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3. Upcycling of Eggshell Waste into Calcium Phosphates for Use in Sustainable Biomedical Engineering Applications.

Author

Pagonis, Nikolaos, Flegkas, Dimitrios, Itziou, Aikaterini, Kountouras, Konstantinos, Stimoniaris, Adam, Samaras, Petros, and Karayannis, Vayos

Subjects
ENERGY dispersive X-ray spectroscopy, PRECIPITATION (Chemistry), SUSTAINABLE engineering, CALCIUM phosphate, BIOMEDICAL engineering
Abstract

Eggshells are an inorganic waste, and their accumulation rate is increasing globally, complicating waste management. However, the European Union defines eggshells as low-risk material that can be recycled and reused safely in other applications. Their chemical composition renders them an attractive precursor of calcium phosphate materials (CaPs). Because of their remarkable biocompatibility and capacity for natural degradation, CaPs are frequently employed in biomedical engineering applications. In this research, the wet precipitation method was employed for fabricating CaP powder. Initially, the eggshells were processed into CaCO3 powder and then reacted with HCl to obtain CaCl2 (aq). This reacted with Na2HPO4 to obtain a precipitate that was filtered and dried. The precipitate in powder form underwent X-ray diffraction (XRD), scanning electron microscopy (SEM) and energy dispersive X-ray spectroscopy (EDS) analysis to evaluate its microstructure, and elemental and phase composition. The results indicated that the recovered powder was brushite. [ABSTRACT FROM AUTHOR]

Published
2024
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4. The Processing of a Novel Health Beverage Based on Extracts from Green Tea and Chios Mastiha.

Author

Itziou, Aikaterini, Ziouzios, Dimitrios, Zaralis, Konstantinos, Lakioti, Evangelia, Karayannis, Vayos, and Tsanaktsidis, Constantinos

Subjects
NON-alcoholic beverages, BIOACTIVE compounds, NUTRITIONAL value, WELL-being, TEA extracts, GREEN tea
Abstract

In the present study, the processing, characterization, and assessment of novel non-alcoholic and sugar-free drinks based on bioactive extracts from valuable natural sources, such as green tea enriched with Chios mastiha, are considered. Currently, the transition towards the consumption of healthy and sustainable food and beverages promoting human health and well-being is strongly encouraged and biologically active compounds from natural resources have a broad range of ap-plications in this sector. In this context, three beverages (all non-alcoholic, non-carbonated, and sugar-free) were created, including extracts of green tea with Chios mastiha, matcha green tea with Chios mastiha and louisa green tea with Chios mastiha, and an evaluation of their biological potential was performed. Specifically, an analysis of water, extracts, and additives for the beverage production was carried out. Microbiological and nutritional value determination was also conducted in samples of the three products. According to the experimental results, the novel health beverage produced from green tea enriched with Chios Mastiha extracts was found to have improved organoleptic characteristics and was microbiologically stable and safe for a period of 180 days from the production date at 25 °C. It is also considered stable and safe for 3 days after production, even if it remains open at 25 °C. In view of a possible scale-up of this application, safety, and preservation control should continue for at least 540 days from the date of production. In conclusion, the current research findings support the development of a novel non-alcoholic sugar-free health drink based on bioactive extracts from green tea enriched with Chios mastiha, to contribute to maintaining human health and also to strengthen the economy. [ABSTRACT FROM AUTHOR]

Published
2024
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5. Environmental Pollution and Oxidative Stress: Health Effects During Pregnancy: A Review.

Author

Itziou, Aikaterini, Balis, Vasileios, Lakioti, Evangelia, Karayannis, Vayos, and Tsanaktsidis, Constantinos

Subjects
CLIMATE change & health, PREGNANCY complications, MALE reproductive organs, PREGNANCY outcomes, GENITALIA
Abstract

Featured Application: Potential application of the outcomes of the present study is feasible for the development of more targeted wellbeing measures in order to promote human health and prevent unfavorable pregnancy impacts related to increased oxidative stress due to pollution. Oxidative stress is an imbalance between reactive oxygen species production and antioxidant defense that can lead to reproductive disorders and poor pregnancy outcomes. Environmental pollution under climate change is involved in reactive oxygen species formation and may cause various dysfunctions of the reproductive system. Oxidative stress is a widespread factor that affects the physiology of the male and female reproductive systems, leading to high levels of DNA damage and infertility. Miscarriage, preeclampsia, and premature birth are all linked to oxidative stress. Environmental pollution induces excesses of oxidative stress by expanding ROS generation or overwhelming the physiological responses of the antioxidant defense system. This increases cellular damage, inflammation, and the development of numerous diseases. Here, we present a brief outline of the physiological and developmental roles that oxidative stress plays during pregnancy. We also offer some insights into the underlying mechanisms that have been put forth, which culminate in a summary of the harmful effects of oxidative stress that have an environmental origin in pregnancy-related complications. The current work may motivate the design of more focused wellbeing measures in order to prevent and promote human health and anticipate unfavorable pregnancy outcomes. [ABSTRACT FROM AUTHOR]

Published
2024
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6. Application of Microalgae to Wastewater Bioremediation, with CO 2 Biomitigation, Health Product and Biofuel Development, and Environmental Biomonitoring.

Author

Iakovidou, Gesthimani, Itziou, Aikaterini, Tsiotsias, Arsenios, Lakioti, Evangelia, Samaras, Petros, Tsanaktsidis, Constantinos, and Karayannis, Vayos

Subjects
GREENHOUSE gas mitigation, ENVIRONMENTAL health, CARBON sequestration, FATTY acid methyl esters, NATURAL resources
Abstract

Featured Application: Potential application of the outcomes of the present study is feasible, for wastewater bioremediation with concurrent cost-efficient biofuel production, along with value-added health product and biofuel development, while also reducing the carbon footprint, certainly after implementation of the necessary regulation sandboxes, to promote environmental and human health protection and also job creation and economy strengthening. In the current study, the cultivation of microalgae on wastewater-based substrates is investigated for an effective natural wastewater treatment that also generates biofuels and value-added products beneficial to human health. Additionally, the health of ecosystems can be evaluated via microalgae. The utilization of microalgae as bioindicators, biofuel producers, and wastewater treatment providers, under the biorefinery concept, is covered in this article. In fact, bioremediation is feasible, and microalgae culture can be used to efficiently process a variety of effluents. Along with wastewater processing and the creation of value-added substances, bioconversion concurrently offers a viable and promising alternative for reducing CO2 greenhouse gas emissions to contribute to climate change mitigation. The microalgal biorefinery being considered as the third generation is unique in that it addresses all the aforementioned problems, in contrast to lignocellulosic biomass from agricultural waste in second-generation biorefineries and edible crops in first-generation biorefineries. In particular, one of the most promising natural resources for the manufacture of biofuel, including biodiesel, bioethanol, biomethane, and biohydrogen, is found to be microalgae. Furthermore, products of high value, like fatty acid methyl esters, astaxanthin, β-carotene, DHA, and EPA can be made. Hence, microalgal biomass offers a substitute for the development of biofertilizers, bioplastics, pharmaceuticals, cosmetics, animal and aquatic feeds, and human nutrition products, thus promoting human and environmental health. [ABSTRACT FROM AUTHOR]

Published
2024
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8. Application of Evolutionary Computation to the Optimization of Biodiesel Mixtures Using a Nature-Inspired Adaptive Genetic Algorithm.

Author

Vasileiadis, Vasileios, Kyriklidis, Christos, Karayannis, Vayos, and Tsanaktsidis, Constantinos

Subjects
EVOLUTIONARY computation, GENETIC algorithms, RENEWABLE natural resources, FOSSIL fuels, NATURAL resources, BIOLOGICAL evolution, MIXTURES, BIODIESEL fuels
Abstract

The present research work introduces a novel mixture optimization methodology for biodiesel fuels using an Evolutionary Computation method inspired by biological evolution. Specifically, the optimal biodiesel composition is deduced from the application of a nature-inspired adaptive genetic algorithm that first examines percentages of the ingredients in the optimal mixtures. The innovative approach's effectiveness lies in problem simulation with improvements in the evaluation of the specific function and the way to define and tune the genetic algorithm. Environmental imperatives in the era of climate change currently impose the optimized production of alternative environmentally friendly biofuels to replace fossil fuels. Biodiesel in particular, appears to be more attractive in recent years, as it originates from renewable bio-derived resources. The main ingredients of the specific biofuel mixture investigated in this research are diesel and biodiesel (100% from bioresources). The assessment of the new biodiesel examined was performed using a fitness function that estimated both the density and cost of the fuel. Beyond the evaluation criterion of cost, density also influences the suitability of this biofuel for commercial use and market sale. The outcomes from the modeling process can be beneficial in saving cost and time for new biodiesel production by using this novel decision-making tool in comparison with randomized laboratory experimentations. [ABSTRACT FROM AUTHOR]

Published
2024
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10. Extraction Study of Lignite Coalbed Methane as a Potential Supplement to Natural Gas for Enhancing Energy Security of Western Macedonia Region in Greece.

Author

Vasiliadou, Ioanna A., Semizoglou, Zacharoula A., Karayannis, Vayos G., and Tsanaktsidis, Constantinos G.

Subjects
LIGNITE, NATURAL gas, COALBED methane, ENERGY security, METHANE as fuel, GREENHOUSE gas mitigation, SWOT analysis
Abstract

Greek lignite reserves are mainly located in the northwestern part of the country (Region of Western Macedonia, Greece), reaching a total of 5 billion tons. Considering that Greece is planning to stop burning lignite for electricity production, the recovery of the CH4 trapped in lignite coalbed reservoirs can be a valuable alternative for power generation and may help to reduce the direct emissions of methane during mining activities. The aim of the present study was to evaluate the LCBM in the Region of Western Macedonia, Greece (Ptolemaida basin). In order to assess the LCBM that could be extracted, three samples were collected from an active mine and were subjected to desorption experiments at different temperatures (25 °C, 50 °C, 100 °C, and 150 °C) by channeling high purity Ar gas at 1 atm of pressure. According to the results, the highest amount of CH4 was extracted during the desorption process at 50 °C, while the total amount of CH4 from all three samples was 0.82 m3/kg, confirming the presence of CH4 in the lignite deposits. Finally, a SWOT analysis was carried out that shows the strengths and opportunities against the weaknesses and threats of a potential LCBM exploitation in Greece, while also taking into account the social, economic, and environmental nexus. [ABSTRACT FROM AUTHOR]

Published
2024
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11. Sustainable Medical Waste Management Using an Intuitionistic Fuzzy-Based Decision Support System.

Author

Kokkinos, Konstantinos, Lakioti, Evangelia, Moustakas, Konstantinos, Tsanaktsidis, Constantinos, and Karayannis, Vayos

Abstract

The growing urban population and increased use of healthcare services have brought significant attention to the safe and sustainable management of medical waste. Selecting the proper technology in medical waste management (MWM) represents one of the most critical challenges for decision-makers to ensure public health. In order to evaluate and choose the best MWM methodology, the current research provides a novel multi-criteria decision-making (MCDM) strategy for a variety of social stakeholders, to compute criteria weights, decision-making weights, and alternative ranking algorithms. The suggested structure addresses uncertain assessments of alternatives by extending weighting and ranking methods to acquire the decision-making weight and rank the MWM alternatives based on uncertain conditions. It also uses 'intuitionistic fuzzy' linguistic variables to indicate criteria weights. To assess all the factors pertaining to the sustainability of MWM actions, this study suggests the creation of a decision support system (DSS). Our DSS is built upon a novel strategy that utilizes a collection of MCDM models that are grounded on contemporary intuitionistic fuzzy logic methodologies. Alternative scenarios have been assessed for the instance of Greece, after specialists in the healthcare management field imposed 17 criteria and sub-criteria. The IF-MCDM methodologies used were the Intuitionistic Fuzzy DEMATEL, TOPSIS, and CORPAS. The alternative scenarios ranged from the prioritizing of safety laws and regulations to public acceptance and awareness, with the handling of hazardous risks and transportation playing a crucial part in the process. All ensemble methods produced the same ranking of the alternatives, demonstrating that safety and risk avoidance is the most significant scenario for sustainable urban development and public health. [ABSTRACT FROM AUTHOR]

Published
2024
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12. Sustainable Antioxidant Production for Hygienic Disinfection Using Bioextractants from Lavender and Oregano Distillation Process.

Author

Itziou, Aikaterini, Zaralis, Konstantinos, Theofanous, Annita, Louloudi, Maria, Rozos, Georgios, Vasiliadou, Ioanna A., Lakioti, Evangelia, Karayannis, Vayos, and Tsanaktsidis, Constantinos

Subjects
LAVENDERS, OREGANO, SUSTAINABILITY, CIRCULAR economy, DISTILLATION, ESSENTIAL oils, RADICALS (Chemistry)
Abstract

In the current study, the production of novel antioxidants for hygienic disinfection against common pathogenic bacteria, based on the incorporation of bioextractant oils/waters from either lavender or oregano distillates is proposed in the framework of circular economy. For the first time, the main compounds found in distillation products (oils/waters), specifically of lavender Lavandula angustifolia (lynalyl acetate and linalool) and of oregano Oreganum vulgare (carvacrol, thymol, and p-cymene) are presented. The analyses of both the lavender and oregano essential oils/waters indicate excellent physicochemical properties and microbial absence. Moreover, the antioxidant activity of all distillates as DPPH radical scavengers is assessed. The results confirm that the essential oils of both oregano and lavender possess superior antioxidant activity to their corresponding waters, while the oregano oil exhibited far better antioxidant activity than the lavender oil, as 1 mL of oregano oil was able to consume 45 μmoles of DPPH radicals. Overall, our research findings suggest that the particular lavender and oregano bioextractants produced possess important potential to address the resistance of bacteria from the perspective of their wider exploitation in therapeutic or preventive medicine, thus contributing to enhancing public health. [ABSTRACT FROM AUTHOR]

Published
2023
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14. Sintering lignite fly and bottom ashes via two-step versus conventional process

Author

Karayannis Vayos G., Moutsatsou Angeliki K., and Katsika Eleni L.

Subjects
lignite fly ash, bottom ash, calcareous, two-step sintering (TSS), ceramics, Chemical technology, TP1-1185
Abstract

Lignite combustion class-C (highly-calcareous) fly ash and bottom ash were sintered employing two-step sintering (TSS) and compared to conventionally sintered ones. TSS sintering is a new promising approach mainly used to obtain effectively densified ceramics. This alternative process is generally characterized by the absence of the final stage of grain growth occurring upon conventional sintering and by the development of nanograin microstructure. The ceramic microstructures successfully obtained in the present research were characterized by means of X-ray diffraction and scanning electron microscopy coupled with energy dispersive X-ray analysis as well as by density measurements. The effectiveness of the solidification process was thoroughly studied, and the specific microstructural features attained are compared between each other and evaluated in relation to the sintering method applied. The results show that the valorization of lignite calcareous ashes into ceramic materials is feasible through different sintering techniques.

Published
2016
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18. Energy and Exergy-Based Screening of Various Refrigerants, Hydrocarbons and Siloxanes for the Optimization of Biomass Boiler–Organic Rankine Cycle (BB–ORC) Heat and Power Cogeneration Plants.

Author

Douvartzides, Savvas L., Tsiolikas, Aristidis, Charisiou, Nikolaos D., Souliotis, Manolis, Karayannis, Vayos, and Taousanidis, Nikolaos

Subjects
RANKINE cycle, SILOXANES, REFRIGERANTS, WORKING fluids, HYDROCARBONS, POWER plants, MECHANICAL efficiency
Abstract

The cogeneration of power and heat was investigated for Biomass Boiler–Organic Rankine Cycle (BB–ORC) plants with the characteristics of typical units, such as the 1 MWel Turboden ORC 10 CHP. The thermodynamic analysis of the ORC unit was undertaken considering forty-two (42) dry and isentropic candidate pure working fluids. Only subcritical Rankine cycles were considered, and the pinch point temperature differences for the evaporation and condensation heat exchangers were kept constant at 10 °C in all cases. The study provides an original and unique screening of almost all pure working fluids that are considered appropriate in the literature under the same operation and optimization conditions and compiles them into a single reference. In its conclusions, the study provides useful fluid selection and design guidelines, which may be easily followed depending on the optimization objective of the ORC designer or operator. In general, hydrocarbons are found to lie in the optimum middle range of the fluid spectrum, between the siloxanes that maximize the production of mechanical power and the refrigerants that maximize the production of heat. Specific hydrocarbon fluids, such as cyclopentane, heptane, hexane, benzene, and toluene, are found as rational options for maximum mechanical efficiency when operating with practically feasible condensation pressures between 10 and 200 kPa. At condensation pressures below 10 kPa, ethylbenzene, o-xylene, m-xylene, p-xylene, and nonane are also found to be feasible options. Finally, cyclopentane, hexane, and MM (hexamethyldisiloxane) are selected as the most appropriate options for cogeneration plants aiming simultaneously at high mechanical power and maximum temperature water production. [ABSTRACT FROM AUTHOR]

Published
2022
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19. Investigation of the Total Phenolic Content and Antioxidant Capacity of Three Sweet Pepper Cultivars (Capsicum annuum L.) at Different Development and Maturation Stages.

Author

Papathanasiou, Theodoros, Gougoulias, Nikolaos, Karayannis, Vayos G., and Kamvoukou, Christina-Anna

Subjects
SWEET peppers, OXIDANT status, CULTIVARS, PLANT phenols, VITAMIN C, CAPSAICINOIDS, CAPSICUM annuum
Abstract

The aim of the current research was to investigate and compare the total phenolic content and antioxidant capacity of sweet pepper cultivars at different development and maturation stages, in order to optimize the beneficial effects. For that purpose, three important sweet pepper cultivars, namely Dolmy-F1, Yahoo-F1 and Florinis-NS-700, were cultivated in a greenhouse. Their total phenolic content, ascorbic acid content and antioxidant properties were assessed at different development and maturation stages. In the aforementioned cultivars, the total phenolic content ranged from 345.2 to 602.1, 404.9 to 794.5, and 795.7 to 2220.3 μg GAE g-1 FW respectively. The ascorbic acid content ranged from 236 to 957, 258 to 1157, and 410 to 1550 μg AA g-1 FW respectively. The highest antioxidant activity was noted at the red maturity stage. Particularly the cultivar Florinis NS 700 was found to possess higher total phenolic, flavonoid phenol, non-flavonoid phenol, ascorbic acid contents, and greater antioxidant capacity, compared to the other cultivars. The results of our study recommend the consumption of the sweet peppers at red maturity stage, for achieving the maximum health-beneficial effects. [ABSTRACT FROM AUTHOR]

Published
2021
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21. Transformation of Industrial By-Products into Composite Photocatalytic Materials.

Author

Katsika, Eleni, Volioti, Maria, Karayannis, Vayos G., and Moutsatsou, Angeliki

Subjects
LIGNITE, COMPOSITE materials, WASTE products, INDUSTRIAL wastes, FLY ash, WATER purification, SLURRY
Abstract

The transformation of both calcareous and siliceous Greek power station by-products (lignite ashes) into novel composite materials with photocatalytic properties for environmental application was investigated. Particularly, a comparison between the development of coated ceramic substrates and the modification of ash surfaces is attempted. Specifically, a) the sintering process (1000 °C, 2 h) of both fly and bottom ash (either calcareous or siliceous) for their conversion into compacted ceramic substrates coated with TiO2 slurry and then further thermally treated (500 °C, 1 h) to acquire TiO2 film consistency onto the ceramic substrate and b) the process of TiO2 precipitation on lignite ash surfaces in acidic solution after neutralization, and estimation of the TiO2 percentage, are compared. The microstructures obtained were examined by XRD and SEM-EDX analysis. Vickers microhardness was also determined for the ceramic microstructures, with satisfactory results (up to 356HV). The energy gap measurements of the coatings were found to be between 3.02eV and 3.17eV, which is located between the energy gap of anatase (3.23eV) and rutile (3.02eV). The coating mass was about 0.059 g/cm2. The photocatalytic activity under visible and UV irradiation was investigated in aqueous solutions of methylene blue and methyl orange organic dyes, with encouraging results. A main advantage of the processes proposed is the immobilization of TiO2 onto largely available secondary resources, which can lead to production of value-added 'green' photocatalysts for the treatment of industrial effluents in the framework of circular economy. [ABSTRACT FROM AUTHOR]

Published
2021
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22. Evaluation of public perception on key sustainability indicators for drinking water quality by fuzzy logic methodologies.

Author

Kokkinos, Konstantinos, Lakioti, Evangelia, Samaras, Petros, and Karayannis, Vayos

Subjects
DRINKING water quality, PUBLIC opinion, WATER utilities, FUZZY logic, WASTE minimization, WATER supply, SOCIAL acceptance
Abstract

Social acceptance of water quality in urban areas depends on the perception and awareness of the stakeholders and the wider public. Moreover, the significance of social trust in stakeholders appears to be an influential factor affecting social support of water quality. However, efforts on understanding, communicating and engaging with the public and the stakeholder community still remain under examination. Urban water resources management problems are often associated with ecological, political, social and economic development and have caused critical concern to both national and local competent authorities in almost every country for many years. When focusing on water quality, key indicators are used to measure the performance (KPIs) of water companies in evaluating their success to customer satisfaction with zero defects while minimizing the environmental footprint caused by the intermediate procedures up to the point of receiving potable tap water. Stakeholder interviews reveal that these KPIs can be identified from an economic, social, environmental and water company perspective, and they can span from the efficiency of water distribution to operational water losses minimization procedures and from customer supply coverage to aesthetic test compliance. Therefore, future policy for water quality should be designed in a strategic framework, taking into consideration key sustainability indicators emanating from the aforementioned perspectives. In the current paper, a complete showcase is illustrated on how to mobilize local stakeholder's knowledge to extract KPIs for supporting effective strategies by local water companies and initiating policy making by the competent authorities in the process of keeping high water quality standards in a sustainable water resources management environment. Specifically, the application of soft computing methods enables the conceptualization and categorization of stakeholders' notion of strategies that need to be followed. This conceptualization allowed the involvement of fuzzy inference systems to simulate the effects of several policies in a multi-criteria analysis. According to the features, the policy maker initiates, the proposed model succeeds to identify the preferred policy options that can be used in achieving minimal environmental footprint. [ABSTRACT FROM AUTHOR]

Published
2019
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23. DEVELOPMENT OF RELIABLE BUILDING BRICKS INCORPORATING OLIVE-MILL WASTEWATER FOCUSing ON THERMAL INSULATION AND ENERGY SAVINGS.

Author

Spiliotis, Xenofon, Karayannis, Vayos, Lamprakopoulos, Stelios, Zaoutsos, Stefanos, and Papapolymerou, George

Subjects
*THERMAL insulation, *HEAT, *BRICKS, *MANUFACTURING processes, *SEWAGE, *ENERGY conservation in buildings
Abstract

The present communication reports the development of reliable building bricks with improved thermal insulation behavior through substitution of the water mixed with the standard ceramic clayey raw materials with olive-mill wastewater (OMWW). This endeavor will contribute to circular economy and environmental protection as well as possible energy savings and CO2 emission reductions. OMWW is an aqueous by-product generated in large amounts during olive oil production processes. It is characterized by high COD values, low biodegradability, high toxicity, acidic pH, a high concentration of potassium and high solid matter content. Therefore, finding eco-friendly and economically viable solutions for OMWW treatment and valorization represents a significant challenge in the oilproducing countries, in order to avoid severe environmental problems from the uncontrolled disposal of this effluent. For that purpose, a series of ceramic brick specimens are fabricated with the introduction of either olive-mill wastewater or water employing a pilot-plant simulation of the industrial brick manufacturing procedures. The brick thermal conductivity and the mechanical performance are evaluated. According to the results obtained the replacement of fresh water by olive-mill wastewater in the ceramic manufacturing provides a production of lighter building bricks of a decreased thermal conductivity (hence increased thermal insulation capability) as well as an acceptable and a reliable mechanical strength. Furthermore, the energy consumption measurements reveal energy savings of as much as 30% attained during the brick firing. [ABSTRACT FROM AUTHOR]

Published
2019

24. Recent progress in the advanced oxidation of wastewaters using recycled fly ashes as alternative catalytic agents.

Author

Baklavaridis, Apostolos N., Samaras, Petros E., and Karayannis, Vayos G.

Subjects
INDUSTRIAL wastes, FLY ash, CATALYSTS
Abstract

In this study, a comprehensive literature review is conducted with regard to recent advances in using recycled fly ashes as alternative and cost-effective reagents than as wastes in the advanced oxidation of wastewaters. Fly ashes are powdery solid residues that are produced in enormous quantities in coal/lignite-fed power stations and also from waste incineration. Novel applications of these industrial by-products in the field under examination, toward sustainable use of resources and circular economy, are discussed and summarized. Since fly ashes contain useful metal oxides, they can actually be considered as alternative catalytic agents in wastewater treatment, depending on their surface properties and the elements solubility rate in the aqueous media. Beyond the possible contribution of these secondary materials to the oxidation of wastewaters, their potential for concurrent beneficial adsorption of substances present in the effluent to be treated also enhances the significance of the current scientific work. For that purpose, fly ashes and several fly ash-based composite catalysts were examined for their effectiveness in advanced oxidation processes that are summarized in three main categories, namely photocatalysis, Fenton/Fenton-like oxidation, and combined mechanisms. Principal system parameters affecting the degradation of wastewaters were considered, including the dosage of each catalytic agent used, the initial dye concentration, the solution pH, and the reaction time and temperature. [ABSTRACT FROM AUTHOR]

Published
2018
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25. Effects of Manure Enriched with Algae Chlorella vulgaris on Soil Chemical Properties.

Author

GOUGOULIAS, NIKOLAOS, PAPAPOLYMEROU, GEORGIOS, KARAYANNIS, VAYOS, SPILIOTIS, XENOFON, and CHOULIARAS, NIKOLAOS

Subjects
CHLORELLA vulgaris, MANURES, SOIL chemistry, PLANT species, PLANT biomass
Abstract

The effect of the algal species Chlorella vulgaris at six different ratios (0, 1, 2, 3, 4, 5 g) of air dried algae biomass, mixed with 10.18 g of sheep manure, added to 50 g of soil, and incubated for a period of 15 weeks was studied in a laboratory in order to detect the role of adding small amounts of admixed algal biomass to soil in biodegradation of soil organic carbon. The obtained data showed that mineralization of soil organic carbon increased by 16.2-35.9% at all rates of algae addition compared to the control, while the highest increase was observed at the highest rates of algae addition. There was a 40-50% increase in the available form of potassium, while the highest increase was also observed at the highest rates of algae addition. The four times higher rates of added algae increased the corresponding content of nitrate nitrogen by 20-30%, while ammonium nitrogen contents decreased by 9.5-35.7% for all amounts of added algae in comparison with the control. The available forms of copper, manganese, and zinc were also increased for all amounts of added algae by 56.8-61.9%, 55.8-67.3%, and 34.1-40.6%, respectively. On the contrary, the addition of algae did not indicate significant differences among treatments as concerns organic or available phosphorus contents. The results proved the effect of the algae Chlorella vulgaris as an accelerator agent in biodegradation of soil organic matter, without any significant negative impact on soil chemical properties. [ABSTRACT FROM AUTHOR]

Published
2018
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26. Wastewater treatment for reuse employing industrial by-products as alternative coagulants.

Author

Domopoulou, Asimina, Moustakas, Konstantinos, Baklavaridis, Apostolos, Koukouzas, Nikolaos, and Karayannis, Vayos

Subjects
WASTEWATER treatment, WATER reuse, COAGULANTS, SEWAGE purification, FLY ash, ELECTRIC arc
Abstract

In the current research, three industrial by-products containing useful iron and aluminum chemical components were introduced as potential alternative coagulants in marble processing wastewater treatment for possible water reuse. Specifically, the coagulation performance of lignite highly calcareous fly ash, siliceous fly ash (FAs) and electric arc furnace dust (EAFD) was compared with that of two commercial coagulants (Al2 (SO4 )3 ·18H2O and FeCl3 ·6H2 O). The kinetic studies were conducted at times up to 60 min by using coagulant dosages up to 4 mg/L. Turbidity (NTU), pH and conductivity were recorded during the kinetic studies. FAs and EAFD revealed enhanced coagulation performance, having similar turbidity removal efficiencies (%ΔNTU) to those of commercial coagulants, with short sedimentation times (~5 min). The pH values recorded for the three industrial by-products/coagulants were in the basic range of 7–9.7. Only the pH values for EAFD, at high dosages, were found to be close to neutral, while, for all commercial coagulants, neutral pH values were recorded at intermediate dosages. The experimental results presented may contribute to the formation of integrated and cost-effective strategies for marble wastewater management with low environmental footprint. [ABSTRACT FROM AUTHOR]

Published
2017
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27. PREPARATION AND CHARACTERIZATION OF LIGNITE ASHES COATED WITH TiO2 FOR ENVIRONMENTAL APPLICATION.

Author

Katsika, Eleni, Moutsatsou, Angeliki, Karayannis, Vayos, and Ntziouni, Afroditi

Subjects
LIGNITE, COMBUSTION, POWER plants, TITANIUM dioxide, RUTILE
Abstract

This research aims at the utilization of both calcareous and siliceous lignite ashes, by-products of lignite combustion in power plants, toward a development of new materials of an environmental benefit. The possibility of fly and bottom ash surface modification by anatase and rutile (titanium dioxide structures) is investigated. The precipitation of TiO2 from an acidic solution on lignite ash surface is studied and the percentage of TiO2 coating obtained is found ranging from 11 to 55%. The latter microstructure is examined by XRD and SEM-EDX taking into consideration the ashes particle size (as received and < 45 µm), the solution pH (5.5 - 7.5), the ageing time (1 and 3 h) and the sintering temperature (300°C, 500°C, 700°C) applied. Anatase and rutile crystalline structures are observed within the whole heat treatment range. The main advantage of the process reported refers to titania immobilization onto a cheap porous substrate providing an additional solution to liquid wastes treatment by photocatalysis. [ABSTRACT FROM AUTHOR]

Published
2017

28. PROCESSING OF STEEL MILL SCALE FOR MANUFACTURING NOVEL ENGINEERING CERAMICS BY POWDER METALLURGY.

Author

KARAYANNIS, Vayos, LAMPRAKOPOULOS, Stylianos, DOMOPOULOU, Asimina, KYRATSIS2, Panagiotis, PAPAPOLYMEROU, George, and SPILIOTIS, Xenofon

Subjects
PRODUCTION engineering, STEEL mills, RAW materials -- Environmental aspects, POWDER metallurgy, CERAMICS
Abstract

The aim of the current research is the beneficial utilization of steel mill scale (MS) as admixture in clayey raw materials at high percentages up to 100% for manufacturing innovative engineering ceramics by powder metallurgy processes. Various MS/clay mixtures were cold compacted at 20 tn load using an automated hydraulic press to form series of 5 cm diam. disc-shaped specimens. The specimens so-produced were sintered in a programmable electric furnace for final consolidation by controlled heating up to 950 °C for 2h. Weight and dimensions changes upon sintering, as well as physico-mechanical properties of sintered specimens were determined in relation to the % MS content. Microstructural examination was conducted by SEM-EDAX. From the experimental results, the substitution of MS for clays is feasible and a tendency for mechanical properties enhancement is recorded with increasing the industrial residue percentage, thus rendering MS a suitable and interesting starting material for the elaboration of engineering ceramics. This endeavor can also contribute to the sustainable management of this industrial residue towards circular economy and environmental protection. [ABSTRACT FROM AUTHOR]

Published
2017

29. CERAMIC PROCESSING VIA MICROWAVE IRRADIATION.

Author

KARAYANNIS, Vayos, DOMOPOULOU, Asimina, BAKLAVARIDIS, Apostolos, and KYRATSIS, Panagiotis

Subjects
CERAMICS design, IRRADIATION, MICROWAVE devices, HEAT treatment, STRUCTURAL analysis (Engineering)
Abstract

Nowadays, several thermal treatment procedures and technologies are being used for in ceramic processing. The application of microwave irradiation in ceramic manufacturing, for the consolidation of the final ceramic structure, has many energy and economical avails, while at the same time it is environmentally benign. In this work, the microwave irradiation potential usage in energyefficient ceramic manufacturing is explored via a comprehensive literature review. Specifically, the advantages/disadvantages of the microwave irradiation compared to conventional heating technologies is discussed. Three different classes of ceramic materials, with industrial significance, are considered: a) bulk ceramics, b) electroceramics and c) bioceramics. Furthermore, future applications which may attract commercial concernment are also pointed out. [ABSTRACT FROM AUTHOR]

Published
2016

30. VALORIZATION OF CFB-COMBUSTION FLY ASHES AS THE RAW MATERIALS IN THE DEVELOPMENT OF VALUE-ADDED CERAMICS.

Author

Karayannis, Vayos, Moutsatsou, Angeliki, Koukouzas, Nikolaos, and Vasilatos, Charalampos

Abstract

The amounts of ashes from circulating fluidized bed (CFB)-combustion steadily increase with the increasing rate of implementation of this environmentally-friendlier technology for firing solid fuels in power generation units. Therefore, beneficial uses of these powdery by-products, which possess particular characteristics, should be identified instead of landfill them at significant environmental and economic impact. Their valorization in the manufacturing of value-added ceramics is a challenging research area. In the present study, CFB-coal combustion fly ashes, mainly bearing Si-Al phases, were utilized as 100% raw materials for the synthesis of ceramics by powder metallurgy (PM) techniques. Test specimens were fabricated by powder cold pressing followed by sintering at 900, 1000 or 1100 °C. The produced materials were characterized by means of XRD and SEM-EDAX. Shrinkage upon sintering, apparent density, water absorption capability and Vickers microhardness were determined. The experimental results show that the recycling of CFB-fly ashes towards PM ceramics development is feasible. In fact, integral light-weight materials are obtained, exhibiting successfully-densified ceramic microstructures where quartz phases prevail. The physico-mechanical properties are proved to be influenced by the starting ash composition and the sintering temperature. The so-produced ceramics possess the potential to be tailored appropriately to meet requirements for specific applications of possible commercial interest. [ABSTRACT FROM AUTHOR]

Published
2013

31. RECYCLING OF LIGNITE HIGHLY-CALCAREOUS FLY ASH INTO NICKEL-BASED COMPOSITES.

Author

Karayannis, Vayos G., Moutsatsou, Angeliki K., and Katsika, Eleni L.

Abstract

Only a small amount of the massive quantities of fly ash derived from lignite combustion in power stations is currently utilized, while the largest portion of ash is directly discharged into ponds and landfills. Therefore, alternative applications should be introduced for the valorization of this industrial waste, thus satisfying current environmental demands. Fly ash can be considered for incorporation into upgraded metal-ceramic composites to provide weight reduction for energy savings, better insulation properties, decreased shrinkage and enhanced corrosion resistance, to contribute towards hardness and wear properties as well as to reduce the high production cost of the composites. So far, only limited data are reported regarding the use of fly ash as a dispersoid into nickel-based composite coatings. In the present study, the feasibility of manufacturing innovative nickel fly ash bulk composites was investigated, starting from powder blends of nickel and 0-50 wt. % recycled lignite highly-calcareous fly ash, and applying powder metallurgy techniques. Composite specimens were successfully prepared and examined by means of XRD and 5EM-EDX analyses as well as apparent density and Vickers microhardness measurements. The obtained metal-ceramic microstructures exhibit a satisfactory densification degree indicative of an effective consolidation process. By adding fly ash into nickel matrix, lightweight nickel-based composites with no significant reduction in nickel hardness are produced. [ABSTRACT FROM AUTHOR]

Published
2012

32. Supportiveness of Low-Carbon Energy Technology Policy Using Fuzzy Multicriteria Decision-Making Methodologies.

Author

Kokkinos, Konstantinos and Karayannis, Vayos

Subjects
*CLEAN energy, *ALTERNATIVE fuels, *ENERGY policy, *GOAL programming, *FUZZY numbers, *WIND power, *SOLAR technology
Abstract

The deployment of low-carbon energy (LCE) technologies and management of installations represents an imperative to face climate change. LCE planning is an interminable process affected by a multitude of social, economic, environmental, and health factors. A major challenge for policy makers is to select a future clean energy strategy that maximizes sustainability. Thus, policy formulation and evaluation need to be addressed in an analytical manner including multidisciplinary knowledge emanating from diverse social stakeholders. In the current work, a comparative analysis of LCE planning is provided, evaluating different multicriteria decision-making (MCDM) methodologies. Initially, by applying strengths, weaknesses, opportunities, and threats (SWOT) analysis, the available energy alternative technologies are prioritized. A variety of stakeholders is surveyed for that reason. To deal with the ambiguity that occurred in their judgements, fuzzy goal programming (FGP) is used for the translation into fuzzy numbers. Then, the stochastic fuzzy analytic hierarchical process (SF-AHP) and fuzzy technique for order performance by similarity to ideal solution (F-TOPSIS) are applied to evaluate a repertoire of energy alternative forms including biofuel, solar, hydro, and wind power. The methodologies are estimated based on the same set of tangible and intangible criteria for the case study of Thessaly Region, Greece. The application of FGP ranked the four energy types in terms of feasibility and positioned solar-generated energy as first, with a membership function of 0.99. Among the criteria repertoire used by the stakeholders, the SF-AHP evaluated all the criteria categories separately and selected the most significant category representative. Finally, F-TOPSIS assessed these criteria ordering the energy forms, in terms of descending order of ideal solution, as follows: solar, biofuel, hydro, and wind. [ABSTRACT FROM AUTHOR]

Published
2020
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