The objective of this research is to analyse the feasibility of reusing the fly ash waste, which is produced in biomass plants, during the production of renewable energy, for controlling phosphorus contamination in the wastewater being processed in sewage treatment plants. The research examines the efficiency of using different types of ash, obtained from representative biomass materials after combustion in an energy plant (paulownia wood, wheat straw and barley straw), in removing phosphorus from water. The ashes were respectively mixed with synthetic water, rich in phosphorus; then, using batch experiments, the effects that the pre-treatment of ash, adsorbent dosage, contact time and temperature had on the adsorption process were studied. The main results show that phosphorus adsorption by the tested ashes augments as temperature increases. Similarly, the adsorbed amount of phosphorus increases by increasing the dose of the adsorbent. In addition, the adsorption of phosphorus by these three materials has been described well by the Langmuir isotherm equation. It has been found that the removal process of phosphorus was endothermic. Finally, this study concludes that waste ash from biomass plants can be used to remove phosphorus from wastewater in sewage treatment plants.

Iron deficiency has been becoming a worldwide problem in crop cultivation. New approaches are desired to alleviate the iron-deficit chlorosis. Iron-containing nanomaterials could be effective to supply the iron to plants and promote plant growth. In this study, soil cultured watermelon plants were treated with 100, 200, and 400 ppm α- and γ-Fe₂O₃ nanoparticles (NPs), respectively. Growth and physiology parameters were investigated in a period of time. The study also evaluated the nutritional quality of watermelon fruit. Results showed that no elevation of plant growth or chlorophyll content was observed. All α- and γ-Fe₂O₃ NPs treatments had no positive influence on nutritional components including central and edge sugar content, and total amino acid content. An interesting result was that the vitamin C (VC) content of all NP treatments was significantly improved compared with the control group (without iron). In addition, we found that iron distribution of α- and γ-Fe₂O₃ NPs treatments was closely related to the concentrations of NPs. Both α- and γ-Fe₂O₃ NPs could accumulate in root, stem, and leaf of watermelon plants, but only 400 ppm γ-Fe₂O₃ NPs treatment was found to exist in watermelon fruit. Although no promotion of α- and γ-Fe₂O₃ NPs on the growth of watermelon plants was occurred, our results showed that both α- and γ-Fe₂O₃ NPs could enter plant roots and translocate upwards to other tissues. Our finds will provide data for the future applications of iron-containing nanomaterials in agricultural production. Graphical Abstract

In different parts of the world, it is verified that green areas provide an improvement in the quality and well-being of the population in the environmental and psychological aspects. In this study, the micronucleus test is performed in Tradescantia pallida (Rose) D.R. Hunt var. purpurea (TRAD-MCN) to detect the mutagenic potential of atmospheric gases in different situations of vehicular flow and urban green areas. Following the protocols for TRAD-MCN, the results obtained confirm the positive correlation between the intensity of vehicle traffic and the frequency of micronuclei. However, in regions with green areas, the results obtained with TRAD-MCN are inferior even with intense vehicular flow. The period of high temperatures and low relative humidity can potentiate the action of stressors on plant species used as a bioindicator. Because of the results found in this study, we can infer that green areas reduce the effects of polluting gases. We emphasize here the importance of preserving or creating parks and reserves in an urban environment to improve air quality and consequently the health of the population.

Layered double hydroxides (LDHs), known as a class of anionic clays, have attracted considerable attention recently due to their potential applications in different areas as catalyst materials, energy materials, and adsorbent materials for environmental remediation, especially for anionic pollutant removal. In this study, magnesium aluminum layered double hydroxide (MgAl-LDH) was synthesized by two methods: standard coprecipitation and urea hydrolysis. Their textural properties and morphologies were examined by X-ray powder diffraction (XRD), scanning electron microscopy (SEM), energy-dispersive X-ray spectroscopy (EDS), Fourier transform infrared spectroscopy (FTIR), thermogravimetry (TG) and differential (DTG) analysis, and point of zero charge (pHₚzc). The specific surface area was calculated from BET adsorption equation. The results indicated that the crystallinity and the regularity of the samples prepared by urea hydrolysis were much preferable to those prepared by the coprecipitation method. Their sorption properties toward phosphate were investigated and the experimental evidence showed that, at the initial concentration of 100 mg L⁻¹ and at room temperature, the LDH synthesized by urea hydrolysis had a percentage removal of 94.3 ± 1.12% toward phosphate ions while 74.1 ± 1.34% were uptaked by LDH synthesized by coprecipitation method, suggesting that the crystallinity affects the sorption capability. The sorption mechanism indicates that phosphate ions could be sorbed onto LDHs via electrostatic attraction, ligand exchange, and ion exchange.

Mechanically robust Fe₃O₄/porous carbon/diatomite composite monolith was prepared from waste corrugated cardboard box and diatomite via slurrying in FeCl₃ solution, dewatering, molding, and carbonization at 600 °C. The products were characterized by X-ray diffraction (XRD), field emission scanning electron microscope (SEM), N₂-adsorption/desorption, Raman spectroscopy, and ultraviolet-visible-near-infrared (UV-Vis-NIR) spectroscopy. The water wettability, photothermal conversion property, and solar steam generation performance of the products were also evaluated. Results showed that the presence of FeCl₃ led to the formation of more pores and magnetic Fe₃O₄ crystallites, while diatomite provided good hydrophilicity for the composite. The product exhibited light absorption above 65% within the wavelength ranging from 200 to1974 nm, and its surface temperature eventually increased by 30 °C under 0.25 sun irradiation due to photothermal effect. Moreover, solar steam yield under 0.25 sun irradiation for 3600 s was improved by 67% with the presence of the monolithic composite because of the occurrence of interfacial solar steam generation and heat transfer from the composite acted as a heat island.

Desiccation of the Namak Lake (NL) can result in the release of fine-grained dust contaminated with heavy metals, while there is little information available on the propagation of metals in the bed sediments of this lake. In this study, contamination of metals in the surface sediments of the NL was analyzed and the pollution status of sediments was assessed using geo-accumulation index (Igₑₒ), enrichment factor (EF), the consensus-based sediment quality guidelines (CBSQGs), and mean probable effect concentration quotient (mPECQ). Results indicated that metal concentrations at the southern part were higher than at the middle and northern parts of the lake. Possible reasons are (i) pollution loads mainly entered the lake through the rivers at the west and northwest, but accumulated at the southern parts, (ii) hard layer of salt covering the bottom of the NL at the northern part suppresses adsorption of metals to the sediment, and (iii) the muddy nature of sediments at the southern part makes it easier for metals to be absorbed. EF results showed that sediments at the southern part of the lake were moderately enriched with lead (Pb). The low Igₑₒ values suggested no pollution with the metals, and CBSQG values showed that the sediments of the NL were not toxic, while the mPECQ index suggested a toxicity probability of less than 25%. Cluster analysis classified the metals into two clusters. In general, the results showed that metal pollution in the surface sediments of NL was generally low although the concentration of Pb at the southern part of the lake was worrisome.

Graphene oxide has great potential for use as an adsorbent due to the high specific surface area, high negative charges, and abundant oxygen-containing functional groups. However, the difficulty of graphene oxide to separate from water renders it impractical for real water treatment. In the present study, a novel graphene oxide/hexadecyltrimethylammonium composite sponge (GO/HDTMA) was prepared and investigated for use as a filtration material for the removal of Cu(II) from water. The formed porous GO/HDTMA sponge was highly stable in water. The adsorption was spontaneous and exothermic, increasing with decreasing temperatures. The material showed good ability to remove Cu(II) with competing cations (K⁺, Na⁺, Ca²⁺, and Mg²⁺) present. Five cycles of adsorption-desorption-regeneration studies showed that, after adsorption, the material could be successfully regenerated for repeated use by using a 1-M HCl solution as the desorption reagent. At a sufficiently high dose, GO/HDTMA showed an excellent performance for Cu(II) removal from river water containing different coexisting solutes. Finally, our 30-day column study revealed that the GO/HDTMA sponge is a good filtering material for the removal of Cu(II) from river water. In conclusion, the GO/HDTMA sponge is an excellent adsorbent material for use in flow-through water treatment applications for Cu(II) removal.

Antibiotics are among the most extensively used pharmaceuticals worldwide. They are natural or synthetic drugs with the capacity to kill or inhibit the growth of microorganisms. Several antibiotics have been detected in aquatic environments, but little is known about their effects on non-target organisms, especially fish. The aim of this study was to evaluate the effects of the antibiotic nitrofurantoin (NTF) using zebrafish embryos as model organisms. To assess mortality and development effects, the embryos were exposed to 0, 4, 9, 44, 100, 223 and 500 mg/L of NTF. A sub-lethal range of concentrations (0, 0.001, 0.02, 0.32, 5.62 and 100 mg/L) was used for biomarker analyses, namely cholinesterase, lactate dehydrogenase, glutathione S-transferase and catalase. The results indicated low toxicity of NTF to zebrafish, with a 168 h-LC₅₀ value of 129.2 mg/L. The main effect on development was the loss of equilibrium related to the uninflated swim bladder (168 h-EC₅₀ = 96.72 mg/L). Biomarker activity was induced in concentrations as low as 0.02 mg/L (cholinesterase, lactate dehydrogenase, glutathione S-transferase). Exposure to NTF induced no significant effects on zebrafish larvae behaviour. In summary, short-term exposure of zebrafish embryos to NTF induced developmental alterations only at high concentrations. However, biochemical changes occurred at lower levels of exposure, suggesting long-term effects on fish populations. Graphical Abstract

Steelmaking slag, a by-product of the steel-refining process, could be used for removing boron excess from irrigation natural and waste waters, due to its strongly alkaline reaction. The objectives of this study were to: (a) establish the optimum conditions (external solution/adsorbent ratio, equilibration time) of boron adsorption by the slag, (b) assess the slag’s capacity to adsorb boron, and (c) study boron desorption from the slag with time. Boron adsorption increased with the increase of the external solution/adsorbent ratio up to the ratio of 200:1. Although, almost 40% of boron was adsorbed within the first hour of equilibration period, the adsorption gradually increased until the 72 h. The Langmuir adsorption maximum for boron was 145 mg g⁻¹, considerably higher than other adsorbents, like fly ash, calcite, and magnesia. At boron initial concentrations lower than 6 mg L⁻¹, slag removed 55% of boron and reduced it below the permissible levels for irrigation waters (< 4 mg L⁻¹) for most crops. The pH of the equilibrium solution was 10.3 ± 0.8 and dropped to acceptable levels for irrigation waters (< 8.5), after contact with atmosphere for 1 week. Almost 25% of boron was released from samples of boron-laden slag during the first hour of desorption. Consequently, steelmaking slag can be used effectively for removing boron excess from irrigation waters. However, attention should be given to the pH of the slag-treated waters. Furthermore, the disposal of boron-laden slag to soils should be practiced with caution to avoid possible boron phytotoxicity risk.

Surface architecting of the catalyst is a hopeful method to expand the surface property of the impetus material for upgrading their response towards the chemical reaction. In the present study, designing of the catalyst was carried out using specific transition metals to boost the simultaneous NO-CO conversion reaction catalytically. These metal oxide systems have been prepared using the combustion and wet impregnation method. Prepared oxides were characterized using XRD, BET, XPS, SEM, and TEM. Further, the surface phenomenon of the catalyst was monitored through H₂-TPR, O₂-TPO, NO-TPD, and CO-TPD studies. The highly remarkable activity was perceived by Pd-based modified manganese oxide-cobalt chromite system as compared with simple Pd-based manganese oxide and Pd-based cobalt chromite. The catalyst showed the highest activity for NO-CO redox reaction with T₁₀₀ at 170 °C. Also, good stability was observed with a runtime of 7 h.