Lehlogonolo P. Chuene, Josephine M. Letsoalo, Margaret H. N. Mollel
South Africa has a history of poor coordination in construction waste management, which has resulted in problems such as illegal dumping, a lack of legislation enforcement, and a lack of waste management practices. Problems linked with the management of construction waste have risen over the past decade because of increased waste production. This study explored the challenges to the enforcement of waste management practices by the Greater Tzaneen Local Municipality construction sector. A qualitative study was conducted in the construction sectors in Limpopo province. Purposive sampling technique was used to interview 24 participants. The interviews were recorded, transcribed verbatim, and analysed thematically. The findings highlight challenges such as employees’ behaviour and attitude, financial barriers, lack of knowledge and awareness, poor enforcement of the law, and inadequate resources that affects the construction waste management practices. This study draws attention to the challenges encountered when implementing effective waste management practices in the construction sector. The challenges are consistent with the broader challenges that the Sustainable Development Goals aim to solve. This study contributes to the endeavour to minimise environmental impact, promote sustainable practices, and preserve public health, while providing lessons that may inform similar contexts beyond the local municipality.
Per- and polyfluoroalkyl substances (PFAS) are frequently detected at elevated levels in municipal solid waste (MSW) landfill leachate, which is recognized as an important source of environmental PFAS contamination. Yet, PFAS presence in MSW landfill refuse remains largely unexplored, despite the growing interest in landfill refuse utilization and the potential for subsequent PFAS emissions into the environment. This study aimed to quantify PFAS contamination in landfill refuse collected from a closed, typical MSW landfill, by analyzing 24 PFAS (including 18 perfluoroalkyl acids (PFAAs) and 6 PFAA precursors) through target analysis and further capturing unknown precursors using a direct total oxidizable precursor (d-TOP) assay. Our findings revealed that perfluorooctanoic acid (PFOA) was the dominant PFAS in landfill refuse, with a median concentration exceeding 10 μg/kg. The comparison of PFAS in refuse and leachate based on detection and mass level clearly reflected that large amount of PFAS, particularly long-chain perfluoroalkyl carboxylic acids (PFCAs) and PFAA precursors, was still retained in refuse compared to leachate even after more than ten years' leaching. Moreover, significant levels of unknown precursors were identified through the d-TOP assay, highlight that neglecting these unknown precursors could lead to an underestimation of PFAS contamination by a factor of 4 to 18. A probabilistic risk assessment indicated a 25 % likelihood that PFAS in landfill refuse pose moderate to high environmental risk, if excavated refuse is sieved and used as greening soil. To our knowledge, this study marks the first report on PFAS distribution between landfill refuse and leachate, as well as the contribution of unknown precursors in refuse, which underscores the need to consider potential PFAS emission when MSW landfill refuse faces utilization.
Juan Serrano-Gomez, Henrique Rasera Raniro, Ludwig Hermann
et al.
Advanced phosphorus (P) recycling from wastewater is critical for improving nutrient circularity and reducing soil pollution associated with the direct application of sewage sludge in agriculture. However, few studies evaluate the long-term environmental and economic trade-offs between recycled P products and raw sewage sludge application. This study compares struvite, vivianite, and dicalcium phosphate (CaP) as P alternatives to sludge to mitigate heavy metal accumulation in Spanish agricultural soils. Using data from 27,835 plots, heavy metal accumulation was simulated over 50- and 100-year fertilisation scenarios. The results indicate that continuous sludge application leads to widespread exceedances of zinc, copper, and cadmium, especially in alkaline soils, whereas substitution with recycled products can substantially reduce these risks. Vivianite balances P recycling and costs, CaP offers the best environmental performance but with higher investment, and struvite suits smaller regions prioritising environmental safety. Economic analysis favours advanced recycling over sludge, especially considering externalities such as soil remediation costs. Despite limitations, our findings emphasise the importance of integrating environmental externalities into economic assessments and the value of advanced P recycling for sustainable soil management.
The global rise in population, increased life expectancy, and heightened international mobility have escalated disease prevalence and pharmaceutical demand. This growth intensifies energy consumption and chemical waste production within the pharmaceutical industry, challenging environmental sustainability and operational efficiency. Chromatography, a vital analytical technique for ensuring product quality and regulatory compliance, can also contribute to material waste and energy inefficiencies if not properly maintained and optimized. This study applies Failure Mode and Effects Analysis (FMEA) to chromatographic equipment maintenance within Hovione’s Engineering and Maintenance Department, aiming to identify and mitigate failure risks. By integrating environmental metrics derived from Life Cycle Assessment (LCA) into the FMEA framework, a hybrid risk evaluation tool was developed that prioritizes both equipment reliability and sustainability performance. The findings demonstrate how this integrated approach reduces unplanned downtime, lowers solvent waste, and improves energy efficiency. Additionally, the study proposes a conceptual dashboard to support proactive, sustainability-driven asset management in pharmaceutical laboratories. By bridging reliability engineering and environmental sustainability, this research offers a strategic model for optimizing resource use, minimizing chemical waste, and enhancing long-term operational resilience in regulated pharmaceutical environments.
Dina Mohamed, Adham Fayad, Abdel-Mohsen O. Mohamed
et al.
This paper analyses the role of electronic waste (E-waste) as a secondary source of critical and precious minerals, addressing the challenges and opportunities in transitioning towards a circular economy (CE) for electronics. The surging global demand for these essential materials, driven by technological advancements and renewable energy infrastructure, necessitates alternative supply strategies due to the depletion of natural reserves and the environmental degradation associated with primary mining. E-waste contains a rich concentration of valuable metals, such as gold, silver, and platinum, making its recovery a promising solution aligned with CE principles, which can mitigate environmental impacts and ensure long-term material availability. This paper examines the environmental, economic, and technological aspects of E-waste recovery, focusing on core processes such as physical and mechanical separation, pyrometallurgical, hydrometallurgical, bio-metallurgical, and electrochemical techniques. It explores innovative strategies to improve material recovery efficiency and sustainability, with consideration of evolving regulatory frameworks, technological advancements, and stakeholder engagement. The analysis highlights that e-waste, particularly printed circuit boards, can contain 40–800 times more gold than mined ore, with 1000–3000 g of gold per tonne compared to 5–10 g per tonne in traditional ores. Recovery costs using advanced E-waste recycling technologies range between $10,000–$20,000 USD per kilogram of gold, significantly lower than the $30,000–$50,000 USD per kilogram in primary mining. Globally, over 50 million tonnes of E-waste are generated annually, yet less than 20% is formally recycled. Efficient recycling methods can recover up to 95% of base and precious metals under optimized conditions. The paper argues that E-waste recycling presents a viable pathway to conserve critical raw materials, reduce environmental degradation, and enhance circular economic resilience. However, it also emphasizes persistent challenges—including high initial investment, technological limitations in developing regions, and regulatory fragmentation—that must be addressed for scalable adoption.
Anjali V. Prajapati, Shailesh R. Dave, Devayani R. Tipre
Industrial effluents pose a significant concern because they contain a variety of metals and metalloids that have detrimental effects on the environment. Conventional techniques are widely used in effluent treatment plants (ETPs) to remove metallic pollutants; however, they are less effective, are costly, and generate secondary toxic waste. Mycosorbent would be a sustainable and economical alternative to conventional techniques, as it offers numerous advantages. In this study, we shed light on the development of mycosorbent, which could be potentially applicable in the treatment of industrial effluent. In a competitive (i.e., multimetal system) optimisation study, mycosorbent AD2 exhibited a maximum biosorption capacity of 3.7 to 6.20 mg/g at pH 6.0, with an initial metal ion concentration of 25 mg/L, a contact time of 2 h, at 50 ± 2 °C, and a pH<sub>PZC</sub> of 5.3. The metal-removal capacity increased up to 1.23-fold after optimisation. The thermodynamic parameters confirmed that the AD2 mycosorbent facilitated an endothermic, feasible, and spontaneous biosorption process. The FT-IR and SEM characterisation analysis confirmed the adsorption of metals on the surface of the mycosorbent from the aqueous system. This study demonstrated that mycosorbent could be an effective tool for combating metallic pollutants in various industrial effluents.
Tânia Galavote, Gisele de Lorena Diniz Chaves, L. Yamane
et al.
Landfills are the destination of most of the refuse generated whereas composting, material recycling, and Waste-to-Energy (WtE) technologies are not commonly employed in developing countries. However, the destination for energy purposes could be supplied with this refuse, improving the viability of energy use. Thus, this article raises some questions to identify aspects that could encourage its use as refuse-derived fuel (RDF) in these countries. Among them, does environmental education affect the municipal solid waste (MSW) source separation with emphasis on a destination? Can selective collection and extended producer responsibility (EPR) affect the MSW for energy recovery? Is there competition between the recycling market and the energy market for RDF? A systematic review of the literature was conducted to gather data and provide answers to such questions. This enabled to observe that EPR, selective collect expansion and source separation influence the quantity and quality of waste sent for energy use. Both internal and external factors impact on source separation. Additionally, there is evidence to support that despite several studies showing their technical, economic, environmental and social viability, the methods of energy usage of the refuse still need to improve their deployment in developing countries. In addition to identifying the main research gaps to be filled in future studies, the article also identified the instruments of MSW management that are to be applied in developing countries to divert recyclable and organic waste from landfill.
Cyclones are employed in many waste treatment industries for the dust collection or abatement purposes. The prediction of the dust collection efficiency is crucial for the design and optimization of the cyclone. However, this is a difficult task because of the complex physical phenomena that influence the removal of particles. Aim of the paper is to present two new meta-models for the prediction of the collection efficiency curve of cyclone separators. A Backpropagation Neural Network (BPNN) and Support Vector Regression (SVR) models were developed using Python environment. These were trained with a set of experimental data taken from the literature. The prediction capabilities of the models were first assessed by comparing the estimated collection efficiency for several cyclones against the corresponding experimental data. Second, by comparing the collection efficiency curves predicted by the models and those obtained from classic models available in the literature for the cyclones included in the validation dataset. The BPNN demonstrated better predictive capability than the SVR, with an overall mean squared error of 0.007 compared to 0.015, respectively. Most important, a 40% to 90% accuracy improvement of the literature models predictions was achieved.
Andrews Larbi, Xiping Chen, Suliman Muhammad Khan
et al.
Electrolytic Manganese Residue (EMR) is a secondary material generated during the process of manganese production, poses significant environmental challenges, including land consumption and contamination threats to soil and water bodies due to its heavy metal content, soluble manganese, ammonia nitrogen, and disposal issues. This review thoroughly examines EMR, emphasizing its metallurgical principles, environmental impacts, and sustainable treatment methods. We critically analyze various approaches for EMR management, including resource recovery, utilization of construction materials, and advanced treatment techniques to mitigate its environmental challenges. Through an extensive review of recent EMR-related literature and case studies, we highlight innovative strategies for EMR valorization, such as the extraction of valuable metals, conversion into supplementary cementitious materials, and its application in environmental remediation. Our findings suggest that integrating metallurgical principles with environmental engineering practices can unlock EMR’s potential as a resource, contributing to the circular economy and reducing the environmental hazards associated with its disposal. This study aims to deepen the understanding of EMR’s comprehensive utilization, offering insights into future research directions and practical applications for achieving sustainable management of electrolytic manganese waste. Finally, we propose some recommendations to address the issue of EMR, intending to offer guidance for the proper disposal and effective exploitation of EMR.
Kohei Hibino, Chochoe Devaporihartakula, Phalla Sam
et al.
(1) The enactment of Sub-Decree No. 113/2015 on Solid Waste Management marked a significant policy shift towards the decentralisation of waste management in Cambodia and some progress has been observed in Phnom Penh and some other large cities and tourist destinations. However, information in rural areas is lacking. Rapid and simple waste assessment methodologies are needed in rural areas where waste data is scarce and different waste management measures are required compared to urban areas. This study aimed to fill the information gap on the status and fate of municipal solid waste management in rural areas by focusing on three underrepresented cities in different geographical areas through empirical studies. (2) Rapid waste assessments, including waste composition analysis, truck scaling, waste recovery surveys, waste flow analysis, and waste hotspot surveys, were conducted. (3) The per capita waste generation averaged 0.44 kg/day, which is lower than the national average, but did not show significant differences between income levels. The waste composition was similar to that of urban areas, with plastics making up more than 20% of the waste. There were major contrasts in the waste collection rates, with one city having a high rate (85.9%) while the other two cities were as low as 22.6% and 24.2%, respectively. This suggests that rural cities in Cambodia are at different stages of transition in establishing their waste management systems after the decentralisation of waste management to municipalities. The main cause of the low waste collection rate was that private waste collectors were finding it difficult to collect service fees. In the absence of waste collection services, a total of 370 waste hotspots were identified outside of the waste collection areas, where littering and open burning of waste were common. (4) Addressing these challenges requires urgent development of sustainable financing mechanisms, enhanced institutional capacities, and implementation of targeted awareness-raising programmes. These measures are essential for providing basic waste collection and disposal services, as well as for curbing littering and open burning of waste in rural cities in Cambodia.
Tzeni Bentoulla, Konstantina Kotsou, Dimitrios Kalompatsios
et al.
<i>Pyrus communis</i> (<i>P. communis</i>) is the most cultivated and consumed species of pear within the European continent. This fruit has been a staple in Greece since ancient times, hence the name “Gift of the Gods”. Given the extensive utilization of this fruit in the industrial sector and the focus on the exploitation of by-products to create new food and beverage products, the present research aimed to enhance the antioxidant activity of the <i>P. communis</i> peel through the implementation of a multifactor extraction system. Increased total polyphenols and ascorbic acid concentration, and enhanced antioxidant activity through radical scavenging and Fe<sup>3</sup>⁺ to Fe<sup>2</sup>⁺ reduction, all assist in boosting the health benefits of the extracts. The results indicated that the best conditions for compound yields were a 75% <i>v</i>/<i>v</i> hydroethanolic concentration, an extraction temperature of 80 °C, and 30 min of extraction time. Under the optimal conditions, the total polyphenol content was up to 4.98 mg of gallic acid equivalents (GAE)/g dried weight (dw). The radical scavenging activity by the 2,2-diphenyl-1-picrylhydrazyl (DPPH<sup>•</sup>) method was expressed as 18.36 μmol ascorbic acid equivalents (AAE)/g dw, while by the ferric-reducing antioxidant power (FRAP) method, it was 35.09 μmol AAE/g dw. Finally, the amount of ascorbic acid was measured at 20.16 mg/100 g dw. In this regard, this study has been conducted to assess and enhance the level of these bioactive compounds in the extract of the <i>P. communis</i> peel, leading to an extract with several applications in different food and beverage industries.
Every year in Australia, the household, commercial and industry sectors generate more than five million tonnes of food waste, with the majority of it ending up in landfills that are costly to run and diminishing in availability. There are urgent calls for effective waste management practices to better address the challenges related to increasing volumes of food waste. This study evaluates potential food waste collection and composting initiatives that will ensure the implementation of the appropriate policies and technologies, and best practice of utilizing food waste as a natural resource. A series of semi-structured interviews were conducted with practitioners from the Southeast Queensland waste industry to gain insights on the challenges and opportunities for implementing a Food Organics, Garden Organics (FOGO) system. The interviews revealed five key themes: levies and taxes, capital investment challenges, lack of capacity, contract inefficiencies, and separate waste streams. Organisations and companies in the waste industry heavily rely on funding in order to technologically advance. There is a divergence of attention between technology and policy. Advancement of technology grows faster than the policies that regulate the appropriate use and level of effectiveness of the introduced technology. Both policy and technological changes need to occur simultaneously for Queensland to evolve and develop a social-economic system that favours a non-wasteful and sustainable future.
Veronica D’Eusanio, Lucia Bertacchini, Andrea Marchetti
et al.
Apricot (AS), peach (PS), and plum shells (PlS) were examined as sustainable aggregates for non-structural lightweight concrete. The extraction of natural resources has a significant environmental impact and is not in line with the Sustainable Development Goals (SDGs) of Agenda 2030. Recycling agri-food waste, such as fruit shells, fully respects circular economy principles and SDGs. The chemical and physical properties of the shells were investigated using scanning electron microscopy (SEM) for microstructure analysis and TG-MS-EGA for thermal stress behavior. Two binding mixtures were used to prepare the concrete samples, one containing lime only (mixture “a”) and one containing both lime and cement (mixture “b”). Lime is a more sustainable building material but it compromises mechanical strength and durability. The performance of lightweight concrete was determined based on the type of aggregate used. PS had a high-water absorption capacity due to numerous micropores, resulting in lower density (1000–1200 kg/m<sup>3</sup>), compressive strength (1–4 MPa), and thermal conductivity (0.15–0.20 W/mK) of PS concrete. AS concrete showed the opposite trend (1120–1260 kg/m<sup>3</sup>; 2.8–7.0 MPa; 0.2–0.4 W/mK) due to AS microporosity-free and denser structure. PlS has intermediate characteristics in terms of porosity, density, and water absorption, resulting in concrete with intermediate characteristics (1050–1240 kg/m<sup>3</sup>; 1.9–5.2 MPa; 0.15–0.3 W/mK).
Rolande Christelle Makamté Kakeu–Tardy, Hannah Howarth, Marlyne Sahakian
et al.
Organic waste is both a refuse and a resource. Focusing on household waste in a city in Western Switzerland, this study examines the practices of waste segregation in relation to the city’s (organic) waste management system. Based on qualitative research with diverse households and experts in waste management, we use social practice theory to discuss the meanings and materiality of household organic waste segregation. We show how more or less visible meanings, tied up with material arrangements, can be either enablers or deterrents for such forms of waste management. The article argues that certain aspects of the waste system could be rendered more visible, such as the proper labelling of collection bins, while less visibility could be given to certain meanings around waste segregation, such as the financial cost of not sorting. We also discuss how organic waste sorting, as a practice, contests the dominant understandings of change based on technological efficiency, economic benefits, and individual changes. More collective forms of change are needed, working at the level of social contexts and materiality, to further support organic waste sorting.
Municipal refuse. Solid wastes, Standardization. Simplification. Waste
This paper presents an analysis that aimed to quantify the consequences of modelling choices in the life cycle assessment of composting by investigating the influence of composting management practices and the influence of the selected marginal product for substitution. In order to investigate the different influencing factors, a set of 11 scenarios were defined. The scenario results revealed that increasing the turning frequency of the input material leads to a Global warming potential (GWP) reduction of approx. 50%. However, there is a trade-off between GWP reduction and increases in other environmental impacts, including acidification potential (AP), ozone formation potential (OFP), and stratospheric ozone depletion potential (ODP). GWP and AP can also be reduced by optimal exhaust gas filter maintenance, although this causes OFP and ODP to increase. The most relevant factor for GWP is the choice of substituted products. When peat for horticulture can be replaced, GWP can be substantially lowered while hardly affecting other environmental impacts.
Reuse of plastic packaging for food is a promising route to reduce the environmental burdens, but presents particular challenges due to the need to avoid cross-contamination of contents. This study investigates the challenges associated with cleaning and assessing existing recycled PET (rPET) food-to-go (FTG) pack forms and provides recommendations to enable a shift towards reusable food packaging systems. Pack forms were fouled under controlled conditions and washed in accordance published guidelines. Three fouling media were selected to represent food residue typically found in FTG packs. Investigated parameters included fouling type and quality, wash and rinse times, and detergent dosage. Cleanliness was assessed using adenosine triphosphate (ATP) swabbing and the effect on the material properties was studied via tensile testing, IR spectroscopy and differential scanning calorimetry. The results demonstrate that cleaning effectiveness is dependent on the quantity of fouling, the duration of the wash cycle and the dosing of detergent indicating the potential to optimise parameters for different fouling conditions. It is also concluded that ATP testing is an inappropriate cleanliness assessment method for food packaging due to many opportunities for it to produce false negative readings, its high cost, and slow response. The rPET material properties remained largely unchanged apart from a slight increase in stiffness, however packaging suffered significant deformation.
Since 1 July 2020, all retail businesses in Japan have been required by law to charge customers for plastic carrier bags in order to reduce the use of single-use plastic and to encourage consumers to change their lifestyles. This has resulted in more shoppers using their own bags, but has also drawn more emotional responses. This article analyses reactions to the plastic carrier bag levy in 'konbini' (convenience stores) and discusses how it has changed customer service and shopping routines, at the same time as affecting notions of convenience, generosity, and propriety. The levy is also challenging consumers’ notions of cleanliness and pollution, as the plastic bag is changing from something that can both protect its contents from dirt and pollution (as a carrier bag) and protect the environment from its dirty contents (as a waste bag) to something that in itself pollutes the environment.
Municipal refuse. Solid wastes, Standardization. Simplification. Waste
Nigeria is reported as having released up to 0.34 million tonnes of plastic debris into the ocean in 2010 and ranked as the ninth country in the world for pollution of the marine environment. It is a postcolonial, oil rich country where plastic is cheap and widely available. Currently there is no government policy regulating single-use plastic products. Previous studies have identified university student residential areas as ‘hot spots’ for plastic waste. We used qualitative methods (focus groups and semi-structured interviews) to explore how students made sense of their single use plastics consumption (including ‘pure water’ plastic sachets) and analysed how young Nigerians interact with plastic waste. Students perceived plastic waste as malodorous, causing harm to human health and blighting environmental aesthetics. Students saw themselves as the cause of plastic pollution (as consumers) whereas plastic industries were framed positively as producers bringing progress and prosperity. Participants were open about their indiscriminate littering practices subverting other study findings where responsibility tends to be deflected (to policy makers, producers). While we are relying on self-reported behaviour, we found no obvious link between awareness of environmental harm caused by plastic pollution and students’ actions. Within this peer group of young Nigerians, it was not considered ‘normal’ or ‘cool’ socially to use waste bins or recycle. We suggest that further research is needed into how plastic pollution is made sense of in terms of individual responsibility; lay understandings of miasmas; perceptions of public/private spaces and plastics as a signifier of modernity; and enhanced social status.
Municipal refuse. Solid wastes, Standardization. Simplification. Waste