Influence of Soil Chemistry and Plant Physiology in the Phytoremediation of Cu, Mn, and Zn

Different anthropogenic sources of metals can result from agricultural, industrial, military, mining and urban activities that contribute to environmental pollution. Plants can be grown for phytoremediation to remove or stabilize contaminants in water and soil. Copper (Cu), manganese (Mn) and zinc (Zn) are trace essential metals for plants, although their role in homeostasis in plants must be strictly regulated to avoid toxicity. In this review, we summarize the processes involved in the bioavailability, uptake, transport and storage of Cu, Mn and Zn in plants. The efficiency of phytoremediation depends on several factors including metal bioavailability and plant uptake, translocation and tolerance mechanisms. Soil parameters, such as clay fraction, organic matter content, oxidation state, pH, redox potential, aeration, and the presence of specific organisms, play fundamental roles in the uptake of trace essential metals. Key processes in the metal homeostasis network in plants have been identified. Membrane transporters involved in the acquisition, transport and storage of trace essential metals are reviewed. Recent advances in understanding the biochemical and molecular mechanisms of Cu, Mn and Zn hyperaccumulation are described. The use of plant-bacteria associations, plant-fungi associations and genetic engineering has opened a new range of opportunities to improve the efficiency of phytoremediation. The main directions for future research are proposed from the investigation of published results.

Avaliação da qualidade química e microbiológica de tintas didácticas do ensino pré-escolar

As tintas utilizadas nas actividades didácticas possuem na sua composição ingredientes que dada a sua natureza, modo de fabrico e de utilização, podem representar um risco para a saúde das crianças. Neste âmbito, procurou-se com este estudo avaliar a qualidade química e microbiológica das tintas utilizadas pelas crianças no ensino pré-escolar. Vinte e nove amostras de tintas, incluindo guaches, tintas de águas, digitintas e tintas para pinturas faciais foram recolhidas em oito estabelecimentos de ensino, nomeadamente, Jardins de Infância, do conselho de Vila Nova de Gaia. A avaliação microbiológica envolveu não só a determinação da concentração microbiana presente nas amostras, como também, a avaliação da estabilidade microbiana nas tintas das espécies S.aureus e E.coli. Na avaliação química procedeu-se à determinação da concentração dos metais chumbo (Pb), cádmio (Cd), crómio (Cr), cobalto (Co), níquel (Nq), manganês (Mn), cobre (Cu) e zinco (Zn) quer em algumas das amostras recolhidas nos estabelecimentos de ensino, quer em tintas adquiridas em três estabelecimentos comerciais. Os resultados obtidos da avaliação microbiológica revelam uma contaminação estática na generalidade das tintas. Três amostras de tintas apresentaram ainda elevada contaminação por fungos, nomeadamente Aspergillus spp. e Trichophyton spp. Da avaliação da estabilidade microbiana das espécies S.aureus e E.coli observou-se uma sensibilidade das mesmas às tintas, sendo evidenciado, em alguns casos, um decrescimento da concentração ao longo do tempo de exposição, e noutros, uma sensibilidade imediata. A espécie S.aureus revelou, contudo, maior capacidade de resistência que a E.coli. Os resultados obtidos da avaliação química revelaram a presença de Cr em todas as amostras, registando as tintas adquiridas em estabelecimentos comerciais concentrações mais elevadas para este metal. Os metais Cu e Zn foram detectados, em algumas amostras de tintas artísticas, em concentrações acima dos valores limites. Nas tintas para a cara foram encontrados os metais Pb, Cd, Cr e Nq, cuja utilização é interdita nestes produtos. O conhecimento das características químicas e microbiológicas das tintas utilizadas por crianças do ensino pré-escolar revelou-se de grande importância, nomeadamente, para a determinação dos riscos a que este grupo de indivíduos pode estar exposto no seu dia-a-dia quando utilizam estes produtos.

Multi-elemental analysis of ready-to-eat “baby leaf” vegetables using microwave digestion and high-resolution continuum source atomic absorption spectrometry

The mineral content (phosphorous (P), potassium (K), sodium (Na), calcium (Ca), magnesium (Mg), iron (Fe), manganese (Mn), zinc (Zn) and copper (Cu)) of eight ready-to-eat baby leaf vegetables was determined. The samples were subjected to microwave-assisted digestion and the minerals were quantified by High-Resolution Continuum Source Atomic Absorption Spectrometry (HR-CS-AAS) with flame and electrothermal atomisation. The methods were optimised and validated producing low LOQs, good repeatability and linearity, and recoveries, ranging from 91% to 110% for the minerals analysed. Phosphorous was determined by a standard colorimetric method. The accuracy of the method was checked by analysing a certified reference material; results were in agreement with the quantified value. The samples had a high content of potassium and calcium, but the principal mineral was iron. The mineral content was stable during storage and baby leaf vegetables could represent a good source of minerals in a balanced diet. A linear discriminant analysis was performed to compare the mineral profile obtained and showed, as expected, that the mineral content was similar between samples from the same family. The Linear Discriminant Analysis was able to discriminate different samples based on their mineral profile.

Copper, nickel and zinc removal by peanut hulls: batch and column studies in mono, tri-component systems and with real effluent

The main goal of this research study was the removal of Cu(II), Ni(II) and Zn(II) from aqueous solutions using peanut hulls. This work was mainly focused on the following aspects: chemical characterization of the biosorbent, kinetic studies, study of the pH influence in mono-component systems, equilibrium isotherms and column studies, both in mono and tri-component systems, and with a real industrial effluent from the electroplating industry. The chemical characterization of peanut hulls showed a high cellulose (44.8%) and lignin (36.1%) content, which favours biosorption of metal cations. The kinetic studies performed indicate that most of the sorption occurs in the first 30 min for all systems. In general, a pseudo-second order kinetics was followed, both in mono and tri-component systems. The equilibrium isotherms were better described by Freundlich model in all systems. Peanut hulls showed higher affinity for copper than for nickel and zinc when they are both present. The pH value between 5 and 6 was the most favourable for all systems. The sorbent capacity in column was 0.028 and 0.025 mmol g-1 for copper, respectively in mono and tri-component systems. A decrease of capacity for copper (50%) was observed when dealing with the real effluent. The Yoon-Nelson, Thomas and Yan’s models were fitted to the experimental data, being the latter the best fit.

Detection of ZnS phases in CZTS thin-films by EXAFS

Copper zinc tin sulfide (CZTS) is a promising Earthabundant thin-film solar cell material; it has an appropriate band gap of ~1.45 eV and a high absorption coefficient. The most efficient CZTS cells tend to be slightly Zn-rich and Cu-poor. However, growing Zn-rich CZTS films can sometimes result in phase decomposition of CZTS into ZnS and Cu2SnS3, which is generally deleterious to solar cell performance. Cubic ZnS is difficult to detect by XRD, due to a similar diffraction pattern. We hypothesize that synchrotron-based extended X-ray absorption fine structure (EXAFS), which is sensitive to local chemical environment, may be able to determine the quantity of ZnS phase in CZTS films by detecting differences in the second-nearest neighbor shell of the Zn atoms. Films of varying stoichiometries, from Zn-rich to Cu-rich (Zn-poor) were examined using the EXAFS technique. Differences in the spectra as a function of Cu/Zn ratio are detected. Linear combination analysis suggests increasing ZnS signal as the CZTS films become more Zn-rich. We demonstrate that the sensitive technique of EXAFS could be used to quantify the amount of ZnS present and provide a guide to crystal growth of highly phase pure films.