ABSTRACT
Since food waste is a contemporary and complicated issue that is widely debated across many societal areas, the world community has designated the reduction of food waste as a crucial aspect of establishing a sustainable economy. However, waste management has numerous challenges, such as inadequate funding, poor waste treatment infrastructure, technological limitations, limited public awareness of proper sanitary practices, and inadequate legal and regulatory frameworks. A variety of microorganisms participate in the process of anaerobic digestion, which can be used to convert organic waste into biogas (e.g., methane) and nutrient-rich digestate. In this study, we propose a synergy among multiple disciplines such as nanotechnology, omics, artificial intelligence, and bioengineering that leverage anaerobic digestion processes to optimize the use of current scientific and technological knowledge in addressing global food waste challenges. The integration of these fields carries with it a vast amount of potential for improved waste management. In addition, we highlighted the relevance, importance, and applicability of numerous biogas-generating technologies accessible in each discipline, as well as assessing the impact of the COVID-19 epidemic on waste production and management systems. We identify diverse solutions that acknowledge the necessity for integration aimed at drawing expertise from broad interdisciplinary research to address food waste management challenges. © 2022 by the authors.
ABSTRACT
Energy crisis and increasing rigorous management standards pose significant challenges for solid waste management worldwide. Several emerging diseases such as COVID-19 aggravated the already complex solid waste management crisis, especially sewage sludge and food waste streams, because of the increasingly large production year by year. As mature waste disposal technologies, landfills, incineration, composting, and some other methods are widespread for solid wastes management. This paper reviews recent advances in key sewage sludge disposal technologies. These include incineration, anaerobic digestion, and valuable products oriented-conversion. Food waste disposal technologies comprised of thermal treatment, fermentation, value-added product conversion, and composting have also been described. The hot topic and dominant research foci of each area are summarized, simultaneously compared with conventional technologies in terms of organic matter degradation or conversion performance, energy generation, and renewable resources production. Future perspectives of each technology that include issues not well understood and predicted challenges are discussed with a positive effect on the full-scale implementation of the discussed disposal methods. © 2022 Elsevier Ltd
ABSTRACT
This work covers important aspects of the occurrence and viability of various viruses in the two most common reusable waste resources: wastewater and biomass waste. Detection of human, bacterial and plant viruses in these wastes are summarized. Historically, human viruses have been monitored in wastewater for decades. Evidence suggests that wastewater mostly contains fecal-orally transmitted viruses, which are abundant and diverse. Recently, an increasing occurrence of SARS-CoV2 in sewage water with the spreading epidemics has been confirmed but lacking biological proof of infectivity yet. Besides human pathogens, wastewater is shown to be rich in bacteriophages and plant viruses as well, which supposedly enter the water from human guts. Viruses serving as water quality indicators are also discussed here. Lastly, we focus on biomass waste treatment, showing the presence of some common and stable plant viruses which may supposedly survive the technological process. Copyright © Publisher PH <<Akademperiodyka>> of the NAS of Ukraine, 2022.
ABSTRACT
This work covers important aspects of the occurrence and viability of various viruses in the two most common reusable waste resources: wastewater and biomass waste. Detection of human, bacterial and plant viruses in these wastes are summarized. Historically, human viruses have been monitored in wastewater for decades. Evidence suggests that wastewater mostly contains fecal-orally transmitted viruses, which are abundant and diverse. Recently, an increasing occurrence of SARS-CoV2 in sewage water with the spreading epidemics has been confirmed but lacking biological proof of infectivity yet. Besides human pathogens, wastewater is shown to be rich in bacteriophages and plant viruses as well, which supposedly enter the water from human guts. Viruses serving as water quality indicators are also discussed here. Lastly, we focus on biomass waste treatment, showing the presence of some common and stable plant viruses which may supposedly survive the technological process. Copyright © Publisher PH <<Akademperiodyka>> of the NAS of Ukraine, 2022.
ABSTRACT
Considering unpredictable and hastily evolving tipping points (like the impacts of the COVID-19 pandemic, ongoing climate crisis and the war in Ukraine), it is clear that sustainable energy transition and utilization of locally sourced renewable energies must be in the heart of both national, regional, and local energy systems. However, if we take a closer look at the actions undertaken at the local (communal) level, we see enormous diversity of patterns, prerequisites, and implications that drive and affect spatial deployment of renewable energies. Therefore, our research targets to better comprehend the question if individual communities are comparatively involved in the energy transition. We also ask whether the demand and supply of renewable energy is territorially balanced and how these differences (if any) can be justified. We are framing our research by the concepts of energy justice and ecological debt. We thoroughly explore and asses the renewable energy balance on the level of individual communities which is based on data on the installed power capacity potentials and energy consumption in local administration units in Poland (380). Spatial distribution and discrepancies in the deployment of the renewable energy creditors and the renewable energy debtors are detected. Noticeable disproportions were identified among communities where improved utilization of local potential of renewable energy could exceed energy demand (29% of communities). This result is contrasting with communities (71% of communities) that can be, on the other hand, classified as renewable energy debtors. We claim that insufficient support (institution, regulatory, and financial) for expanding local renewable energy systems is a clear barrier when adapting to the climate crisis by balancing the energy demand and supply at the local level.
ABSTRACT
Energy crisis and increasing rigorous management standards pose significant challenges for solid waste management worldwide. Several emerging diseases such as COVID-19 aggravated the already complex solid waste management crisis, especially sewage sludge and food waste streams, because of the increasingly large production year by year. As mature waste disposal technologies, landfills, incineration, composting, and some other methods are widespread for solid wastes management. This paper reviews recent advances in key sewage sludge disposal technologies. These include incineration, anaerobic digestion, and valuable products oriented-conversion. Food waste disposal technologies comprised of thermal treatment, fermentation, value-added product conversion, and composting have also been described. The hot topic and dominant research foci of each area are summarized, simultaneously compared with conventional technologies in terms of organic matter degradation or conversion performance, energy generation, and renewable resources production. Future perspectives of each technology that include issues not well understood and predicted challenges are discussed with a positive effect on the full-scale implementation of the discussed disposal methods.
ABSTRACT
Antimicrobial resistance (AMR) is a growing public health threat. Improved surveillance of AMR's genetic indicators in environmental reservoirs should lead to a more comprehensive understanding of the problem at a global scale, as with SARS-CoV-2 monitoring in sewage. However, the "best" monitoring approach is unclear. Some scientific works have emphasized monitoring for the abundance of already-known antimicrobial resistance genes (ARGs);others have emphasized monitoring for the potential of new ARGs to arise. The goal of this study was to examine which methods were employed by highly-cited papers studying AMR in environmental engineering and agricultural systems, thus providing insight into current and future methodological trends for monitoring ARGs. We searched recent (2018-2020) literature documenting AMR in five environmental matrices: wastewater, surface water, drinking water, stormwater, and livestock manure. We selected the most highly-cited papers across these matrices (89 papers from 17 809 initial results) and categorized them as using targeted methods (e.g., qPCR), non-targeted methods (e.g., shotgun metagenomics), or both. More than 80% of papers employed targeted methods. Only 33% employed non-targeted methods, and the use of targeted versus non-targeted methods varied by environmental matrix. We posit that improving AMR surveillance in environmental reservoirs requires assessing risk, and that different monitoring approaches imply different objectives for risk assessment. Targeted methods are appropriate for quantifying known threats, particularly in environmental matrices where direct human exposure is likely (e.g., drinking water). However, long-term studies employing non-targeted methods are needed to provide an understanding of how frequently new threats (i.e., novel ARGs) arise.
ABSTRACT
The farmers’ welfare and its interlinkages to energy efficiency and farm sustainability has attracted global scientific interest within the last few decades. This study examines the contribution of Agriculture 5.0 to the prosperity of the farmers in the post-pandemic era and the gradual transition to an energy-smart farm. To obtain an insight into the attributes of Agriculture 5.0 and the emerging technologies in the field, Bibliometrix analysis with the use of an R package was conducted based on 2000 data consisting of peer-reviewed articles. The data were retrieved from the Scopus database. A bibliometric approach was employed to analyze the data for a comprehensive overview of the trend, thematic focus, and scientific production in the field of Agriculture 5.0 and energy-smart farming. Emerging technologies that are part of Agriculture 5.0 in combination with alternative energy sources can provide cost-effective access to finance, weather updates, remotely monitoring, and future energy solutions for the establishment of smart farms. Keywords such as “renewable energy,” “Internet of Things,” and “emission control” remain the trending keywords. Moreover, thematic analysis shows that “economic and social effects”, “energy efficiency”, “remote sensing”, and “Artificial Intelligence” with their associated components such as “anaerobic digestion”, “wireless sensor network,” “agricultural robots”, and “smart agriculture” are the niche themes of Agriculture 5.0 in combination with green energy sources, which can lead to the cut cost, energy-efficient, and sustainable energy-smart farms.
ABSTRACT
Combined heat and power (CHP) generation plants are an assessed valuable solution to significantly reduce primary energy consumption and carbon dioxide emissions. Nevertheless, the primary energy saving (PES) and CO2 reduction potentials of this solution are strictly related to the accurate definition and management of thermal and electric loads. Data-driven analysis could represent a significant contribution for optimizing the CHP plant design and operation and then to fully deploy this potential. In this paper, the use of a bi-level optimization approach for the design of a CHP is applied to a real application (a large Italian hospital in Rome). Based on historical data of the hospital thermal and electric demand, clustering analysis is applied to identify a limited number of load patterns representative of the annual load. These selected patterns are then used as input data in the design procedure. A Mixed Integer Linear Programming coupled with a Genetic Algorithm is implemented to optimize the energy dispatch and size of the CHP plant, respectively, with the aim of maximizing the PES while minimizing total costs and carbon emissions. Finally, the effects of integrating biogas from the Anaerobic Digestion (AD) of the Spent Coffee Ground (SCG) and Energy Storage (ES) technologies are investigated. The results achieved provide a benchmark for the application of these technologies in this specific field, highlighting performances and benefits with respect to traditional approaches. The effective design of the CHP unit allows for achieving CO2 reduction in the order of 10%, ensuring economic savings (up to 40%), when compared with a baseline configuration where no CHP is installed. Further environmental benefits can be achieved by means of the integration of AD and ES pushing the CO2 savings up to 20%, still keeping the economical convenience of the capital investment.
ABSTRACT
Following the BBC’s Blue Planet II nature documentary series on marine ecosystems, plastic packaging has come under public fire, with consumers demanding greener alternatives. The biodegradable properties of some bioplastics have offered a potential solution to the global challenge of plastic pollution, while enabling the capture of food waste through anaerobic digestion as a circular and energy-positive waste treatment strategy. However, despite their increasing popularity, currently bioplastics are being tested in environments that do not reflect real-life waste management scenarios. Bioplastics find their most useful, meaningful and environmentally-sound application in food packaging—why is there so little interest in addressing their anaerobic co-digestion with food waste? Here, we provide a set of recommendations to ensure future studies on bioplastic end-of-life are fit for purpose. This perspective makes the link between the environmental sustainability of bioplastics and the role of food waste anaerobic digestion as we move towards an integrated food–energy–water–waste nexus. It shines light on a novel outlook in the field of bioplastic waste management while uncovering the complexity of a successful path forward. Ultimately, this research strives to ensure that the promotion of bioplastics within a circular economy framework is supported across waste collection and treatment stages.
ABSTRACT
The primary objective of this research is to study ways to increase the potential of energy production from food waste by co-production of bioethanol and biomethane. In the first step, the food waste was hydrolysed with an enzyme at different concentrations. By increasing the concentration of enzyme, the amount of reducing sugar produced increased, reaching a maximum amount of 0.49 g/g food waste. After 120 h of fermentation with Saccharomyces cerevisiae, nearly all reducing sugars in the hydrolysate were converted to ethanol, yielding 0.43–0.50 g ethanol/g reducing sugar, or 84.3–99.6% of theoretical yield. The solid residue from fermentation was subsequently subjected to anaerobic digestion, allowing the production of biomethane, which reached a maximum yield of 264.53 ± 2.3 mL/g VS. This results in a gross energy output of 9.57 GJ, which is considered a nearly 58% increase in total energy obtained, compared to ethanol production alone. This study shows that food waste is a raw material with high energy production potential that could be further developed into a promising energy source. Not only does this benefit energy production, but it also lowers the cost of food waste disposal, reduces greenhouse gas emissions, and is a sustainable energy production approach.
ABSTRACT
Cyprus (3) Greece (2) Kazakhstan (2) Australia (1) China (1) Oman (1) Palestine (1) Spain (1) Tunisia (1) United Kingdom (1) The published submissions, without limitation, are related to waste strategies management, air pollution, waste valorization, environmental impact evaluation, life cycle analysis and wastewater treatment. 2. [...]since the treaty of Rome, back in 1957, there was no common statement from the leaders to take action on environmental protection. [2] provided responses to the hypothesis that the COVID-19 pandemic lockdown scenario would advance the environmental performance in this area. [...]there are very few studies focused on the environmental dimensions in any coastal area due to the pandemic. [17] assessed the environmental, technical and economic viability of the anaerobic digestion (AD) sludge formed in a wastewater treatment plant (WWTP).
ABSTRACT
In the U.S., spray irrigation is the most common method used in agriculture and supplementing with animal wastewater has the potential to reduce water demands. However, this could expose individuals to respiratory pathogens such as Legionella pneumophila and nontuberculosis Mycobacteria (NTM). Disinfection with methods like anaerobic digestion is an option but can increase concentrations of cytotoxic ammonia (personal communication). Our study aimed to model the annual risks of infection from these bacterial pathogens and the air concentrations of ammonia and determine if anaerobically digesting this wastewater is a safe option. Air dispersion modeling, conducted in AERMOD, generated air concentrations of water during the irrigation season (May-September) for the years 2013-2018. These values fed into the quantitative microbial risk assessments for the bacteria and allowed calculation of ammonia air concentrations. The outputs of these models were compared to the safety thresholds of 10-4 infections/year and 0.5 mg/m3 , respectively, to determine their potential for negative health outcomes. It was determined that infection from NTM was not a concern for individuals near active spray irrigators, but that infection with L. pneumophila could be a concern, with a maximum predicted annual risk of infection of 3.5 × 10-3 infections/year and 25.2% of parameter combinations exceeding the established threshold. Ammonia posed a minor risk, with 1.5% of parameter combinations surpassing the risk threshold of 0.5 mg/m3 . These findings suggest that animal wastewater should be anaerobically digested prior to use in irrigation to remove harmful pathogens.
Subject(s)
Risk Assessment/methods , Waste Disposal, Fluid/methods , Wastewater , Water Purification/methods , Aerosols , Agricultural Irrigation/methods , Agriculture/methods , Air , Air Movements , Ammonia/chemistry , Animals , Legionella pneumophila , Legionnaires' Disease/microbiology , Manure , Microfluidics , Mycobacterium/metabolism , Probability , Risk , Swine , WaterABSTRACT
The impacts of different operational temperatures, and organic load (OL) on the fate of SARS-CoV-2 during the anaerobic co-digestion of food waste (FW) and sewage sludge (SS) was evaluated. The lab-scaled batch reactors (i.e. R1-R7) were performed under psychrophilic, mesophilic, and thermophilic conditions and the OL of systems was 1.5, 3.5, 6 gVS/L. The performance parameters showed that at higher OL the stability of systems failed and low biogas was produced. In contrast, increasing of operational temperature of systems induced more biogas generation due to the increment of metabolic activity of bacteria. Therefore, R1-R7 achieved biogas yield of 202.5, 249, 187, 260, 246, 163, and 300 mL/gVS respectively. Both SARS-CoV-2 genes i.e. ORF1ab, and N genes were detected in the effluent of psychrophilic reactors i.e. R1, and R2, with a total concentration of 46 × 103, and 11 × 103 copies/L respectively. In R3, no viral genes were observed, when the VFAs was accumulated up to 2000 mg/L and caused a pH drop to 5.6. At the mesophilic condition, the viral concentration was significantly declined, and no viral genes were observed at an OL of 3.5 gVS/L. Furthermore, the synergistic effect of temperature and accumulation of intermediate metabolites provided a sever condition for SARS-CoV-2 survival at an operational temperature and OL of 50 °C, and 1.5 gVS/L respectively.