatest increase in the accumulation of heavy metals was 264.7 % in the shoot of Festuca arundinacea, with the bioconcentration factor (BCF) increasing from 0.30 to 1.10. Humic acid also increased the BCFs of the roots of Brassica campestris for Ni and Pb. These results suggest that HA amendment could enhance plant uptake of heavy metals, while concurrently reducing heavy metal leachability and preventing subsurface contamination, even in soils simultaneously contaminated with petroleum hydrocarbons.     

The use of vetiver grass (Vetiveria zizanioides) in the phytoremediation of soils contaminated with heavy metals

Recent research has shown that phytoextraction approaches often require soil amendments, such as the application of EDTA, to increase the bioavailability of heavy metals in soils. However, EDTA and EDTA–heavy metal complexes can be toxic to plants and soil microorganisms and may leach into groundwater, causing further environmental pollution. In the present study, vetiver grass (Vetiveria zizanioides) was studied for its potential use in the phytoremediation of soils contaminated with heavy metals. In the pot experiment, the uptake and transport of Pb by vetiver from Pb-contaminated soils under EDTA application was investigated. The results showed that vetiver had the capacity to tolerate high Pb concentrations in soils. With the application of EDTA, the translocation ratio of Pb from vetiver roots to shoots was significantly increased. On the 14th day after 5.0 mmol EDTA kg⁻¹ of soil application, the shoot Pb concentration reached 42, 160, 243 mg kg⁻¹ DW and the root Pb concentrations were 266, 951, and 2280 mg kg⁻¹ DW in the 500, 2500 and 5000 mg Pb kg⁻¹ soils, respectively. In the short soil leaching column (9.0-cm diameter, 20-cm height) experiment, about 3.7%, 15.6%, 14.3% and 22.2% of the soil Pb, Cu, Zn and Cd were leached from the artificially contaminated soil profile after 5.0 mmol EDTA kg⁻¹ of soil application and nearly 126 mm of rainfall irrigation. In the long soil leaching experiment, soil columns (9.0-cm diameter, 60-cm height) were packed with uncontaminated soils (mimicking the subsoil under contaminated upper layers) and planted with vetiver. Heavy metal leachate from the short column experiment was applied to the surface of the long soil column, the artificial rainwater was percolated, and the final leachate was collected at the bottom of the soil columns. The results showed that soil matrix with planted vetiver, could re-adsorb 98%, 54%, 41%, and 88% of the initially applied Pb, Cu, Zn, and Cd, respectively, which may reduce the risk of heavy metals flowing downwards and entering the groundwater.     

Uptake and fixation of Zn, Pb, and Cd by Thlaspi caerulescens: application in the cases of old mines of Mibladen and Zaida (West of Morocco)

Contaminated soils and mine tailings pose major environmental and agricultural problems worldwide. These problems may be partially solved by an emerging new technology: phytoremediation. This technique uses plants to extract soil contaminants from the ground. Thlaspi caerulescens is known to accumulate in their tissues several heavy metals from soil and aerial deposition. This study was conducted to screen plants growing on a contaminated site to determine their potential for metal accumulation. Seeds of T. caerulescens metallicolous have been collected in the vicinity of F.T. Laurent le Minier in the Pb–Zn mining district of les Malines (North of Montpellier, Southern France), and seeds of T. caerulescens non-metallicolous were sampled on Larzac Plateau (North of Montpellier, Southern France). Soil substrates were collected from a mine site of Mibladen and Zaida (West, Morroco). Cultivated plant and surface soil samples were analyzed for zinc, lead, and cadmium concentrations by inductively coupled plasma mass spectrometry. A non-metallicolous (NM) ecotype of T. caerulescens and a metallicolous (M) ecotype are compared for Pb, Cd, and Zn accumulation in shoot and root in five metal-contaminated soils and one uncontaminated soil. The growth of individuals from uncontaminated soil was greater than that of individuals from metal-contaminated soils. The NM populations had markedly higher root/shoot ratio compared to M populations. The results indicate that both ecotypes of T. caerulescens are highly tolerant of zinc and Cd. Ecotype NM had constitutively higher Zn uptake capacity than the M ecotype. T. caerulescens species accumulate higher amount of Zn and Cd in their tissues in polluted soil and, in both of the two ecotypes, the root Pb concentrations were much greater than those of the shoot Pb contents. From both uncontaminated and metal-contaminated soils, we conclude that T. caerulescens are interesting material for phytoremediation of zinc and cadmium.     

黑河中游间作灌溉农田的能量平衡

利用布设在黑河流域中游的张掖绿洲区的一套自动气象观测系统在2004年作物生长期内的完整资料,分析了黑河中游春小麦和玉米间作农田生态系统的辐射收支,在此基础上选用波文比能量平衡法(BREB)进行了能量平衡计算.结果表明:间作作物-土壤系统截获的太阳短波辐射占太阳总辐射的比例从生长初期的0.81持续增加到生长末期的0.86;净辐射在生长初期较小,生长中期第一阶段增幅大,至第二阶段达到最大,生长末期降低;净辐射占太阳总辐射的比例与净辐射的变化相似.能量平衡中,净辐射的消耗以潜热为主,占70%左右,感热能量占20%,土壤热通量占净辐射总值的10%.不同生长阶段的能量平衡差异较大,能量平衡在不同生长阶段呈现出不同的日变化特征.     

Chelate enhanced phytoremediation of soil containing a mixed contaminant

Greenhouse tests were conducted to study the effect of chelates on the phytoextraction of cadmium and lead, and the rhizodegradation of used engine oil present as a mixed contaminant in a sandy soil. Indian mustard plants were grown in test pot soil for 30 days and chelates ethylenediamine tetraacetic acid (EDTA) and ethylenediaminedisuccinic acid (EDDS) were individually applied to the test soil. The soil was spiked earlier with 50 mg kg^?1 of CdCl₂, 500 mg kg^?1 of PbCl₂ and 500 mg kg^?1 of used engine oil to form the mixed soil contaminant. At the same concentration of chelates, EDTA was found to be more effective than EDDS in increasing the concentration of metal contaminants Cd and Pb in the plant. Compared to EDDS, EDTA was also more effective in promoting rhizodegradation of the organic contaminant formed by used engine oil. The study demonstrated that the application of chelates to soils containing mixed contaminants such as heavy metals (Cd and Pb) and organics (used engine oil) can simultaneously assist metal accumulation at higher concentrations in the biomass of Indian mustard plant and also reduce the amount of used engine oil in the soil through rhizodegradation.     

Evaluation of soil loss change after Grain for Green Project in the Loss Plateau: a case study of Yulin,China

Soil erosion is one of the serious and urgent issues in the Loss Plateau of China. Chinese government has implemented Grain for Green Project to restore the ecological environment since 1999. In order to explore the spatiotemporal evolution of erosion and sediment yield before and after Grain for Green Project in the Loss Plateau, annual soil loss of Yulin from 2000 to 2013 is estimated by Chinese Water Erosion on Hillslope Prediction Model in conjunction with Remote Sensing and Geographic Information Systems. This model has the characteristics of a simple algorithm and can be applied to predict erosion in the Loss Plateau. The result shows that vegetation cover increased significantly after Grain for Green Project, and the annual average value of NDVI increased from 0.20 to 0.33. The spatiotemporal variations of soil erosion are largely related to rainfall erosion distribution, slope, and land use type. The overall soil erosion categories in the south region are higher than those of the northwest. Mid slopes and valleys are the major topographic contributors to soil erosion. With the growth of slope gradient, soil erosion significantly increased. The soil loss has a decreasing tendency after Grain for Green Project. Although the rainfall of 2002 and 2013 is similar, the soil loss decreased from 5192.86 to 3598.94 t/(km² a), decreasing by 30.33%. It is also expressed that soil loss appears a reducing trend in the same degree of slope and elevation in 2002, 2007, and 2013. Under the simulation of the maximum and the minimum rainfall, soil erosion amount in 2013 decreased by 29.16 and 30.88%. The study proved that GFG has already achieved conservation of water and soil. The results indicate that the vegetation restoration as part of the Grain for Green Project on the Loss Plateau is effective.     

Nutrient acquisition and yield response of Barley exposed to salt stress under different levels of potassium nutrition

A greenhouse experiment was carried out in 2002 at Jordan University of Science and Technology, Agricultural Experiment Station to examine the effect of potassium fertilization on the response of barley (Hordeum vullgare L.) to different soil salinity levels. Five levels of potassium (0, 0.2, 0.4, 0.6, and 0.8 g K per pot as KCl) and two salt levels (0.75 and 13 ds/m) were investigated in a split plot design with four replications. Soil salinity affected growth and yield component parameters in most of the cases. However, potassium application alleviated the stress condition and significantly (p < 0.05) improved dry matter yield and yield components in barley. The highest dry matter yield (19.63 g/ pot) of barley grown on the very saline soil was obtained in response to the highest potassium level (0.8 g K/ pot). Number of kernels per spike, number of tillers per plant, weight of kernels per spike and total top (shoot) dry weight were all significantly influenced by the main effects and their interaction. The content of nitrogen and Potassium in barley shoot was also increased due to potassium application. In general, the result of this experiment indicated that application of potassium to barley grown on saline soil medium could bring about improvements in yield and yield component parameters, which would otherwise suffer badly.