Your search keyword '"Balat, M."' showing total 1,163 results

1. Oxidation of silicon nitride under standard air or microwave-excited air at high temperature and low pressure

Author

BALAT, M, CZERNIAK, M, and BERJOAN, R

Published

1997

2. The Semiotics of Pierce and of Greimas/La sémiotique du Peirce et celle de Greimas

Author

Balat, M., Deledalle-Rhodes, J., Deledalle, G., Wolde, E.J. van, Balat, M., Deledalle-Rhodes, J., Deledalle, G., and Wolde, E.J. van

Abstract

Item does not contain fulltext

Published

1992

3. THE RESPONSE AFFECTED BY PROGRAMS OF LAYING HENS TO INDUCED MOLT AS STRAIN, FEEDING AND LIGHTING

Author

Breikaa,, Mervat, primary, Abou EI-Ella, Nazla, additional, Afify, Yousria, additional, and Balat, M., additional

Published

2002

4. Active to passive transition in the oxidation of silicon carbide at high temperature and low pressure in molecular and atomic oxygen

Author

Balat, M., primary, Flamant, G., additional, Male, G., additional, and Pichelin, G., additional

Published

1992

5. The Potential of Lignocellulosic Biomass Hydrolysates for Microbial Oil Production Using Yeasts and Microalgae.

Author

Legodi, Lesetja Moraba, Moganedi, Kgabo L. Maureen, and Pipitone, Giuseppe

Subjects

BIOMASS production, BIOCHEMICAL substrates, HEMICELLULOSE, FOOD crops, ARABLE land, LIGNOCELLULOSE

Abstract

The use of food‐based biomass and arable land for bio‐oil and biofuel production could compromise global food security. Therefore, renewable and environmentally friendly oils for biofuels from oleaginous microorganisms such as yeasts and microalgae (heterotrophic and mixotrophic) are gaining interest within the scientific community. These microorganisms have shorter cultivation times and higher lipid productivity when compared to higher plants/food crops/autotrophic microorganisms. Despite many advantages, the high carbon requirements and production cost are limiting factors that hinder their deployment at a commercial scale. Lignocellulosic waste substrates are abundant and inexpensive materials that are rich in organic carbon in the form of cellulose and hemicellulose, which release bioavailable forms of sugars upon hydrolysis. Recent studies have shown the tremendous potential of the hydrolysates of these substrates to be utilized as carbon sources for biomass production and the accumulation of lipids in oleaginous hetero‐/mixotrophic microorganisms. Therefore, this review highlights the potential use of lignocellulosic biomass as a low‐cost carbon substrate for the cultivation of hetero‐/mixotrophic microalgae and yeast for microbial oil production for commercial applications. It also examines the current status, challenges, and future prospects for the utilization of lignocellulose biomass. [ABSTRACT FROM AUTHOR]

Published

2024

6. Alkaline hydrogen peroxide pretreatment of bamboo residues and its influence on physiochemical properties and enzymatic digestibility for bioethanol production.

Author

Ummalyma, Sabeela Beevi, Herojit, Ningthoujam, Sukumaran, Rajeev K., Dar, Mudasir A., and Xiao, Ling-Ping

Subjects

HYDROGEN peroxide, BIOMASS, HEMICELLULOSE, FUNCTIONAL groups, ETHANOL as fuel, BIOMASS energy, CELLULASE

Abstract

Bamboo is a perennial rapid-growing plant that is given preference for renewable biosources for biofuels and bio-based chemical conversion. Bamboos are rich in cellulose and have highly recalcitrant biomass due to high lignin. Bamboo is abundantly available in Northeastern India and can be utilized as a feedstock biofuels. Here, we evaluated the pretreatment of bamboo residues Dendrocalamus strictus with different concentrations of alkali, hydrogen peroxide, and alkaline hydrogen peroxide and its influence on biomass digestibility for enhancement of sugar recovery with Celic C cellulase enzyme blend. Enzymatic hydrolysis data indicated untreated raw biomass showed a digestibility of 40% after 48 h of incubation. The biomass pretreated with alkali showed a maximum digestibility of 61% obtained from 10% loaded with 0.5% w/v NaOH. Pretreatment of the bamboo with H2O2 shows a maximum digestibility of 75% from biomass loaded with 1% w/v of H2O2. Combinational pretreatment of alkaline hydrogen peroxide showed a maximum efficiency of biomass digestibility of 83% attained from biomass loaded with 1% w/v NaOH-H2O2. Crystallinity index (CrI) analysis showed that CrI increased from 64% to 70.75% in pretreated biomass. FTIR and SEM analysis show changes in functional groups, morphology, and surface of biomass in pretreated biomass. Compositional analysis shows that 68% of lignin removal is obtained from alkaline hydrogen peroxide pretreatment. Cellulose content increased from 52% to 65%, and hemicellulose decreased from 18.6% to 8.6%. Results indicated that the potential possibility of bamboo waste biomass as feedstock for biorefinery products and alkaline hydrogen peroxide pretreatment methods is an efficient strategy for sugar recovery for bioethanol production. [ABSTRACT FROM AUTHOR]

Published

2024

7. Alcohols as Biofuel for a Diesel Engine with Blend Mode—A Review.

Author

Jamrozik, Arkadiusz and Tutak, Wojciech

Subjects

DIESEL motors, ALCOHOL as fuel, DIESEL fuels, DIESEL motor exhaust gas, THERMAL efficiency, METHYL formate, NITROGEN oxides emission control, BUTANOL

Abstract

In the era of decarbonization driven by environmental concerns and stimulated by legislative measures such as Fit for 55, the industry and transportation sectors are increasingly replacing petroleum-based fuels with those derived from renewable sources. For many years, the share of these fuels in blends used to power compression ignition engines has been growing. The primary advantage of this fuel technology is the reduction of GHG emissions while maintaining comparable engine performance. However, these fuel blends also have drawbacks, including limited ability to form stable mixtures or the requirement for chemical stabilizers. The stability of these mixtures varies depending on the type of alcohol used, which limits the applicability of such fuels. This study focuses on evaluating the impact of eight types of alcohol fuels, including short-chain (methanol, ethanol, propanol) and long-chain alcohols (butanol, pentanol, hexanol, heptanol, and octanol), on the most critical operational parameters of an industrial engine and exhaust emissions. The engines being compared operated at a constant speed and under a constant load, either maximum or close to maximum. The study also evaluated the effect of alcohol content in the mixture on combustion process parameters such as peak cylinder pressure and heat release, which are the basis for parameterizing the engine's combustion process. Determining ignition delay and combustion duration is fundamental for optimizing the engine's thermal cycle. As the research results show, both the type of alcohol and its concentration in the mixture influence these parameters. Another parameter important from a usability perspective is engine stability, which was also considered. Engine performance evaluation also includes assessing emissions, particularly the impact of alcohol content on NOx and soot emissions. Based on the analysis, it can be concluded that adding alcohol fuel to diesel in a CI engine increases ignition delay (up to 57%), pmax (by approximately 15–20%), HRRmax (by approximately 80%), and PPRmax (by approximately 70%). Most studies indicate a reduction in combustion duration with increasing alcohol content (by up to 50%). For simple alcohols, an increase in thermal efficiency (by approximately 15%) was observed, whereas for complex alcohols, a decrease (by approximately 10%) was noted. The addition of alcohol to diesel slightly worsens the stability of the CI engine. Most studies pointed to the positive impact of adding alcohol fuel to diesel on NOx emissions from the compression ignition engine, with the most significant reductions reaching approximately 50%. Increasing the alcohol fuel content in the diesel blend significantly reduced soot emissions from the CI engine (by up to approximately 90%). [ABSTRACT FROM AUTHOR]

Published

2024

8. Influence of Microwave-Assisted Chemical Thermohydrolysis of Lignocellulosic Waste Biomass on Anaerobic Digestion Efficiency.

Author

Dębowski, Marcin, Zieliński, Marcin, Nowicka, Anna, and Kazimierowicz, Joanna

Subjects

TECHNOLOGY assessment, METHANE fermentation, LIGNOCELLULOSE, BIOCHEMICAL substrates, ORGANIC compounds, MICROWAVE heating

Abstract

To date, microwave radiation has been successfully used to support the chemical hydrolysis of organic substrates in the laboratory. There is a lack of studies on large-scale plants that would provide the basis for a reliable evaluation of this technology. The aim of the research was to determine the effectiveness of using microwave radiation to support the acidic and alkaline thermohydrolysis of lignocellulosic biomass prior to anaerobic digestion on a semi-industrial scale. Regardless of the pretreatment options, similar concentrations of dissolved organic compounds were observed, ranging from 99.0 ± 2.5 g/L to 115.0 ± 3.0 in the case of COD and from 33.9 ± 0.92 g/L to 38.2 ± 1.41 g/L for TOC. However, these values were more than twice as high as the values for the substrate without pretreatment. The degree of solubilisation was similar and ranged between 20 and 28% for both monitored indicators. The highest anaerobic digestion effects, ranging from 99 to 102 LCH4/kgFM, were achieved using a combined process consisting of 20 min of microwave heating, 0.10–0.20 g HCl/gTS dose, and alkaline thermohydrolysis. For the control sample, the value was only 78 LCH4/kgFM; for the other variants, it was between 79 and 94 LCH4/kgFM. The highest net energy gain of 3.51 kWh was achieved in the combined alkaline thermohydrolysis with NaOH doses between 0.10 and 0.20 g/gTS. The use of a prototype at the 5th technology readiness level made it possible to demonstrate that the strong technological effects of the thermohydrolysis process, as demonstrated in laboratory tests to date, do not allow for positive energy balance in most cases. This fact considerably limits the practical application of this type of solution. [ABSTRACT FROM AUTHOR]

Published

2024

9. Sustainability assessment of a conceptual multipurpose offshore platform in the South China Sea.

Author

Chen, Shanyu, Duan, Fengjun, and Tabeta, Shigeru

Subjects

SUSTAINABLE development, SUSTAINABILITY, ENERGY infrastructure, MARINE engineering, MODULAR construction

Abstract

An offshore multipurpose floating platform (MPFP) combines different marine technologies to serve industry needs using one infrastructure; the aim of an MPFP is enlarging the synthesis benefits and reducing the negative impacts. Ocean thermal energy conversion (OTEC) in particular has attracted significant attention for its great potential and low environmental risk. This research demonstrates the system design of a conceptual MPFP in the South China Sea, evaluating its economic and environmental sustainability using an inclusive index. The system is based on a modular floating structure with a designed lifetime of 50 years. Tuna aquaculture, microalgae cultivation and processing, and the OTEC energy infrastructure are integrated to increase the profitability of the applications. We adopted a high-yield photobioreactor microalgae cultivation system and a low-cost barge-type floating structure combined with a semisubmergible to reduce the required area and cost of the floating structure and improve the sustainability of the system. The inclusive impact index "Triple-I-light (IIIlight)" was calculated to evaluate the environmental sustainability and economic feasibility of the floating system. The result shows that the new system becomes environmentally neutral (EF = BC) at a lifetime of 11.5 years, showing sustainability (IIIlight ≤ 0) at a lifetime of 20 years. The proposed system can produce fish with no external energy or feed supply. An autonomous system, such as the one proposed here, is considered very effective when it comes to utilizing the ocean and contributing to a sustainable society. [ABSTRACT FROM AUTHOR]

Published

2024

10. Progress in metal oxide-based electrocatalysts for sustainable water splitting.

Author

Jamadar, Aasiya S., Sutar, Rohit, Patil, Susmita, Khandekar, Reshma, and Yadav, Jyotiprakash B.

Subjects

ELECTROCATALYSTS, OXYGEN evolution reactions, HYDROGEN evolution reactions, METALS, CATALYTIC activity, PLATINUM group

Abstract

Metal oxide-based electrocatalysts are promising alternatives to platinum group metals for water splitting due to their low cost, abundant raw materials, and impressive stability. This review covers recent progress in various metal oxides tailored for hydrogen and oxygen evolution reactions, discussing their crystal structure, composition, and surface modification influence on performance. Strategies like surface engineering, doping, and nanostructuring are evaluated for enhancing catalytic activity and stability. The key considerations for commercialization are highlighted, emphasizing ongoing research, innovation, and future scope to drive widespread adoption of water-splitting technology for a cleaner and sustainable future. [ABSTRACT FROM AUTHOR]

Published

2024

11. Biomass-Fueled Organic Rankine Cycles: State of the Art and Future Trends.

Author

Heidarnejad, Parisa, Genceli, Hadi, Hashemian, Nasim, Asker, Mustafa, and Al-Rawi, Mohammad

Subjects

MACHINE learning, RANKINE cycle, COAL mine waste, RENEWABLE energy sources, BIOMASS energy

Abstract

Biomass-fueled organic Rankine cycles (ORCs) are widely utilized technologies for power production because of their simplicity, low cost, and relatively high efficiencies. Furthermore, raw material availability and topographical independency make these systems preferable to other renewable-fueled power generation systems. A deep and comprehensive understanding of biomass-fueled organic Rankine cycles will provide researchers with a solid foundation to prioritize their investigations and assist future developments in this field. In this regard, feedstocks and their properties, biomass conversion mechanisms, and biomass-fueled power generation systems are discussed in this study. Power generation technologies based on coal and waste as feedstock have been widely investigated in the literature due to higher energy content and technological maturity. Additionally, depending on the type of biomass available, the scale of the power plant, and economic and environmental considerations, the most common technologies utilized for biomass conversion are combustion, gasification, and anaerobic digestion. Finally, the authors investigate various aspects of biomass-fueled organic Rankine cycles, including working fluids, analysis methods, and environmental issues. Since maximizing product yield is key in biomass-based power generation systems, technical assessment of these systems has been a primary focus of many studies. Further research is required on integrated environmental and socio-economic approaches, along with Machine Learning algorithms. Future advancements focusing on integration of feedstock with other renewable energy sources, efficient working fluids like nanofluids, and high-tech heat exchangers will drive the development of biomass-fueled ORC systems. [ABSTRACT FROM AUTHOR]

Published

2024

12. Direct Hydrothermal Synthesis and Characterization of Zr–Ce-Incorporated SBA-15 Catalysts for the Pyrolysis Reaction of Algal Biomass.

Author

Ghimiș, Simona-Bianca, Oancea, Florin, Raduly, Monica-Florentina, Mîrț, Andreea-Luiza, Trică, Bogdan, Cîlțea-Udrescu, Mihaela, and Vasilievici, Gabriel

Subjects

ALGAL biofuels, MESOPOROUS materials, HYDROTHERMAL synthesis, BIOCHAR, PYROLYSIS, BIOMASS liquefaction

Abstract

In recent years, algae have emerged as a promising feedstock for biofuel production, due to their eco-friendly, sustainable, and renewable nature. Various methods, including chemical, biochemical, and thermochemical processes, are used to convert algal biomass into biofuels. Pyrolysis, a widely recognized thermochemical technique, involves high temperature and pressure to generate biochar and bio-oil from diverse algal sources. Various pyrolytic processes transform algal biomass into biochar and bio-oil, including low pyrolysis, fast pyrolysis, catalytic pyrolysis, microwave-assisted pyrolysis, and hydropyrolysis. These methods are utilized to convert a range of microalgae and cyanobacteria into biochar and bio-oil. In this publication, we will discuss catalytic pyrolysis using mesoporous materials, such as SBA-15. Mesoporous catalysts have earned significant attention for catalytic reactions, due to their high surface area, facilitating the better distribution of impregnated metal. Pyrolysis conducted in the presence of a mesoporous catalyst is viewed more as efficient, compared to reactions occurring within the smaller microporous cavities of traditional zeolites. SBA-15 supports with incorporated Zr and/or Ce were synthesized using the direct hydrothermal synthesis method. The catalyst was characterized using structural and morphological technical analysis and utilized for the pyrolysis reaction of the algal biomass. [ABSTRACT FROM AUTHOR]

Published

2024

13. Hydrogen Revolution in Europe: Bibliometric Review of Industrial Hydrogen Applications for a Sustainable Future.

Author

Vergara, Diego, Fernández-Arias, Pablo, Lampropoulos, Georgios, and Antón-Sancho, Álvaro

Subjects

BIBLIOMETRICS, SCIENTIFIC literature, PUBLIC investments, SUSTAINABILITY, HYDROGEN analysis

Abstract

Industrial applications of hydrogen are key to the transition towards a sustainable, low-carbon economy. Hydrogen has the potential to decarbonize industrial sectors that currently rely heavily on fossil fuels. Hydrogen, with its unique and versatile properties, has several in-industrial applications that are fundamental for sustainability and energy efficiency, such as the following: (i) chemical industry; (ii) metallurgical sector; (iii) transport; (iv) energy sector; and (v) agrifood sector. The development of a bibliometric analysis of industrial hydrogen applications in Europe is crucial to understand and guide developments in this emerging field. Such an analysis can identify research trends, collaborations between institutions and countries, and the areas of greatest impact and growth. By examining the scientific literature and comparing it with final hydrogen consumption in different regions of Europe, the main actors and technologies that are driving innovation in industrial hydrogen use on the continent can be identified. The results obtained allow for an assessment of the knowledge gaps and technological challenges that need to be addressed to accelerate the uptake of hydrogen in various industrial sectors. This is essential to guide future investments and public policies towards strategic areas that maximize the economic and environmental impact of industrial hydrogen applications in Europe. [ABSTRACT FROM AUTHOR]

Published

2024

14. Research and Prediction of Wear Characteristics of Alfalfa Densification Die Based on the Discrete Element Method.

Author

Du, Haijun, Du, Hailong, Ma, Yanhua, Su, He, Xuan, Chuanzong, and Xue, Jing

Subjects

PARTICLE motion, WEAR resistance, COMPACTING, ALFALFA, DISCRETE element method

Abstract

In this study, the wear characteristics of the die were tested and analyzed through compaction tests, and the distribution of wear depth along the direction toward the extrusion outlet was obtained. A discrete element method (DEM) model of the die's wear process was established. The results show that the severe wear area is located near the stop position of the compression rod, forming a plow-shaped wear area along the extrusion direction, accompanied by fatigue peeling. The wear depth gradually decreases towards the extrusion outlet. The DEM model partially reveals the occurrence of the wear phenomenon, but the particle motion speed deviates from the actual situation. The maximum compression force value range during the DEM compression stage is within the actual maximum compression force value range, and the relative error range of the average maximum compression force is less than 2%. By verifying the formula to calibrate the model, the calibrated model is compared with the actual mold wear, and the predicted value is close to the actual test result. The DEM can be used to explore the wear mechanism and predict the die's wear failure process, laying the foundation for optimizing die wear resistance design. [ABSTRACT FROM AUTHOR]

Published

2024

15. Ecotoxicity of Tar from Coffee Grounds and Pine Pellet Gasification Process.

Author

Hawrot-Paw, Małgorzata, Koniuszy, Adam, Borusiewicz, Andrzej, Skibko, Zbigniew, Romaniuk, Wacław, Zając, Grzegorz, and Szyszlak-Bargłowicz, Joanna

Abstract

This study determined the toxicity of the condensates produced during the gasification of two waste types. Coffee grounds, pine pellets, and a mixture of both substrates at a ratio of 1:1 were used in the study. Two microbiotests were applied for soil plants and aquatic macrophytes, and quantitative analysis of the soil microbiome for primary taxonomic groups of microorganisms was conducted. Three contamination rates were used in the Phytotoxkit test and the microbiological tests, 100, 1000, and 10,000 mg·kg−1 d.m. of soil, while in the aquatic organism studies, successive two-fold serial dilutions of condensates were used. The presence of liquid waste from the gasification process adversely affected the germination and development of terrestrial plants and the vegetative growth of aquatic plants. The condensate components modified the composition of the soil microbiome, adversely affecting soil fertility. The negative impact increased with increasing levels of contamination and primarily depended on the type of substrate from which the gasification process produced the liquid waste. [ABSTRACT FROM AUTHOR]

Published

2024

16. Ru/GCN Nanocomposite as an Efficient Catalyst for Hydrogen Generation from Sodium Hypophosphite.

Author

Shirman, Ron, Chakraborty, Sourav, and Sasson, Yoel

Subjects

ENERGY dispersive X-ray spectroscopy, HETEROGENEOUS catalysts, X-ray photoelectron spectroscopy, PRECIOUS metals, X-ray powder diffraction

Abstract

Sodium hypophosphite is a promising green source for generating clean elemental hydrogen without pollutants. This study presents the development of an efficient heterogeneous catalyst, Ru/g-C3N4 (Ru/GCN), for hydrogen generation from sodium hypophosphite. The Ru/GCN catalyst demonstrates excellent activity under mild reaction conditions and maintains its effectiveness over multiple cycles without significant loss of activity. This easily separable and recyclable heterogeneous catalyst is straightforward to operate, non-toxic, eco-friendly, and provides a cost-effective alternative to the extensive use of expensive noble metals, which have limited industrial applications. The Ru/GCN catalyst was characterized using various material characterization and spectral methods, including powder X-ray diffraction (PXRD), Fourier transform infrared (FTIR), thermogravimetric analysis (TGA), transmission electron microscopy (TEM), scanning electron microscopy with energy dispersive X-ray spectroscopy (SEM-EDS), and X-ray photoelectron spectroscopy (XPS). Hypophosphite, combined with the catalytically active and recyclable Ru/GCN catalyst, forms a system with high potential for industrial-scale hydrogen production, suggesting promising avenues for further research and application. [ABSTRACT FROM AUTHOR]

Published

2024

17. Optimizing Combustion Efficiency in Blast Furnace Injection: A Sustainable Approach Using Biomass Char and Coal Mixtures.

Author

Tang, Chenmei, Pan, Jian, Zhu, Deqing, Guo, Zhengqi, Yang, Congcong, and Li, Siwei

Abstract

This study investigated the combustion characteristics of mixed straw char and coal powder when used in blast furnace injection. The experiments examined the effects of mixing ratios between biomass char types of wheat straw char, corn straw char as well as cotton straw char, and anthracite coal on combustion characteristics and the injection effect of blast furnace. The results show that a 1:1 mixing ratio of wheat straw char and anthracite coal yields the best combustion characteristics, followed by a 1:1 ratio of corn straw char and anthracite coal. A 2:1 mixture of cotton straw char and anthracite coal exhibits the highest combustion efficiency. The study on the grindability of the mixtures indicates that straw char is easier to grind due to its brittleness. Blast furnace coal injection experiments reveal that a 50:50 mixture of cotton straw char and anthracite coal achieves the highest combustion efficiency at 74%, which is a 20.2% improvement compared to mixtures of bituminous coal and anthracite coal, significantly outperforming the other ratios. The findings underscore the importance of integrating renewable biomass resources in industrial applications to enhance sustainability in the metallurgical industry. [ABSTRACT FROM AUTHOR]

Published

2024

18. A scoping review on the association between early childhood caries and life on land: The Sustainable Development Goal 15.

Author

Foláyan, Morẹ́nikẹ́ Oluwátóyìn, Schroth, Robert J., Duangthip, Duangporn, Al-Batayneh, Ola B., Virtanen, Jorma I., Sun, Ivy Guofang, Arheiam, Arheiam, Feldens, Carlos A., and El Tantawi, Maha

Subjects

DENTAL caries, SUSTAINABLE development, REAL estate development, LAND degradation, ENVIRONMENTAL degradation, DENTAL health education, FOOD security

Abstract

Background: The Sustainable Development Goal 15 (SDG15) deals with protecting, restoring, and promoting the sustainable use of terrestrial ecosystems, sustainably managing forests, halting and reversing land degradation, combating desertification and halting biodiversity loss. The purpose of this scoping review was to map the current evidence on the association between SDG 15 and Early Childhood Caries (ECC). Methods: This scoping review was reported in accordance with the preferred reporting items for systematic reviews and meta-analyses extension for scoping reviews (PRISMA-ScR) guidelines. Formal literature searches were conducted in PubMed, Web of Science, and Scopus in March 2023 using key search terms. Studies with the criteria (in English, with full text available, addressing component of life on land, focusing on dental caries in humans, with results that can be extrapolated to control ECC in children less than 6 years of age) were included. Retrieved papers were summarised and a conceptual framework developed regarding the postulated link between SDG15 and ECC. Results: Two publications met the inclusion criteria. Both publications were ecological studies relating environmental findings to aggregated health data at the area level. One study concluded that the eco-hydrogeological environment was associated with human health, including caries. The other reported that excessive calcium was associated with the presence of compounds increasing groundwater acidity that had an impact on human health, including caries. The two ecological studies were linked to SDG 15.1. It is also plausible that SDG 15.2 and SDG 15.3 may reduce the risk for food insecurity, unemployment, gender inequality, zoonotic infections, conflict and migration; while SDG 15.4 may improve access to medicinal plants such as anticariogenic chewing sticks and reduction in the consumption of cariogenic diets. Conclusions: There are currently no studies to support an association between ECC and SDG15 although there are multiple plausible pathways for such an association that can be explored. There is also the possibility of synergistic actions between the elements of soil, water and air in ways that differentially affect the risk of ECC. Studies on the direct link between the SDG15 and ECC are needed. These studies will require the use of innovative research approaches. [ABSTRACT FROM AUTHOR]

Published

2024

19. Co-pyrolysis of biomass woodchips with Ca-rich oil shale fuel in a continuous feed reactor.

Author

Ceron, Alejandro Lyons, Pihu, Tõnu, and Konist, Alar

Subjects

OIL shales, ATMOSPHERIC carbon dioxide, ALIPHATIC hydrocarbons, PETROLEUM as fuel, WOOD chips

Abstract

A co-pyrolysis of woodchips and oil shale was conducted in a continuous reactor at 520 °C in a CO2 atmosphere. Experimental product yields were derived and an analysis of the liquid products was conducted, using gas chromatography, infrared spectroscopy, and physicochemical analysis. A maximum yield of liquids and gases was obtained as the share of biomass increased (43.9 and 35.1 wt%, respectively). Product characterization confirmed additive behavior in co-pyrolysis. The liquid products from copyrolysis blends exhibited fewer oxygenated compounds, derived from biomass, and fewer aromatic compounds, derived from oil shale. Co-pyrolysis liquids contained abundant aliphatic hydrocarbons (C6 to C11). [ABSTRACT FROM AUTHOR]

Published

2024

20. Recent advances in the processing of Napier grass (Pennisetum purpureum Schumach) as a potential bioenergy crop for bioethanol production.

Author

Chamoli, Priya, Jhildiyal, Samiksha, Agrawal, Palak, Kumar, Navin, and Singh, Pallavi

Published

2024

21. Environmental policy and farmers' active straw return: administrative guidance or economic reward and punishment.

Author

He, Jia, Zhou, Wenfeng, Guo, Shili, Deng, Xin, Song, Jiahao, and Xu, Dingde

Subjects

ENVIRONMENTAL policy, STRAW, INCOME, CARBON offsetting, CONSCIOUSNESS raising, PUNISHMENT

Abstract

Straw used to be an important raw material for heating, cooking, and raising livestock in rural areas. However, with the development of the economy, straw burning poses a great threat to the environment. Straw return is of great significance for realizing carbon peaks and carbon neutrality because of its ecological value and economic value. Based on the survey data of 540 households in Sichuan Province, China, the Probit model and CMP model are used to empirically analyze the influence of environmental policy on farmers' active straw return and its mechanism. The results show that: (1) 65.9% of farmers actively return straw to the field, and 34.1% of farmers passively return straw to the field. (2) environmental policies significantly promote farmers' initiative to return straw to the field, in which the influence of economic rewards and punishments is greater than that of administrative guidance. (3) Government propaganda and government training in government administrative guidance can promote farmers' active straw return by raising their awareness, with intermediary effects of 76.05% and 60.14%, respectively. (4) Female heads of households, high education level of heads of households, and high family income can also positively promote farmers' active straw return. [ABSTRACT FROM AUTHOR]

Published

2024

22. The Moderating Role of ESG Administration on the Relationship between Tourism Activities and Carbon Emissions: A Case Study of Basic Local Governments in South Korea.

Author

Oh, Heekyun

Abstract

This study examines the impact of tourism activities (TA) on carbon emissions (CE) in South Korea and investigates how ESG (environmental, social, and governance) administration power moderates these relationships. To explore four research areas—the relationship between TA and CE; variations across three years (2019–2021); the moderating effect of ESG policies; and the influence of control variables—MIMIC models were employed using secondary data from credible national institutions. The main results across the years and ESG groups (high vs. low) are as follows: (1) The positive influence of individual TA on CE ranked as food and beverage > shopping > recreation > accommodation, with no differences across the years or ESG groups. (2) ESG administration alleviated the carbon-emitting effects of TA, with significant moderation in 2019 and 2021, but not in 2020 (particularly, the effect sizes of TA were greater in low ESG groups). (3) Although tourism development stimulates TA more strongly in the high ESG groups, the CE induced by TA is significantly mitigated by ESG administrative support, resulting in smaller effects than those observed in the low groups. (4) The latter part covers diverse discussions on the influence of control variables—such as infection safety, atmospheric pollution, tourism development, income levels, green space, and local population. [ABSTRACT FROM AUTHOR]

Published

2024

23. The Cultural Ecohydrogeology of Mediterranean-Climate Springs: A Global Review with Case Studies.

Author

Pascual, Roger, Piana, Lucia, Bhat, Sami Ullah, Castro, Pedro Fidel, Corbera, Jordi, Cummings, Dion, Delgado, Cristina, Eades, Eugene, Fensham, Roderick J., Fernández-Martínez, Marcos, Ferreira, Verónica, Filippini, Maria, García, Guillermo, Gargini, Alessandro, Hopper, Stephen D., Knapp, Lynette, Lewis, Ian D., Peñuelas, Josep, Preece, Catherine, and Resh, Vincent H.

Subjects

CLIMATIC zones, CLIMATE change, CULTURAL pluralism, LITERATURE reviews, WESTERLIES, CULTURAL landscapes, GROUNDWATER flow

Abstract

Cultures in Mediterranean climate zones (MCZs) around the world have long been reliant on groundwater and springs as freshwater sources. While their ecology and cultural sustainability are recognized as critically important, inter-relationships between springs and culture in MCZs have received less attention. Here we augmented a global literature review with case studies in MCZ cultural landscapes to examine the diversity and intensity of cultural and socio-economic relationships on spring ecohydrogeology. MCZs are often oriented on western and southern coasts in tectonically active landscapes which control aquifer structure, the prevalence of westerly winds, and aridity, and generally expose associated habitats and cultures to harsh afternoon sunlight. Cultural appreciation and appropriation of springs ranges widely, from their use as subsistence water supplies to their roles in profound traditions such as Greco-Roman nymphalea as well as Asian and Abrahamic spiritual cleansing and baptism. The abandonment of traditional ways of life, such as rural livestock production, for urban ones has shifted impacts on aquifers from local to regional groundwater exploitation. The commoditization of water resources for regional agricultural, industrial (e.g., mining, water bottling, geothermal resorts), and urban uses is placing ever-increasing unsustainable demands on aquifers and spring ecosystems. When the regional economic value of springs approaches or exceeds local cultural values, these irreplaceable aquatic ecosystems are often degraded, over-looked, and lost. Sustainable stewardship of springs and the aquifers that support them is a poorly recognized but central conservation challenge for modern Mediterranean societies as they face impending impacts of global climate change. Solutions to this crisis require education, societal dialogue, and improved policy and implementation. [ABSTRACT FROM AUTHOR]

Published

2024

24. Determination of the Possibilities of Using Woody Biomass Ash from Thermal Power Plants in Corn Cultivation.

Author

Rolka, Elżbieta, Żołnowski, Andrzej Cezary, Wyszkowski, Mirosław, and Skorwider-Namiotko, Anna

Subjects

BIOMASS, POWER plants, CIRCULAR economy, BIOMASS burning, COPPER, CORN

Abstract

Combustion of woody biomass in professional bioheating plants to generate heat and reduce the dust emissions from this process results in the formation of a huge mass of woody biomass ash (WBA). Due to WBA's rich chemical composition and the assumptions of the circular economy, this mineral material should be used for environmental purposes to recover valuable macro- and micronutrients. The basis of the research was a pot experiment designed to assess the effect of six doses of WBA (15, 30, 45, 60, 75, and 90 g pot−1) on the growth, development, yield, and chemical composition of corn. Each pot contained 9 kg of soil. Observations show that the use of increasing doses of WBA had a positive effect on the height of corn plants, increasing its yield by 7 to 10% but reducing the dry matter content by 0.47 to 1.37% and the leaf greenness index (SPAD). Moreover, WBA application (T1–T5 treatments) had a positive effect on the content of macroelements (N, K, Mg, Ca, and Na) in corn biomass. A significant increase in the content of K (54%), Mg (38%), Ca (43%), and Na (19%) was observed. However, at the same time, a significant increase in the content of heavy metals—Ni, Cd, and Pb—was observed. Different results were obtained for P, Zn, Cu, Cr, and Co, whose content in corn decreased after WBA application to soil. The obtained results indicate the possibility of using WBA in an environmentally friendly way. However, due to the great diversity of this material in terms of the content of undesirable heavy metals, it is necessary to optimize its dosage and monitor its chemical composition. Considering the growing number of bioheating plants in our country in recent years and the resulting increase in the amount of WBA produced, it is necessary to develop a rational and environmentally friendly method for managing them in the future. The results of our research may provide partial indications of such solutions. [ABSTRACT FROM AUTHOR]

Published

2024

25. Rapid chemical recycling of waste polyester plastics catalyzed by recyclable catalyst.

Author

Yu-Ji Luo, Jia-Yin Sun, and Zhi Li

Subjects

CHEMICAL recycling, WASTE recycling, PLASTIC scrap, PLASTIC recycling, SUSTAINABILITY, POLYESTERS, CATALYSTS recycling, PLASTIC marine debris

Abstract

Waste plastics are serious environmental threats due to their low degradability and low recycling rate. Rapid and efficient waste plastics recycling technologies are urgently demanded for a sustainable future. Herein, we report a rapid, closed-loop, and streamlined process to convert polyesters such as poly(ethylene terephthalate) (PET) back to its purified monomers. Using trifluoromethanesulfonic acid or metal triflates as the recyclable catalyst, polyesters such as PET can be completely depolymerized by simple carboxylic acids within 1 h. By coupling this acidolysis with a subsequent hydrogenolysis process, the consumed carboxylic acid was recovered and the closed-loop of PET depolymerization could be established. All catalysts and depolymerization agents are fully recycled while only PET and hydrogen are consumed. [ABSTRACT FROM AUTHOR]

Published

2024

26. Hydrogen Formation from Water with Various Reducing Metals Catalyzed by In Situ-Generated Nickel Nanoparticles.

Author

Shirman, Ron and Sasson, Yoel

Subjects

METALS, NICKEL, SCANNING electron microscopy, NANOPARTICLES, HYDROGEN, IRON

Abstract

Water is a potential green source for the generation of clean elemental hydrogen without contaminants. One of the most convenient methods for hydrogen generation is based on the oxidation of different metals by water. The inspection of the catalytic activity toward hydrogen formation from water performed in this study was carried out using four different metals, namely, zinc, magnesium, iron, and manganese. The process is catalyzed by in situ-generated nickel nanoparticles. The zinc–water system was found to be the most effective and exhibited 94% conversion in 4 h. The solid phase in the latter system was characterized by PXRD and SEM techniques. Several blank tests provided a fundamental understanding of the role of each constituent within the system, and a molecular mechanism for the catalytic cycle was proposed. [ABSTRACT FROM AUTHOR]

Published

2024

27. Emerging Trends and Challenges in Pink Hydrogen Research.

Author

Fernández-Arias, Pablo, Antón-Sancho, Álvaro, Lampropoulos, Georgios, and Vergara, Diego

Subjects

RENEWABLE energy sources, NUCLEAR reactors, PINK, NUCLEAR energy, CLEAN energy, HYDROGEN, SCIENCE databases

Abstract

Pink hydrogen is the name given to the technological variant of hydrogen generation from nuclear energy. This technology aims to address the environmental challenges associated with conventional hydrogen production, positioning itself as a more sustainable and eco-efficient alternative, while offering a viable alternative to nuclear power as a source of electricity generation. The present research analyzes the landscape of pink hydrogen research, an innovative strand of renewable energy research. The methodology included a comprehensive search of scientific databases, which revealed a steady increase in the number of publications in recent years. This increase suggests a growing interest in and recognition of the importance of pink hydrogen in the transition to cleaner and more sustainable energy sources. The results reflect the immaturity of this technology, where there is no single international strategy and where there is some diversity of research topic areas, as well as a small number of relevant topics. It is estimated that the future development of Gen IV nuclear reactors, as well as Small Modular Reactor (SMR) designs, will also favor the implementation of pink hydrogen. [ABSTRACT FROM AUTHOR]

Published

2024

28. Preparation of Fe-HMOR with a Preferential Iron Location in the 12-MR Channels for Dimethyl Ether Carbonylation.

Author

Liu, Wenrong, Wang, Yaquan, Bu, Lingzhen, Chu, Kailiang, Huang, Yitong, Guo, Niandong, Qu, Liping, Sang, Juncai, Su, Xuemei, Zhang, Xian, and Li, Yaoning

Subjects

CARBONYLATION, METHYL ether, BRONSTED acids, ETHYLENEDIAMINETETRAACETIC acid, COKE (Coal product), HYDROTHERMAL synthesis, MORDENITE, X-ray diffraction

Abstract

As the Brønsted acid sites in the 8-membered ring (8-MR) of mordenite (MOR) are reported to be the active center for dimethyl ether (DME) carbonylation reaction, it is of great importance to selectively increase the Brønsted acid amount in the 8-MR. Herein, a series of Fe-HMOR was prepared through one-pot hydrothermal synthesis by adding the EDTA–Fe complex into the gel. By combining XRD, FTIR, UV–Vis, Raman and XPS, it was found that the Fe atoms selectively substituted for the Al atoms in the 12-MR channels because of the large size of the EDTA–Fe complex. The NH3-TPD and Py-IR results showed that with the increase in Fe addition from Fe/Si = 0 to 0.02, the Brønsted acid sites derived from Si-OH-Al in the 8-MR first increased and then decreased, with the maximum at Fe/Si = 0.01. The Fe-modified MOR with Fe/Si = 0.01 showed the highest activity in DME carbonylation, which was three times that of HMOR. The TG/DTG results indicated that the carbon deposition and heavy coke formation in the spent Fe-HMOR catalysts were inhibited due to Fe addition. This work provides a practical way to design a catalyst with enhanced catalytic performance. [ABSTRACT FROM AUTHOR]

Published

2024

29. Impact of biodiesel blends on performance, emissions and waste heat recovery of diesel engine driven cogeneration system.

Author

CHAND, Saini Mahesh, PRAKASH, Jakhar Om, and ROHIT, Khatri

Subjects

DIESEL motors, HEAT recovery, WASTE heat, DIESEL fuels, RENEWABLE energy sources, HEAT engines, ENERGY conservation, ENERGY consumption

Abstract

Due to the rapidly increasing energy demand, the world needs to focus more on identifying alternative energy sources like biofuels and energy conservation techniques that enhance the efficiency of various systems. A cogeneration (CHP) system is one of the most emerging techniques for achieving the goal of energy conservation by providing useful power (electricity) and heating simultaneously. So the current study proposes a diesel engine-driven CHP system that is fueled with different blends of biodiesel. The objective of the current study is to investigate the impact of Eureka Sativa oil biodiesel on waste heat recovery, performance, and emission characteristics of diesel engine driven combined heating and power generation system. The cogeneration unit is developed by connecting the exhaust pipe of a single-cylinder, four-stroke diesel engine with a heat exchanger. The pure diesel, along with 10%, 15%, 20%, and 25% by volume of biodiesel, was used as fuel for the cogeneration unit. The AVL Di-Gas 444N multi-gas analyzer was utilized to evaluate the engine exhaust gas emissions. Diesel fuel has the highest brake thermal efficiency and the lowest brake specific fuel consumption (BSFC). B20 has the highest brake thermal efficiency and the lowest BSFC among all blends of biodiesel. Also, B20 has better emission characteristics than all other blends of biodiesel. The exhaust gas temperature and waste heat recovery increase with the percentage of biodiesel in the blends. The B25 has the highest overall efficiency (38.49%) among all blends, which is 1.93 % lower than pure diesel. However, result analysis revealed that B20 is the best fuel among all biodiesel blends in terms of engine performance and emission formation. Whereas B25 is a better fuel in terms of WHR and overall cogeneration unit efficiency. [ABSTRACT FROM AUTHOR]

Published

2024

30. 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

31. Optimally Splitting Solar Spectrums by Concentrating Solar Spectrums Splitter for Hydrogen Production via Solid Oxide Electrolysis Cell.

Author

Lang, Shaocheng, Yuan, Jinliang, and Zhang, Houcheng

Subjects

HYDROGEN production, SOLAR concentrators, ELECTROLYSIS, GREEN fuels, ELECTRIC currents, SOLAR spectra

Abstract

The concentrating solar spectrums splitter (CSSS)-driven solid oxide electrolysis cell (SOEC) is an attractive technology for green hydrogen production. The CSSS mainly comprises a concentrating photovoltaic (CPV), which converts sunlight with shorter wavelengths into electricity, and a concentrating solar collector (CSC), which converts the remaining sunlight into heat. However, the optimal splitting of the solar spectrums is a critical challenge that directly impacts the efficiency and normal operation of the SOEC. To address this challenge, a mathematical model integrating the CSSS with the SOEC is developed based on principles from thermodynamics and electrochemistry. By analyzing the requirements of electricity and heat for the SOEC, the model determines the optimal configuration and operational parameters. The results show that the anode-supported type, higher operating temperature, larger inlet flow rate of water, higher operating pressure of the SOEC, higher operating temperature of the CSC, and larger electric current of the CPV contribute to allocating more solar spectrums to the CSC for heat generation. However, the greater effectiveness of the heat exchangers, higher operating temperature, and larger optical concentration ratio of the CPV exhibit contrasting effects on the spectrum allocation. The obtained results provide valuable theoretical guidance for designing and running the CSSS for hydrogen production through SOEC. [ABSTRACT FROM AUTHOR]

Published

2024

32. A review of hydrogen production and storage materials for efficient integrated hydrogen energy systems.

Author

Alasali, Feras, Abuashour, Mohammed I., Hammad, Waleed, Almomani, Derar, Obeidat, Amr M., and Holderbaum, William

Subjects

HYDROGEN storage, CLEAN energy, SUSTAINABILITY, WATER electrolysis, INTERSTITIAL hydrogen generation, HYDROGEN production, HYDROGEN as fuel

Abstract

The rapidly growing global need for environmentally friendly energy solutions has inspired extensive research and development efforts aimed at harnessing the potential of hydrogen energy. Hydrogen, with its diverse applications and relatively straightforward acquisition, is viewed as a promising energy carrier capable of tackling pressing issues, such as carbon emissions reduction and energy storage. This study conducts a preliminary investigation into effective hydrogen generation and storage systems, encompassing methods like water electrolysis, biomass reforming, and solar‐driven processes. Specifically, the study focuses on assessing the potential of nanostructured catalysts and innovative materials to enhance the productivity and versatility of hydrogen energy systems. Additionally, the utilization of novel materials not only improves hydrogen storage capacity and safety but also opens up possibilities for inventive applications, including on‐demand release and efficient transportation. Furthermore, critical factors such as catalyst design, material engineering, system integration, and technoeconomic viability are examined to identify challenges and chart paths for future advancements. The research emphasizes the importance of fostering interdisciplinary collaborations to advance hydrogen energy technologies and contribute to a sustainable energy future. [ABSTRACT FROM AUTHOR]

Published

2024

33. Computational Fluid Dynamics–Discrete Phase Method Simulations in Process Engineering: A Review of Recent Progress.

Author

Yang, Xiaolian, Xi, Te, Qin, Yebo, Zhang, Hui, and Wang, Yongwei

Subjects

ENGINEERING simulations, PRODUCTION engineering, FLUIDS, COMPUTATIONAL fluid dynamics

Abstract

Complex fluid–solid systems generally exist in process engineering. The cognition of complex flow systems depends on numerical and experimental methods. The computational fluid dynamics–discrete phase method simulation based on coarsening technology has potential application prospects in industrial-scale equipment. This review outlines the computational fluid dynamics–discrete phase method and its application in several typical types of process engineering. In the process research, more attention is paid to the dense condition and multiphase flow. Furthermore, the CFD-DPM and its extension method for comprehensive hydrodynamics modeling are introduced. Subsequently, the current challenges and future trends of the computational fluid dynamics–discrete phase method are proposed. [ABSTRACT FROM AUTHOR]

Published

2024

34. Study on the Environmental Impact and Benefits of Incorporating Humus Composites in Anaerobic Co-Digestion Treatment.

Author

Zhao, Ke, Wei, Qiang, Bai, Mingxuan, and Shen, Mengnan

Subjects

ENVIRONMENTAL impact analysis, HUMUS, REFUSE collection, PRODUCT life cycle assessment, WASTE treatment, DIGESTION

Abstract

This study evaluated the environmental impact and overall benefits of incorporating humus composites in the anaerobic co-digestion of kitchen waste and residual sludge. The life cycle assessment method was used to quantitatively analyze the environmental impact of the entire anaerobic co-digestion treatment process of waste, including garbage collection, transportation, and final product utilization. Moreover, the comprehensive assessment of the environmental impact, energy-saving and emission-reduction abilities, and economic cost of using humus composites in the anaerobic co-digestion treatment process was conducted using a benefit analysis method. The results showed that the anaerobic co-digestion of kitchen waste and residual sludge significantly contributed to the mitigation of global warming potential (GWP), reaching −19.76 kgCO2-eq, but had the least impact on the mitigation of acidification potential (AP), reaching −0.10 kgSO2-eq. In addition, the addition of humus composites significantly increased the production of biogas. At a concentration of 5 g/L, the biogas yield of the anaerobic co-digestion process was 70.76 m3, which increased by 50.62% compared with the blank group. This amount of biogas replaces ~50.52 kg of standard coal, reducing CO2 emissions by 13.74 kg compared with burning the same amount of standard coal. Therefore, the anaerobic co-digestion treatment of kitchen waste and residual sludge brings considerable environmental benefits. [ABSTRACT FROM AUTHOR]

Published

2024

35. Comparative Review on the Production and Purification of Bioethanol from Biomass: A Focus on Corn.

Author

Assaf, Jean Claude, Mortada, Zeinab, Rezzoug, Sid-Ahmed, Maache-Rezzoug, Zoulikha, Debs, Espérance, and Louka, Nicolas

Subjects

ETHANOL as fuel, SUSTAINABILITY, BIOMASS, CORN, RENEWABLE energy sources, BIOMASS conversion, CLEAN energy

Abstract

In the contemporary era, conventional energy sources like oil, coal, and natural gas overwhelmingly contribute 89.6% to global CO2 emissions, intensifying environmental challenges. Recognizing the urgency of addressing climate concerns, a pivotal shift towards renewable energy, encompassing solar, wind, and biofuels, is crucial for bolstering environmental sustainability. Bioethanol, a globally predominant biofuel, offers a versatile solution, replacing gasoline or integrating into gasoline–ethanol blends while serving as a fundamental building block for various valuable compounds. This review investigates the dynamic landscape of biomass generations, drawing insightful comparisons between the first, second, third, and fourth generations. Amid the drive for sustainability, the deliberate focus on the initial generation of biomass, particularly corn, in bioethanol production is grounded in the current dependence on edible crops. The established utilization of first-generation biomass, exemplified by corn, underscores the necessity for a comprehensive examination of its advantages and challenges, allowing for a nuanced exploration of existing infrastructure and practices. To produce bioethanol from corn feedstock, various milling methods can be employed. Thus, this paper delves into a comparative assessment of dry-milling and wet-milling processes scrutinizing their efficiency, environmental impact, and economic feasibility. [ABSTRACT FROM AUTHOR]

Published

2024

36. Sustainability Assessment of 2G Bioethanol Production from Residual Lignocellulosic Biomass.

Author

Correia, Bárbara, Matos, Henrique A., Lopes, Tiago F., Marques, Susana, and Gírio, Francisco

Subjects

CORN stover, ETHANOL as fuel, RENEWABLE energy sources, LIGNOCELLULOSE, CORN residues, SUSTAINABILITY, FOSSIL fuels

Abstract

The development of sustainable biofuels can help to reduce the reliance on fossil fuels and mitigate the impact of climate change. This study analyzes bioethanol production from agro-forestry residual biomass, namely eucalyptus residues and corn stover. The study includes process simulation using Aspen Plus software, followed by economic analysis and life cycle assessment (LCA) with the help of SimaPro software and by applying the environmental footprint (EF) 3.0 method. The economic analysis on the biorefinery's economic viability, equipment, and production costs reveals a positive decision for bioethanol production from eucalyptus residues due to logistical and transportation costs. The minimum ethanol selling price (MESP) obtained was 2.19 €/L and 2.45 €/L for eucalyptus residues and corn stover, respectively. From the LCA with a functional unit of 1 MJ of ethanol, bioethanol production from eucalyptus residues results in a single score impact of 37.86 µPt, whereas for corn stover, it is 33.47 µPt. In the climate change impact category, the eucalyptus residues scenario has an impact of 0.264 kg CO2 eq/MJ ethanol while corn stover leads to 0.254 kg CO2 eq/MJ ethanol. In-situ enzyme production, heat integration, and the use of renewable energy sources were also analyzed. Combining in situ enzyme production with renewable energy sources lowers CO2 equivalent emissions by 89% for both feedstocks, in comparison to the base-case scenario. [ABSTRACT FROM AUTHOR]

Published

2024

37. Impact of irradiance and inorganic carbon availability on heterologous sucrose production in Synechococcus elongatus PCC 7942.

Author

Lisa Yun, Zegarac, Robert, and Ducat, Daniel C.

Subjects

SYNECHOCOCCUS elongatus, CYANOBACTERIAL toxins, SUCROSE, LIGHT intensity, CARBON

Abstract

Cyanobacteria have been proposed as a potential alternative carbohydrate feedstock and multiple species have been successfully engineered to secrete fermentable sugars. To date, the most productive cyanobacterial strains are those designed to secrete sucrose, yet there exist considerable differences in reported productivities across different model species and laboratories. In this study, we investigate how cultivation conditions (specifically, irradiance, CO2, and cultivator type) affect the productivity of sucrose-secreting Synechococcus elongatus PCC 7942. We find that S. elongatus produces the highest sucrose yield in irradiances far greater than what is often experimentally utilized, and that high light intensities are tolerated by S. elongatus, especially under higher density cultivation where turbidity may attenuate the effective light experienced in the culture. By increasing light and inorganic carbon availability, S. elongatus cscB/sps produced a total of 3.8 g L-1 of sucrose and the highest productivity within that period being 47.8 mg L-1 h-1. This study provides quantitative description of the impact of culture conditions on cyanobacteria-derived sucrose that may assist to standardize cross-laboratory comparisons and demonstrates a significant capacity to improve productivity via optimizing cultivation conditions. [ABSTRACT FROM AUTHOR]

Published

2024

38. Assessment of Hydrogen Energy Industry Chain Based on Hydrogen Production Methods, Storage, and Utilization.

Author

Ziobrowski, Zenon and Rotkegel, Adam

Subjects

ENERGY industries, GREEN fuels, PRODUCTION methods, RENEWABLE energy sources, HYDROGEN as fuel, HYDROGEN production, CARBON dioxide mitigation

Abstract

To reach climate neutrality by 2050, a goal that the European Union set itself, it is necessary to change and modify the whole EU's energy system through deep decarbonization and reduction of greenhouse-gas emissions. The study presents a current insight into the global energy-transition pathway based on the hydrogen energy industry chain. The paper provides a critical analysis of the role of clean hydrogen based on renewable energy sources (green hydrogen) and fossil-fuels-based hydrogen (blue hydrogen) in the development of a new hydrogen-based economy and the reduction of greenhouse-gas emissions. The actual status, costs, future directions, and recommendations for low-carbon hydrogen development and commercial deployment are addressed. Additionally, the integration of hydrogen production with CCUS technologies is presented. [ABSTRACT FROM AUTHOR]

Published

2024

39. Experimental Investigation of the Effect of Fault Reactivation Induced by Water Injection.

Author

Liu, Wenjing and Si, Hu

Subjects

FLUID pressure, ENERGY consumption, ENERGY development, PRESSURE control, GEOTHERMAL resources, INDUCED seismicity

Abstract

An understanding of fault reactivation induced by water injection is of great significance for geothermal energy development and utilization. We conducted a series of water injection shear tests on low-permeability granite samples that each contained a single saw-cut fault under locally undrained conditions. Slip characteristics were analyzed by varying the fluid pressurization rate, confining pressure, and stress state of the fault to understand fault reactivation. The experimental results demonstrated that at a high pressurization rate, a higher local fluid pressure was needed to reactivate the fault than had been estimated theoretically, and the required fluid pressure increased with an increase in pressurization rate. The fluid pressurization rate and confining pressure both controlled the slip mode of the fault. The slip mode changed from dynamic slip to quasi-static slip at a high pressurization rate, and the peak slip rate of dynamic slip increased with an increasing pressurization rate. The fault showed significant stick-slip characteristics under a high confining pressure, as fault locking and reactivation phenomena occurred repeatedly. Faults with different initial stress states had little influence on the slip mode after the onset of slip. [ABSTRACT FROM AUTHOR]

Published

2024

40. Development of Transition Metal Phosphates NiCoP/NF and Evaluation of Their Hydrogen Evolution Properties.

Author

Bo YU, Lei YU, and Yan LI

Subjects

TRANSITION metals, WATER electrolysis, FOSSIL hominids, ELECTROLYTE solutions, HETEROGENEOUS catalysts, OXYGEN evolution reactions, HYDROGEN evolution reactions

Abstract

Energy and the environment are one of the most important global issues in the 21st century. In order to avoid the excessive destruction of the environment and human settlements by fossil fuels, and achieve sustainable development of the Earth, clean energy carrier hydrogen shows its application value. Facing the challenges in preparing transition metal phosphides, in this study, transition metal salts and urea were used as raw materials to react under hydrothermal conditions. The transition metal basic carbonate NiCo2(CO3)1.5OH3 was grown in situ on nickel-foam (NF) substrates. After low-temperature phosphating treatment, NiCoP alloy phosphide electrocatalysts (NiCoP/NF) grown on nickel-foam substrates were obtained. The electrochemical hydrogen evolution performance was tested in 1 mol/L KOH alkaline electrolyte solution. Experiments show, NiCoP/NF heterostructure catalyst has excellent hydrogen evolution performance. In an alkaline medium, the overpotential required to obtain the catalytic current density of 10 mA/cm² is only 93 mV, and the Tafel slope is 118 mV/dec. This is largely due to: 1) the good dispersion of NiCoP/NF nano-catalyst on the Nickel Foam substrate increased the number of active sites exposed; 2) the heterostructure promotes the electron interaction between NiCoP and NF; 3) theoretical calculations show that the construction of NiCoP/NF heterostructure can effectively reduce the dissociation barrier of water, promote the dissociation of water, the kinetic reaction process of electrocatalytic hydrogen evolution is accelerated. Therefore, the construction of NiCoP/NF nanostructured heterogeneous catalysts enriches the application of non-noble metal nanomaterials in the field of hydrogen production from water electrolysis. [ABSTRACT FROM AUTHOR]

Published

2024

41. Ethanol Production from a Mixture of Waste Tissue Paper and Food Waste through Saccharification and Mixed-Culture Fermentation.

Author

Ma, Hongzhi, Wang, Yueyao, Lv, Pin, Zhou, Jun, Gao, Ming, Qian, Dayi, Song, Bo, and Wang, Qunhui

Subjects

WASTE paper, FOOD waste, ETHANOL, FERMENTATION, SACCHAROMYCES cerevisiae, TEMPERATURE control

Abstract

This study focused on the co-fermentation of food waste and tissue paper to produce ethanol, which will eliminate the need for additional nitrogen sources and nutrients, thereby reducing production costs. In response to the inhibitory effect of the high concentrations of glucose present in mixed-substrate hydrolysates on xylose fermentation, a co-fermentation process using Saccharomyces cerevisiae and Candida shehatae was proposed. This approach reduced the fermentation time by 24 h, increased the xylose utilization rate to 88%, and improved the ethanol yield from 41% to 46.5%. The impact of external conditions and corresponding optimization were also analyzed in this process. The optimum conditions were a 1:3 ratio of Saccharomyces cerevisiae to Candida shehatae, a pH of 5, and shaking at 150 r/min, and by employing dynamic temperature control, the ethanol production was increased to 21.98 g/L. Compared to conventional processes that only use Saccharomyces cerevisiae, this method enhanced the ethanol yield from 41% to 49%. [ABSTRACT FROM AUTHOR]

Published

2024

42. Tribological Study of Fe–Cr Alloys for Mechanical Refinement in a Corn Stover Biomass Environment.

Author

Brooks, Nicholas, Brewer, Luke, Beheshti, Ali, and Davami, Keivan

Subjects

CORN stover, MECHANICAL alloying, PITTING corrosion, BIOMASS, STAINLESS steel, WEAR resistance, SLURRY, MECHANICAL abrasion

Abstract

The tribological behavior of three Fe–Cr alloys with Cr contents ranging from ~12 to 16 wt.% as well as low-alloy high-carbon 52100 steel were investigated using pin-on-disk wear testing. Wear tests were performed in both open atmospheric (dry) and biomass environments (wet). Delamination and abrasion were observed to be the dominant wear regimes following dry wear tests. For wet testing, adhesion and pitting corrosion were determined to be the primary wear mechanisms in the Fe–Cr alloys while adhesion and delamination/cracking were identified as the primary wear mechanisms in the 52100 steel. The 440C stainless steel and 52100 steel specimens exhibited the lowest wear volume following dry (7.58 ± 0.52 mm3 and 0.78 ± 0.05 mm3, respectively) and wet wear testing (0.11 ± 0.06 mm3 and 0.12 ± 0.09 mm3, respectively); however, these specimens exhibited the most significant corrosion damage. The 410 stainless steel specimen exhibited the best resistance to corrosion after wear testing in the deacetylated and disc-refined corn stover slurry and had measured wear volumes after dry and wet wear testing of 6.84 ± 0.88 mm3 and 0.33 ± 0.12 mm3, respectively. The worst wear resistance was observed by the 420 stainless steel specimen after both dry and wet wear testing. [ABSTRACT FROM AUTHOR]

Published

2024

43. Bioethanol production from sugarcane molasses by co-fermentation of Saccharomyces cerevisiae isolate TA2 and Wickerhamomyces anomalus isolate HCJ2F-19.

Author

Hawaz, Estifanos, Tafesse, Mesfin, Tesfaye, Anteneh, Kiros, Solomon, Beyene, Dereje, Kebede, Gessesse, Boekhout, Teun, Groenwald, Marizeth, Theelen, Bart, Degefe, Ayantu, Degu, Sisay, Admasu, Alene, Hunde, Biru, and Muleta, Diriba

Subjects

ETHANOL as fuel, SACCHAROMYCES cerevisiae, MOLASSES, RESPONSE surfaces (Statistics), SUGARCANE

Abstract

Purpose: Co-culturing is a widely used method to improve bioethanol production from biomass enriched in fermentable sugars. This study aims to produce bioethanol from sugarcane molasses by simultaneous co-fermentation of S. cerevisiae isolate TA2 and W. anomalus isolate HCJ2F-19. Methods: Response surface methodology (RSM) based on the central composite design (CCD) was employed to optimize fermentation conditions, including mixing rate (110–150 rpm), temperature (25–35 °C), molasses concentration (25–35 obrix), and incubation time (36–72 h). The ethanol concentration was analyzed using HPLC equipped with a UV detector. Results: The monocultureS. cerevisiae isolate TA2 produced 17.2 g.L−1 of ethanol, 0.33 g.g−1 of ethanol yield, and 0.36 g.L−1.h−1 of productivity compared to W. anomalus isolate HCJ2F that produced 14.5 g.L−1, 0.30 g.g−1 and 0.28 g.L−1.h−1 ethanol, ethanol yield, and productivity under laboratory conditions, respectively. In comparison to single cultures of S. cerevisiae TA2 and W. anomalus HCJ2F, the co-fermentation using both isolates showed an increased ethanol yield of 29% and 53% compared to the single species fermentations, respectively. The results showed that the growth of W. anomalus HCJ2F-19 and S. cerevisiae TA2 was not influenced by each other during the co-fermentation process. The one variable at a time optimization (OVAT) analysis resulted in an ethanol concentration of 26.5 g.L−1 with a specific yield and productivity of 0.46 g.g−1, 0.55 g.L−1.h−1, respectively, at pH 5.5, 25 obrix, 48 h, 150 rpm, 30 °C, 60:40 inoculum ratio, and 10% overall inoculum size. The maximum ethanol concentration of 35.5 g.L−1 was obtained by co-fermentation using the RSM-CCD tool at 30 obrix, 30 °C, 54 h, and 130 rpm. Conclusion: The results suggested that the co-fermentation of S. cerevisiae isolate TA2 and W. anomalus isolate HCJ2F improves bioethanol production from sugar cane molasses under optimum fermentation conditions. [ABSTRACT FROM AUTHOR]

Published

2024

44. Separation of Cellulose from Wastewater and Valorisation via Pyrolysis: A Case Study in the Czech Republic.

Author

Djordjevićová, Denisa, Carnevale Miino, Marco, Raček, Jakub, Chorazy, Tomáš, Hlavínek, Petr, and Vranayova, Zuzana

Subjects

SEWAGE sludge digestion, UPFLOW anaerobic sludge blanket reactors, CELLULOSE, SEWAGE disposal plants, WASTE recycling, SEWAGE, BIOGAS production

Abstract

Currently, the recovery of resources from urban wastewater (WW) represents a priority. On this topic, the potential recovery of cellulose for its subsequent reuse in different sectors is gaining interest. In this work, a large-size conventional wastewater treatment plant (WWTP) was selected as a case study. A preliminary mechanical treatment was used, with the aim of separating, quantifying, and characterizing cellulose in WW. The results suggest that the per-capita production of dry primary cellulosic sludge (D-PCS) is equal to 1.46 ± 0.13 kgD-PCS PE−1 y−1, with an average calorific value of 21.04 MJ kg−1DM. Cellulosic fibres have an average length of >100 µm and a thickness of 2–5 µm. The D-PCS was subsequently treated via medium-temperature pyrolysis; a total of 29.5% of the initial D-PCS was converted into pyrolyzed primary cellulosic sludge (P-PCS) and only 26% into pyrolytic gas. More than 44.5% of the dried cellulose can be converted into pyrolytic oil. Moreover, three different scenarios of recovery have been considered, and the impact of cellulose separation in terms of COD fluxes entering the WWTP and potential energy recovery has been studied. The results suggested that, in this case study, the potential separation of the primary cellulosic sludge from the influent water flux would have no significant impact on COD load entering the biological treatments and biogas production in the anaerobic digestion of the secondary sludge. [ABSTRACT FROM AUTHOR]

Published

2024

45. A Comprehensive Review of Bimetallic Nanoparticle–Graphene Oxide and Bimetallic Nanoparticle–Metal–Organic Framework Nanocomposites as Photo-, Electro-, and Photoelectrocatalysts for Hydrogen Evolution Reaction.

Author

Makhafola, Mogwasha Dapheny, Balogun, Sheriff Aweda, and Modibane, Kwena Desmond

Subjects

HYDROGEN evolution reactions, NANOCOMPOSITE materials, BIMETALLIC catalysts, GRAPHENE oxide, ALLOYS, HYDROGEN production, ACTIVATION energy

Abstract

This review extensively discusses current developments in bimetallic nanoparticle–GO and bimetallic nanoparticle–MOF nanocomposites as potential catalysts for HER, along with their different synthesis methodologies, structural characteristics, and catalytic mechanisms. The photoelectrocatalytic performance of these catalysts was also compared based on parameters such as Tafel slope, current density, onset potential, turnover frequency, hydrogen yield, activation energy, stability, and durability. The review shows that the commonly used metal alloys in the bimetallic nanoparticle–GO-based catalysts for HERs include Pt-based alloys (e.g., PtNi, PtCo, PtCu, PtAu, PtSn), Pd-based alloys (e.g., PdAu, PdAg, PdPt) or other combinations, such as AuNi, AuRu, etc., while the most used electrolyte sources are H2SO4 and KOH. For the bimetallic nanoparticle MOF-based catalysts, Pt-based alloys (e.g., PtNi, PtCu), Pd-based alloys (e.g., PdAg, PdCu, PdCr), and Ni-based alloys (e.g., NiMo, NiTi, NiAg, NiCo) took the lead, with KOH being the most frequently used electrolyte source. Lastly, the review addresses challenges and prospects, highlighting opportunities for further optimization and technological integration of the catalysts as promising alternative photo/electrocatalysts for future hydrogen production and storage. [ABSTRACT FROM AUTHOR]

Published

2024

46. Renewable Energy Potential: Second-Generation Biomass as Feedstock for Bioethanol Production.

Author

Igwebuike, Chidiebere Millicent, Awad, Sary, and Andrès, Yves

Subjects

ETHANOL as fuel, RENEWABLE energy sources, BIOMASS, CLEAN energy, POTENTIAL energy, PLANT biomass

Abstract

Biofuels are clean and renewable energy resources gaining increased attention as a potential replacement for non-renewable petroleum-based fuels. They are derived from biomass that could either be animal-based or belong to any of the three generations of plant biomass (agricultural crops, lignocellulosic materials, or algae). Over 130 studies including experimental research, case studies, literature reviews, and website publications related to bioethanol production were evaluated; different methods and techniques have been tested by scientists and researchers in this field, and the most optimal conditions have been adopted for the generation of biofuels from biomass. This has ultimately led to a subsequent scale-up of procedures and the establishment of pilot, demo, and large-scale plants/biorefineries in some regions of the world. Nevertheless, there are still challenges associated with the production of bioethanol from lignocellulosic biomass, such as recalcitrance of the cell wall, multiple pretreatment steps, prolonged hydrolysis time, degradation product formation, cost, etc., which have impeded the implementation of its large-scale production, which needs to be addressed. This review gives an overview of biomass and bioenergy, the structure and composition of lignocellulosic biomass, biofuel classification, bioethanol as an energy source, bioethanol production processes, different pretreatment and hydrolysis techniques, inhibitory product formation, fermentation strategies/process, the microorganisms used for fermentation, distillation, legislation in support of advanced biofuel, and industrial projects on advanced bioethanol. The ultimate objective is still to find the best conditions and technology possible to sustainably and inexpensively produce a high bioethanol yield. [ABSTRACT FROM AUTHOR]

Published

2024

47. The Experimental Analysis of Biochar Combustion in a Traveling Grate Furnace.

Author

Ferreira, Tânia, Paiva, João Monney, and Pinho, Carlos

Subjects

COMBUSTION, RENEWABLE energy sources, BIOCHAR, BIOMASS energy, FURNACES, CLUSTER pine

Abstract

The current energy policy targets reducing energy dependence and minimizing pollutant emissions. Therefore, with the growing interest in using biomass as an alternative energy source, conducting scientific studies on its behavior and optimizing the respective conversion systems has become imperative. The present study focuses on investigating the combustion of biochar pellets in a laboratory-scale traveling grate furnace at three different bed temperatures: 700, 750, and 800 °C. The biochars were obtained via the carbonization process of Pinus pinaster, Acacia dealbata, and Cytisus scoparius pellets. The biochar combustion was studied using a moving-bed carbon particle burning model, supported by kinetic information which was obtained via the combustion of the same biochars in a bubbling fluidized bed. The diffusive parameter which was representative of this traveling grate combustion technology was determined, particularly the bed bypass factor. The combustion tests were carried out with the incomplete combustion of the char pellets. In general, the increase in biochar size led to a decrease in the bypass factor. However, the furnace temperature did not influence this parameter. [ABSTRACT FROM AUTHOR]

Published

2024

48. 钠离子电池用生物质基硬碳的研究进展.

Author

吴芮瑶, 欧阳丹丹, 艾礼莉, 刘岸杰, 朱 慧, 高晓鑫, and 殷 娇

Abstract

Copyright of Chinese Journal of Applied Chemistry is the property of Chinese Journal of Applied Chemistry and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

49. Study of the effect of ignition crank angle and mixture composition on the performance of a spark-ignition engine fueled with ethanol.

Author

JAKLIŃSKI, Piotr, CZARNIGOWSKI, Jacek, and ŚCISŁOWSKI, Karol

Subjects

EXHAUST gas from spark ignition engines, ETHANOL, ALTERNATIVE fuels for spark ignition engines, NITROGEN oxides, BIOMASS energy, ALTERNATIVE fuels

Abstract

The publication presents the results of the measurements of the operating parameters of a spark-ignition engine fueled with 95-octane unleaded gasoline (ES95) and ethyl alcohol, approx. 92%. The measurements were carried out at a constant load: an engine speed of 1500 rpm and a constant pressure in the intake system - MAP = 0.45 bar. For each type of fuel, the measurements were carried out in two series for two variables. The ignition crank angle was varied in the range of 0°÷40° and the mixture composition λ in the range of 0.85-1.25. The recorded engine performance parameters included torque, intake manifold pressure, intake air temperature, exhaust gas temperature and temporal fuel consumption; and exhaust gas composition was examined in terms of carbon monoxide, hydrocarbons and nitrogen oxides. The study showed that an ethanol-fueled engine has lower average efficiency compared to a gasoline one. The highest efficiency for ethanol was obtained for rich mixtures in the range λ = 0.85-1.0 and at high ignition advance angles. The use of alcohol fuel showed a very favorable effect on the composition of exhaust gas and a significantly lower content of harmful exhaust components was demonstrated. For the same operating points, carbon monoxide content was reduced by an average of 15%, and hydrocarbons and nitrogen oxides by an average of 80%. [ABSTRACT FROM AUTHOR]

Published

2024

50. Are Biological Pretreatments of Lignocellulosic Residues a Real Option for Biofuels Production?

Author

Alba Fierro, Carlos Antonio, Escobedo Bretado, Miguel Ángel, Núñez Ramírez, Diola Marina, Martell Nevárez, María Angélica, and Ríos Fránquez, Francisco Javier

Subjects

LIGNOCELLULOSE, BIOMASS energy, MICROBIAL enzymes, LIGNINS, CELLULOSE, SUGARS, ETHANOL as fuel

Abstract

The use of lignocellulosic residues as feedstocks for biofuels production represents an economic and ecofriendly option, since they are generated as byproducts or wastes from different industrial areas. Nevertheless, a pretreatment method aimed at eliminating the lignin content of these residues must be performed. This is required in order to increase cellulose bioavailability, which favors the production of reducing sugars through microbial or enzymatic attack. Some performed pretreatments can be classified as physical, chemical, and physicochemical methods. Although such methods are the most used pretreatments, they are expensive and generate or make use of harmful compounds. Biological methods, by the action of microorganisms or their enzymes for lignin content reduction, may be regarded as an alternative, being cheaper and more friendly to the environment than the aforementioned methods. However, until now, biological pretreatments have not shown the same yield as the previously mentioned methods in both sugar recovery and biofuel production. In that sense, the aim of this work is to review the efficiency of these methods, with the goal of clarifying their advantages and disadvantages for improvement of biofuel production. [ABSTRACT FROM AUTHOR]

Published

2024