Search Results (187)

Black-odorous water pollution presents a serious threat to aquatic ecosystems and severely hinders the sustainable development of the ecological environment, as conventional remediation technologies often fall short in achieving the simultaneous removal of multiple pollutants. In this study, a novel composite remediation agent was developed by integrating microbial active components with modified clay minerals—sodium-modified zeolite (Na-Z) and magnesium–aluminum–lanthanum layered ternary hydroxides loaded onto sulfuric acid-modified bentonite (Mg-Al-La-LTHs@SBt)—through gel-embedding immobilization. This integrated system enabled the synergistic remediation of both overlying water and sediment pollutants. The modified clay minerals exhibited strong adsorption capacity for nitrogen and phosphorus compounds in the overlying water. Under 25 °C conditions, the composite agent achieved removal efficiencies of 58.14% for ammonium nitrogen (NH₄⁺-N) and 88.89% for total phosphorus (TP) while significantly reducing sedimentary organic matter and acid volatile sulfide (AVS). Notably, the agent retained substantial remediation efficacy even under low-temperature conditions (5 °C). High-throughput microbial community analysis revealed that the treatment enriched beneficial phyla (e.g., Proteobacteria) and beneficial genera (e.g., Thiobacillus) and suppressed sulfate-reducing groups (e.g., Desulfobacterota), promoting favorable nitrogen and sulfur transformations. These results provide a robust material and methodological basis for efficient, synergistic restoration of black-odorous water and the sustainable development of water resources. Full article

Volatile organosulfur compounds (VSCs) play significant roles in atmospheric chemistry and malodorous pollution. Accurate measurement of VSCs is challenging due to their high reactivity and adsorption tendencies, which are strongly influenced by sampling materials. This study comprehensively evaluates the performance of six types of sampling bags and passivated canisters for measuring nine VSCs. The results indicate that passivated canisters provide stable storage for all target VSCs for up to 7 days under dry conditions. Among the bags, polyvinyl fluoride (PVF) bags exhibited the lowest blank levels and preserved most VSCs (except disulfides) stably for 8 h. Field comparisons in a power battery recycling plant showed good agreement between PVF bag and canister measurements under dry conditions. However, in high-humidity stack gases, canisters showed severe losses of methanethiol and ethanethiol, likely due to humidity-driven conversion on metal surfaces, underscoring the necessity of drying humid-air samples. The application of these methods revealed significant VSCs emissions and distinct compositional profiles from power battery recycling processes, particularly pyrolysis drying, lithium leaching, and nickel–cobalt leaching processes, with concentrations of total VSCs reaching up to 1046.86 ppb. This work provides crucial guidance for selecting appropriate sampling methods for reliable VSCs measurement and offers the first emissions characteristics of VSCs from the power battery recycling industry, supporting future environmental monitoring and pollution control. Full article

Urban wetlands are strategic socio-ecological systems that provide diverse cultural ecosystem services, including recreation, environmental education, and spiritual connections with nature. At the same time, they can generate ecosystem disservices, undermine human well-being, and challenge urban sustainability. This study investigates visitors’ perceptions of such disservices in three Ramsar-designated wetlands in Bogotá, Colombia (Santa María del Lago, Juan Amarillo, and Córdoba) to assess their influence on tourist experiences and their potential role in fostering urban peace. A mixed-methods approach was employed, combining structured surveys, quantitative analysis, and qualitative coding. The results reveal that pollution, insecurity, and unpleasant odors significantly reduce visitors’ willingness to return, with notable variations across gender groups and wetland sites. Visitors also emphasized the need to strengthen infrastructure, surveillance, and environmental education. These findings underscore the importance of incorporating disservice analysis into wetland governance as a strategy to advance regenerative tourism, promote environmental justice, and support peacebuilding in Latin American metropolitan contexts, with broader implications for global urban sustainability. Full article

Freshwater quality criteria (FWQC) are essential scientific thresholds established to protect human health and aquatic ecosystems, serving as the foundation for water quality standards, environmental risk management, and pollution control. The latest research advancements were summarized, including the screening of priority pollutants for FWQC and the theory and methodology for environmental criteria in China in the last decade. The potential work has been meticulously analyzed and discussed concerning FWQC to be conducted in the short-term future. The possible prioritized list of pollutants for FWQC should be concerned with including nine categories of heavy metal ions, three categories of non-metal ions, and five categories of organic compounds in the short-term future research. The guidelines for deriving FWQC for the protection of human health for organoleptic effects and for sediment need to be modified and emphasized to ensure the safety of drinking water sources, address issues related to black and odorous surface water, and protect the biodiversity of benthic organisms. Toxicity data, water quality parameters, exposure data, and the geographical distribution of freshwater species should be systematically collected to support the development of FWQC in China. The potential applications of FWQC were also explored in the evaluation and formulation of WQS, ecological risk assessments, and the management of environmental emergencies and damage assessments to support environmental protection and management in China. Full article

Industrial odour is a common pollution concern raised with local regulatory authorities, with communities citing impacts to their mental health and wellbeing. We performed a systematic review to determine if industrial odours are associated with psychosocial wellbeing in nearby communities. PubMed, Medline, PsycINFO, and Web of Science were searched for peer-reviewed articles published between 2003 and 2023, assessing associations between industrial odour and psychosocial wellbeing (mental health or quality of life). Critical appraisal of the studies was conducted using JBI’s assessment tools. We undertook a narrative synthesis of results. After screening, 13 articles met the inclusion criteria: 11 cross-sectional and 2 longitudinal studies. Sample sizes ranged from 23 to 25,236 participants. Odour exposure was assessed through self-reported measures (intensity, annoyance) and objective measures (proximity to source, odorous chemical concentration). Psychosocial health outcomes included stress, psychological distress, quality of life, depression and anxiety. Of the 13 studies, 11 identified an association between odour exposure and poorer psychosocial wellbeing, with the strongest evidence relating to quality of life. However, the critical appraisal identified quality issues with most studies. The findings suggest that industrial odours may be associated with poorer psychosocial wellbeing for nearby residents, particularly in terms of quality of life. Future research using consistent objective and subjective measures of odour exposure, and prospective data collection, would strengthen the quality of the evidence. Full article

Electronic nose (e-nose) systems have emerged as transformative tools for odor and gas analysis, leveraging advances in nanomaterials, sensor arrays, and machine learning (ML) to mimic biological olfaction. This review synthesizes recent developments in e-nose technology, focusing on innovations in sensor design (e.g., graphene-based nanomaterials, MEMS, and optical sensors), drift compensation techniques, and AI-driven data processing. We highlight key applications across healthcare (e.g., non-invasive disease diagnostics via breath analysis), food quality monitoring (e.g., spoilage detection and authenticity verification), and environmental management (e.g., pollution tracking and wastewater treatment). Despite progress, challenges such as sensor selectivity, long-term stability, and standardization persist. The paper underscores the potential of e-noses to replace conventional analytical methods, offering portability, real-time operation, and cost-effectiveness. Future directions include scalable fabrication, robust ML models, and IoT integration to expand their practical adoption. Full article

Food waste from fish processing contributes significantly to environmental pollution, and fish skin is often discarded despite being a rich collagen source. This study evaluated the efficacy and consumer satisfaction of a ready-to-drink collagen supplement made from hydrolyzed collagen derived from seabass skin. The compositional analysis of this study revealed α-amino groups, hydroxyproline, and amino acids essential for skin elasticity, hydration, and tissue repair. A 30-day clinical trial was conducted in 36 Thai volunteers who were aged between 20 to 70 years, and their skin condition was assessed using a facial skin analyzer and a moisture analyzer on days 0, 15, and 30. Participants also completed self-perception and sensory satisfaction questionnaires. The results showed improved skin moisture, reduced pore size, and smoother skin texture. Participants reported high satisfaction, especially regarding increased moisture and skin smoothness. Sensory score evaluation showed favorable scores for color and taste; however, odor was the least preferred attribute with the lowest score. Notably, no adverse effects were reported throughout this study. The findings suggest that fish skin-derived collagen supplements can enhance skin appearance while offering a sustainable approach that converts fish by-products into functional skincare solutions aligned with global sustainability goals. Full article

The persistent issue of odor nuisance poses significant challenges to the sustainable development of livestock farming. While previous studies have primarily focused on individual gas concentrations, a comprehensive understanding of overall odor impact based on human perception remains limited. This study introduces a novel perspective by employing the odor activity value (OAV)—calculated from the ratio of gas concentration to its olfactory threshold—to evaluate the actual odor contribution of various compounds. Through a meta-analysis of data from 123 papers, we systematically assessed odor emission characteristics and mitigation strategies across different manure management stages. The results indicated that ammonia (NH₃) (with maximum concentration of 8056 ppm) and hydrogen sulfide (H₂S) (with maximum concentration of 20,057 ppm) were the most concentrated odor components in the whole manure management links. However, considering the olfactory threshold, trimethylamine (TMA) (with OAVmax 380800), H₂S (with OAVmax 48919512), butyric acid (with OAVmax 801684), and aldehydes (with OAVmax 11707) played major odor-causing roles. Notably, biological methods (83%), covering (77%), and additives (39%) were the most efficient odor mitigation strategies in the barn, manure storage, and manure treatment link, respectively. Therefore, employing the OAV-based approach is crucial for identifying priority pollutants and developing targeted control strategies across different livestock species and management stages, ultimately guiding more effective odor mitigation and healthier cohabitation. Full article

This study examines the impacts of industrial wastewater from the Uttara Export Processing Zone (UEPZ) on natural resources, agriculture, and the health of nearby communities in Nilphamari, Bangladesh. Using a quantitative, self-report approach, data were collected from 162 households across four villages in Nilphamari Sadar Upazila, selected based on proximity to the UEPZ. Findings reveal significant environmental degradation: almost all (96%) respondents reported that water in nearby rivers and ponds has changed color and is odorous, unpleasant to taste, and contaminated, harming aquatic biodiversity. Agricultural productivity has declined, with 67 percent of respondents experiencing reduced crop yields, increased crop diseases, and rising cultivation costs due to greater dependence on fertilizers and pesticides. Also, 96 percent of respondents reported that the fish population diminished, reducing alternative income sources. Health impacts were pronounced; 69 percent of the respondents experienced water pollution-related complications, including skin, respiratory, gastrointestinal, and eye problems. Perceptions of wastewater health risks were strongly aligned with reported illnesses. Binary logistic regression further indicated a positive association between degraded crop health and human health problems. The study concludes that UEPZ’s wastewater disposal negatively affects natural resources, agriculture, and public health, underscoring the need for improved waste management and mitigation to protect affected communities. Full article

Detection of soil pollution by petroleum products is necessary to remedy threats to economic and human health. Pollution by hydraulic oil often occurs through leaks from forestry machinery such as harvesters. Electronic noses equipped with gas sensor arrays are promising tools for applications of pollution detection and monitoring. A self-made, low-cost electronic nose was used for differentiation between clean and polluted samples, with two types of oils and three levels of pollution severity. An electronic nose uses the TGS series of gas sensors, manufactured by Figaro Inc. Sensor responses to changes in environmental conditions from clean air to measured odor, as well as responses to changes in sensor operation temperature, were used for analysis. Statistically significant response results allowed for the detection of pollution by biodegradable oil, while standard mineral oil was difficult to detect. It was demonstrated that the TGS 2602 gas sensor is most suitable for the studied application. LDA analysis demonstrated multidimensional data patterns allowing differentiation between sample categories and pollution severity levels. Full article

During heavy rainfalls, overflowing sewage water flows from the Combined Sewer Overflow (CSO) chambers and pollutes the Trnávka River in Trnava, Slovakia. This paper aims to propose water retention measures for the Trnávka River as a remediation technique for CSO-affected watercourses, which can contribute to the ‘flushing’ of the riverbed. During heavy rainfalls, the Trnávka River is polluted by solid, non-soluble materials, which produce unpleasant odors and are the subject of numerous complaints by citizens, particularly during low water levels. Three inflatable rubber weirs were designed, and their design was verified using a 1D numerical model of the Trnávka River. The simulations of the proposed measures performed in the HEC-RAS 5.0 software excluded the adverse effect of the backwater on the functioning of the CSO chambers in the city of Trnava during normal flow rates and confirmed that, even after installation of the weirs, the transition of the flood wave will pass in the riverbed, not causing the flooding of the adjacent area. The chemical–physical study of the Trnávka River confirmed our assumption that higher flow rates, which can be secured by the regulation of the proposed weirs, can contribute to the purity of the watercourse in the city of Trnava. Full article

Water pollution is a global concern, especially due to iron and manganese, which, at high concentrations, affect water quality by altering taste, odor, and color. This work explores the sustainable synthesis of hydrochar from orange peel and bagasse using hydrothermal carbonization (HTC) and a 2³ factorial design to optimize Fe²⁺ and Mn²⁺ removal for water treatment polishing. HTC was performed by varying (1) temperature (100–200 °C), (2) residence time (8–14 h), and (3) activation agent (H₃PO₄ or NaOH), with a central point at 150 °C for 11 h without activation. Characterization was performed using FTIR, TGA, SEM, nitrogen adsorption (BET) for surface area determination, elemental analysis, Brønsted acidity measurements, and zeta potential analysis. The hydrochar synthesized at 100 °C for 14 h with NaOH (HC6) showed the best Fe²⁺ and Mn²⁺ removal performance. The equilibrium time was 400 min, with pseudo-first-order kinetics best fitting the Fe²⁺ adsorption data, while pseudo-second-order kinetics provided the best fit for Mn²⁺ adsorption. The adsorption process was best described by the Freundlich and Langmuir isotherms, with maximum adsorption capacities (q_max) of 21.44 and 33.67 mg g⁻¹ for Fe²⁺ and Mn²⁺, respectively. It can be concluded that HTC-derived hydrochars offer a sustainable and efficient solution for Fe²⁺ and Mn²⁺ removal. This strategy presents a potentially valuable approach for sustainable water treatment, offering advantages for industrial application by operating at lower temperatures and eliminating the need for biomass drying, thereby reducing energy consumption and environmental impact. Full article

This study examines the assessment and management strategies for odor risks during emergency cleanup of VOC-contaminated waste. By analyzing illegally dumped VOC waste, the impact on odor intensity levels and exceedance probabilities in nearby residential areas was evaluated. Utilizing a VOC source emission model, a Gaussian plume dispersion model, and Monte Carlo simulations under various meteorological conditions, the effectiveness of the control measures was assessed. Key pollutants included ethylbenzene, toluene, styrene, and m/p-xylene, which, despite posing minimal short-term health risks (PHI: 0.17–0.64), exhibited significant odor risks (Odor PHI: 127–1156). At 20 m from the source, the probability of the odor intensity exceeding Level 2.5 approached 100%, decreasing to 85% at 50 m and further declining with distance. Atmospheric stability shifts—from very unstable (Class A) to stable (Class F)—increased the odor intensity from 0.5 to 2.5. Under moderately stable conditions (Class E), m/p-xylene had a 44.2% probability of exceeding an odor intensity level of 2.5. Even at 250 m, the odor intensity levels ranged between 1.2 and 1.7, remaining perceptible. Effective mitigation strategies include establishing appropriate buffer distances and using adsorption materials like activated carbon. Full article

The odour quality of atmospheric air plays an important role in the comfort of life and human health. Odours can originate from various sources, including municipal facilities, the agricultural and food sectors or industrial plants. A holistic approach to reducing the formation and emission of odorous substances should therefore include the development of odour-neutral process solutions, deodorisation techniques and analytics to measure and monitoring such pollutants in the atmosphere. The implementation of appropriate measures in these three areas can enable the effective management and control of odour emissions. The aim of the work is to carry out a comparative analysis of current methods for measuring the content of odorous substances in the air and for monitoring this type of pollutant. The characterisation of existing solutions carried out became the basis for determining the strengths and weaknesses of the applied protocols and indicating the directions for their further development and improvement. Full article

Many US states have adopted regulations to divert food waste from landfills to composts. While this may lower greenhouse emissions from landfills, volatile organic compound (VOC) emissions from compost may contain hazardous air pollutants or produce odors, posing potential public health concerns. Effective methods to analyze speciated VOCs in compost are needed to better understand VOC source generation. Here, a two-component compost sampling method was developed and employed consisting of a chilled impinger and pump apparatus to trap water-soluble VOCs, and dual sorbent tubes to capture hydrophobic VOCs in yard and food/yard waste compost. VOCs were measured via headspace gas chromatography with flame ionization detection (HS-GC-FID) and thermal desorption–gas chromatography–mass spectrometry (TD-GC-MS). Overall, there was higher VOC generation within higher-temperature compost piles, with concentrations ranging up to 27,000 ppm for ethanol and 3500 ppm for methanol. Alpha-pinene and D-limonene were seen in these piles with concentrations over 1600 ppb. Methanol and ethanol were more than one thousand times as concentrated in mixed food/yard waste than yard waste alone, while terpenes were seen in slightly higher concentrations for yard waste than the mixed food/yard waste. Methanol was observed to be higher than permissible indoor levels and may pose potential health risks. Full article