Your search keyword '"ENERGY shortages"' showing total 791 results

1. Metal Imidazole-Modified Covalent Organic Frameworks as Electrocatalysts for Alkaline Oxygen Evolution Reaction.

Author

Xia, Meng, Yu, Xinxin, Wu, Zhuangzhuang, Zhao, Yuzhen, Feng, Lijuan, and Chen, Qi

Subjects

*GREENHOUSE gases, *OXYGEN evolution reactions, *RENEWABLE energy sources, *ENERGY shortages, *POLLUTION

Abstract

Since the product contains no carbon-based substances and can be driven by non-carbon-based electricity, electrocatalytic water splitting is considered to be among the most effective strategies for alleviating the energy crisis and environmental pollution. This process helps lower greenhouse gas emissions while also supporting the shift toward renewable energy sources. The anodic oxygen evolution reaction (OER) involves a more complex multi-electron transfer process, which is the principal limiting factor in overall water splitting. Extensive research has demonstrated that the controlled design of effective electrocatalysts can address this limitation. In this study, a previously unreported covalent organic framework material (COF-IM) was synthesized via a post-synthetic modification strategy. Notably, COF-IM contains imidazole nitrogen metal active sites. Transition metal-coordinated COF-IM@Co can function as a highly effective electrocatalyst, exhibiting a lower overpotential (403.8 mV@10 mA cm−2) in alkaline electrolytes, thereby highlighting its potential for practical applications in energy conversion technologies. This study offers new perspectives on the design and synthesis of COFs, while also making substantial contributions to the advancement and application of OER electrocatalysts. [ABSTRACT FROM AUTHOR]

Published

2024

2. Design and Preparation of Heterostructured Cu 2 O/TiO 2 Materials for Photocatalytic Applications.

Author

Tai, Yating, Yang, Boxuan, Li, Jing, Meng, Lingshi, Xing, Pengcheng, and Wang, Shengjie

Subjects

*CHEMICAL energy, *POWER resources, *PHOTOCATALYSTS, *CLEAN energy, *ENERGY shortages

Abstract

The extensive use of fossil fuels has sped up the global development of the world economy and is accompanied by significant problems, such as energy shortages and environmental pollution. Solar energy, an inexhaustible and clean energy resource, has emerged as a promising sustainable alternative. Light irradiation can be transformed into electrical/chemical energy, which can be used to remove pollutants or transform contaminants into high-value-added chemicals through photocatalytic reactions. Therefore, photocatalysis is a promising strategy to overcome the increasing energy and environmental problems. As is well-known, photocatalysts are key components of photocatalytic systems. Among the widely investigated photocatalysts, titanium dioxide (TiO2) has attracted great attention owing to its excellent light-driven redox capability and photochemical stability. However, its poor solar light response and rapid recombination of electron–hole pairs limit its photocatalytic applications. Therefore, strategies to enhance the photocatalytic activity of TiO2 by narrowing its bandgap and inhibiting the recombination of charges have been widely accepted. Constructing heterojunctions with other components, including cuprous oxide (Cu2O), has especially narrowed the bandgap, providing a promising means of solving the present challenges. This paper reviews the advances in research on heterostructured Cu2O/TiO2 photocatalysts, such as their synthesis methods, mechanisms for the enhancement of photocatalytic performance, and their applications in hydrogen production, CO2 reduction, selective synthesis, and the degradation of pollutants. The mechanism of charge separation and transfer through the Cu2O/TiO2 heterojunctions and the inherent factors that lead to the enhancement of photocatalytic performance are extensively discussed. Additionally, the current challenges in and future perspectives on the use of heterostructured Cu2O/TiO2 photocatalysts are also highlighted. [ABSTRACT FROM AUTHOR]

Published

2024

3. Recent Advances in the Utilization of Chiral Covalent Organic Frameworks for Asymmetric Photocatalysis.

Author

Liu, Peng, Dai, Weijun, Shen, Xianfu, Shen, Xiang, Zhao, Yuxiang, and Liu, Jian-Jun

Subjects

*DERACEMIZATION, *ENERGY shortages, *PROBLEM solving, *ENERGY consumption, *ORGANIC compounds, *PHOTOCATALYSIS

Abstract

The use of light energy to drive asymmetric organic transformations to produce high-value-added organic compounds is attracting increasing interest as a sustainable strategy for solving environmental problems and addressing the energy crisis. Chiral covalent organic frameworks (COFs), as porous crystalline chiral materials, have become an important platform on which to explore new chiral photocatalytic materials due to their precise tunability, chiral structure, and function. This review highlights recent research progress on chiral COFs and their crystalline composites, evaluating their application as catalysts in asymmetric photocatalytic organic transformations in terms of their structure. Finally, the limitations and challenges of chiral COFs in asymmetric photocatalysis are discussed, with future opportunities for research being identified. [ABSTRACT FROM AUTHOR]

Published

2024

4. Heterogeneous Responses of Energy and Non-Energy Assets to Crises in Commodity Markets.

Author

Vortelinos, Dimitrios, Menegaki, Angeliki, Passas, Ioannis, Garefalakis, Alexandros, and Viskadouros, Georgios

Subjects

*COMPARATIVE method, *MOMENTS method (Statistics), *COMMODITY exchanges, *GARCH model, *ENERGY shortages

Abstract

In this study, we investigate the heterogeneity in energy and non-energy commodities by analyzing their four realized moments: returns, realized volatility, realized skewness and realized kurtosis. Utilizing monthly data, we examine two commodity categories over various crisis periods. This study examines a comparative approach to descriptive statistics across different crisis periods and the full sample and assesses the out-of-sample significance of heteroscedasticity using GARCH models. The findings reveal significant heterogeneity in both energy and non-energy commodities, with energy commodities exhibiting higher average returns and volatility. Crisis periods markedly influence the statistical properties of these commodities. GARCH models outperform ARMA models in forecasting realized moments, particularly for non-energy commodities. This research contributes to the literature by providing robust evidence of heterogeneity in commodity markets and highlights the importance of considering all four realized moments in such analyses. [ABSTRACT FROM AUTHOR]

Published

2024

5. Utilization of Biomass Waste Through Small-Scale Gasification Technology in the Eastern Cape Province in South Africa: Towards the Achievement of Sustainable Development Goal Number 7.

Author

Chivanga, Shylet Yvonne and Mukumba, Patrick

Subjects

*RENEWABLE energy sources, *BIOMASS gasification, *ALTERNATIVE fuels, *ENERGY shortages, *RURAL poor

Abstract

Despite being resource-richly endowed with various energy sources, and despite the connection of 89.8% of the households to the grid in South Africa, the Eastern Cape province, as compared to other provinces, has the lowest level of grid connection of about 64.5%. Some of the rural poor households in the Eastern Cape province supplement their free basic electricity with unclean energy alternatives. Using unclean energy alternatives is not only detrimental to the environment and health of the people, but it is a sign of energy poverty and among the contributing factors to depesantization, deagrarianization, and deindustrialization which prolongs the underdevelopment in rural areas. Innovation in energy technologies is a key ingredient in meaningful rural development. The utilization of small-scale biomass gasification technologies can be a solution to the South African energy crisis in rural areas, and it is in line with sustainable development goal number 7, which is about ensuring access to affordable, reliable, sustainable, and modern energy for all. Alternative renewable energy sources cannot be ignored when dealing with the energy crises in South Africa. Renewable energy sources in the country include biomass, solar, wind, and hydropower. Despite its low utilization in the Eastern Cape province, small-scale biomass gasification technology remains pivotal in reducing energy crisis by producing electricity. However, the affordability of biomass gasification technology also plays a role in whether people will accept small-scale biomass gasification technology. The purpose of this paper is to determine the possibilities of using small-scale biomass gasification technology. This paper gives a comprehensive review of small-scale biomass gasification technology potential in the Eastern Cape province and the link between acceptance of small-scale gasification technology and affordability by evaluating the availability of biomass sources in the province and achievements with regards to small-scale biomass gasification. This paper also covers the impact of biomass gasification technology integration in the energy grid, what needs to be taken into consideration before its installation, its benefits and the barriers to its development in Eastern Cape province. [ABSTRACT FROM AUTHOR]

Published

2024

6. Review of Major Influencing Factors Contributing to Persisting Safety Problems in Coal Mines: Addressing Systemic Challenges.

Author

Wang, Jiyu, Zheng, Xigui, Shahani, Niaz Muhammad, Guo, Xiaowei, Xin, Wei, Yue, Wei, Liu, Longhe, and Yan, Kai

Subjects

COAL mining safety, MINE safety, ENERGY shortages, CONSUMPTION (Economics), ENERGY consumption, SAFETY standards

Abstract

The coal mining industry in Pakistan faces recurring fatal accidents due to data scarcity, lack of research, and technology adoption. This paper reviews the current status of coal mining, the ongoing energy crisis, the utilization of indigenous coal resources, and the prevailing safety challenges. By comparing coal mining safety standards in Pakistan with global benchmarks, this study proposes advanced mining technologies to improve productivity and safety. This study emphasizes the importance of investigating the underlying factors causing mining accidents in order to devise effective strategies to mitigate them. The lack of relevant data and the reluctance to adopt technology in the industry are identified as major obstacles to improving safety conditions. The proposed strategies for overcoming safety issues include improving data collection and analysis, increasing research efforts, and promoting the adoption of advanced technology. Thus, this paper highlights the urgent need to address safety concerns in Pakistan's coal mining industry to avoid further loss of lives and resources. [ABSTRACT FROM AUTHOR]

Published

2024

7. A Review: Recent Advances of Piezoelectric Photocatalysis in the Environmental Fields.

Author

Ye, Zhengjie, Zheng, Ru, Li, Shuangjun, Wang, Qing, Zhang, Rui, Yu, Chenjing, Lei, Jia, Liu, Xiaoyan, and Zhang, Dieqing

Subjects

*CHEMICAL energy conversion, *PIEZOELECTRICITY, *CHEMICAL energy, *ELECTRIC fields, *ENERGY shortages, *PHOTOCATALYSTS, *PHOTOCATALYSIS

Abstract

Piezoelectric photocatalysis can effectively suppress the recombination of electron holes during the course of photocatalysis, which has been widely applied in environmental and energy catalysis. Its advantage is that when the piezoelectric effect happens, a built-in electric field is formed inside the catalyst, which improves the separation efficiency of photogenerated charge carriers and obtains more excellent photocatalytic performance. The efficient conversion of mechanical energy to chemical energy can be realized through the synergistic effect of the piezoelectric effect, and photocatalysis is greatly significant in solving the energy crisis and providing environmental protection. Therefore, we organized a more complete review to better understand the mechanism and system of piezoelectric photocatalysis. We briefly introduce the principle of the piezoelectric effect, the existing types of piezoelectric photocatalysts, the practical application scenarios, and the future challenges and feasible methods to improve catalytic efficiency. The purpose of this review is to help us broaden the idea of designing piezoelectric photocatalysts, clarify the future research direction, and put it into more fields of environmental protection and energy reuse. [ABSTRACT FROM AUTHOR]

Published

2024

8. Design and Modeling of Coreless Magnetoelectric Transducers for Snake-like Wave Energy Converters.

Author

Duan, Weiping, Zhang, Yuxiang, Liu, Shihao, Shen, Qian, Hou, Zhiwei, and Chen, Renwen

Subjects

RENEWABLE energy sources, MAGNETIC circuits, WAVE energy, ENERGY shortages, ENERGY development

Abstract

With the development of the economy, people's demand for energy is increasing, which has led to a shortage of fossil fuels. Wave energy is a widely distributed renewable energy source, and the development of wave energy generation technology can greatly alleviate the energy shortage problem. This study takes the snake-like wave energy converter (WEC) as an example and designs a coreless magnetoelectric transducer for it. The structure of the coreless magnetoelectric transducer is relatively simple, eliminating the iron core in the transducer, which can eliminate its own damping. At the same time, this structure can minimize the gap between the magnet and the coil, improve energy conversion efficiency, and work continuously under complex working conditions. This study takes two types of coreless magnetoelectric transducers as examples to analyze. This study aims to establish equivalent magnetic circuit models for the coreless magnetoelectric transducers, explore the effects of different magnets on the performance of the transducers, and optimize the parameters in the transducers. We used simulation software to analyze the transducer and verify the accuracy of the models. Finally, prototypes of the coreless magnetoelectric transducers were made, and a testing system for the transducer was established to test its energy conversion capability. Our experiments show that coreless magnetoelectric transducers have good energy conversion capabilities and can be used as transducers for snake-like WECs. At the same time, this type of transducer can also be applied to other types of WECs, providing a new approach for the research of WECs. [ABSTRACT FROM AUTHOR]

Published

2024

9. Recent Advances in Novel Catalytic Hydrodeoxygenation Strategies for Biomass Valorization without Exogenous Hydrogen Donors—A Review.

Author

Zhao, Bojun, Du, Bin, Hu, Jiansheng, Huang, Zujiang, Xu, Sida, Chen, Zhengyu, Cheng, Defang, and Xu, Chunbao

Subjects

*BIOMASS liquefaction, *BIOMASS chemicals, *ENERGY shortages, *RENEWABLE energy sources, *FOSSIL fuels

Abstract

Driven by the growing energy crisis and environmental concerns regarding the utilization of fossil fuels, biomass liquefaction has emerged as a highly promising technology for the production of renewable energy and value-added chemicals. However, due to the high oxygen content of biomass materials, biocrude oil produced from liquefaction processes often contains substantial oxygenated compounds, posing challenges for direct downstream applications. Catalytic hydrodeoxygenation (HDO) upgrading with hydrogen donors is crucial for improving the quality and applicability of biomass-derived fuels and chemicals. The costs, safety, and sustainability concerns associated with high-pressure gaseous hydrogen and organic molecule hydrogen donors are driving researchers to explore alternative and innovative biomass hydrodeoxygenation approaches without exogenous hydrogen donors. This review offers an overview of the recent developments in catalytic hydro-liquefaction and hydrodeoxygenation methods for biomass valorization without external hydrogen donation, including catalytic self-transfer hydrogenolysis using endogenous hydrogen in biomass structure, in situ catalytic hydrodeoxygenation employing water as the hydrogen donor, and in situ hydrodeoxygenation via water splitting assisted by zero-valent metals. The in situ hydrogen supply mechanisms and the impact of various hydrodeoxygenation catalysts on hydrogen donation efficiency using endogenous hydrogen are summarized in detail in this work. Furthermore, the current obstacles and future research demands are also discussed in order to provide valuable recommendations for the advancement of biomass utilization technologies. [ABSTRACT FROM AUTHOR]

Published

2024

10. Research Progress on Moisture-Sorption Actuators Materials.

Author

Zhang, Dajie, Ding, Jia, Zhou, Yulin, and Ju, Jie

Subjects

*MECHANICAL energy, *CLEAN energy, *ELECTRICAL energy, *ENERGY conversion, *ENERGY shortages

Abstract

Actuators based on moisture-sorption-responsive materials can convert moisture energy into mechanical/electrical energy, making the development of moisture-sorption materials a promising pathway for harnessing green energy to address the ongoing global energy crisis. The deformability of these materials plays a crucial role in the overall energy conversion performance, where moisture sorption capacity determines the energy density. Efforts to boost the moisture absorption capacity and rate have led to the development of a variety of moisture-responsive materials in recent years. These materials interact with water molecules in different manners and have shown diverse application scenarios. Here, in this review, we summarize the recent progress on moisture-sorption-responsive materials and their applications. We begin by categorizing moisture-sorption materials—biomaterials, polymers, nanomaterials, and crystalline materials—according to their interaction modes with water. We then review the correlation between moisture-sorption and energy harvesting performance. Afterwards, we provide examples of the typical applications using these moisture-sorption materials. Finally, we explore future research directions aimed at developing next-generation high-performance moisture-sorption materials with higher water uptake, tunable water affinity, and faster water absorption. [ABSTRACT FROM AUTHOR]

Published

2024

11. Design and Optimization of a Gorlov-Type Hydrokinetic Turbine Array for Energy Generation Using Response Surface Methodology.

Author

Chalaca, Andrés, Velásquez, Laura, Rubio-Clemente, Ainhoa, and Chica, Edwin

Subjects

*RESPONSE surfaces (Statistics), *COMPUTATIONAL fluid dynamics, *SINGLE-degree-of-freedom systems, *FLUID flow, *ENERGY shortages

Abstract

Hydrokinetic arrays, or farms, offer a promising solution to the global energy crisis by enabling cost-effective and environmentally friendly energy generation in locations with water flows. This paper presents research focused on the design and optimization of a Gorlov-type vertical-axis hydrokinetic turbine array for power generation. The study involved (i) numerical simulations using computational fluid dynamics (CFD) software with the six degrees of freedom (6DoF) tool, (ii) optimization techniques such as response surface methodology, and (iii) experimental testing in natural environments. The objective was to develop an efficient system with low manufacturing and maintenance costs. A key finding was that the separation distance between rotors, both along and across the fluid flow, is a critical parameter in designing hydrokinetic arrays. For this study, a triangular array configuration, termed Triframe, was used, consisting of three Gorlov-type turbines with four blades each. The optimization process led to separation distances based on the diameter (D) of the turbines, with 15.9672D along the fluid flow (X) and 4.15719D across the flow (Y). Finally, an experimental scale model of the hydrokinetic array was successfully constructed and characterized, demonstrating the effectiveness of the optimization process described in this study. [ABSTRACT FROM AUTHOR]

Published

2024

12. Addressing the Renewable Energy Challenges through the Lens of Monetary Policy—Insights from the Literature.

Author

Lupu, Iulia, Criste, Adina, Ciumara, Tudor, Milea, Camelia, and Lupu, Radu

Subjects

*LITERATURE reviews, *RENEWABLE energy sources, *ENERGY development, *ENERGY policy, *ENERGY shortages, *CRISIS management

Abstract

This review explores the interplay between renewable energy and monetary policy, highlighting how central banks can contribute to renewable energy development. Although the shift towards renewable energy is tremendous for sustainable development, it also comes with notable economic and financial challenges. Supervenient, the energy transition has raised significant interest among decision-makers and academia, prompting them to explore new innovative policies and strategies; as a result, these actions acknowledged that research in this field is essential for identifying optimal solutions. Moreover, recent global crises, including the energy crisis, have emphasised the important role of macroeconomic policies in crisis management. Within this framework, it's essential to investigate how monetary policy, as the main tool of central banks, can foster renewable energy development. This comprehensive review systematically examines existing literature through a semi-structured literature analysis, which allows for a more flexible, complex, and thorough approach to identifying key issues and providing insights into the potential of monetary policy to address renewable energy challenges. We identified four main clusters of research: sustainability and development, economic growth and energy, monetary policy and investment, and emissions and renewable energy. Furthermore, exploring the interaction between monetary policy and renewable energy objectives to uncover paths for harmonizing monetary strategies with the goals of renewable energy development contributes to highlighting the existing gaps in the field and represents a starting point for further research topics. This study provides a comprehensive overview of the existing knowledge, identifies gaps in the literature, and suggests directions for future research. [ABSTRACT FROM AUTHOR]

Published

2024

13. Magnetic Phase-Change Microcapsules with High Encapsulation Efficiency, Enhancement of Infrared Stealth, and Thermal Stability.

Author

Chang, Chun-Wei, Chen, Zheng-Ting, and Shih, Yeng-Fong

Subjects

*FERROUS oxide, *METHYL methacrylate, *ENERGY shortages, *DIFFERENTIAL scanning calorimetry, *GREENHOUSE effect

Abstract

Due to energy shortages and the greenhouse effect, the efficient use of energy through phase-change materials (PCMs) is gaining increased attention. In this study, magnetic phase-change microcapsules (Mag-mc) were prepared by suspension polymerization. The shell layer of the microcapsules was formed by copolymerizing methyl methacrylate and triethoxyethylene silane, with the latter enhancing the compatibility of the shell layer with the magnetic additive. Ferric ferrous oxide modified by oleic acid (Fe3O4(m)) was added as the magnetic additive. Differential scanning calorimetry (DSC) testing revealed that the content of phase-change materials in microcapsules without and with ferric ferrous oxide were 79.77% and 96.63%, respectively, demonstrating that the addition of Fe3O4(m) improved the encapsulation efficiency and enhanced the energy storage ability of the microcapsules. Laser particle size analysis showed that the overall average particle sizes for the microcapsules without and with ferric ferrous oxide were 3.48 μm and 2.09 μm, respectively, indicating that the incorporation of magnetic materials reduced the size and distribution of the microcapsules. Thermogravimetric analysis indicated that the thermal stability of the microcapsules was enhanced by the addition of Fe3O4(m). Moreover, the infrared emissivity of the microcapsule-containing film decreased from 0.77 to 0.72 with the addition of Fe3O4(m) to the shell of microcapsules. [ABSTRACT FROM AUTHOR]

Published

2024

14. Bi-Level Operation Optimization and Performance Analysis for a Distributed Energy System with Energy Network.

Author

Tan, Yuhua and Yu, Nuo

Subjects

BILEVEL programming, HEAT recovery, GLOBAL optimization, ENERGY development, ENERGY shortages

Abstract

The increasing energy crisis and environmental problems promote the development of distributed energy systems (DESs) that utilize combined heat and power technology, renewable energy technology, and waste heat recovery technology to meet various load requirements. Although there is existing work and research on a variety of DESs, most previous studies tend to focus on energy production with little consideration of a distributed energy network and its energy loss, which results in large errors in energy-efficiency calculations and performance analyses. In this paper, a new DES model is proposed with full consideration of an energy network and the full use of solar energy, terrestrial heat, and exhaust gases. At the same time, an effective bi-level optimization method is also proposed for the daily operation of the DES in order to improve the system performance and benefits in the energy, the economy, and the environment. Specifically, the co-generation energy station and water heating network in the DES are optimized separately with two different optimization models. The first-level optimization model is used to seek the optimal values of water mass flow rate and water temperature of the water heating network, and the second-level optimization model is built to determine the optimal energy purchasing strategy and the optimal energy outputs of the co-generation energy station. In order to verify the advantages and effectiveness of the proposed system and method, a contrastive simulation study is undertaken to provide a comparison of the global optimization method. Simulation results show that energy loss, energy cost, and energy consumption of the DES using the bi-level optimization operation strategy only account for 22.51%, 33.42%, and 51.31% of the quantities of the global optimization method, respectively. The hourly curves of the optimal operating variables also demonstrate that the proposed bi-level optimization method can improve the operating stability of the DES better than the global optimization method. [ABSTRACT FROM AUTHOR]

Published

2024

15. A Numerical Investigation on Kick Control with the Displacement Kill Method during a Well Test in a Deep-Water Gas Reservoir: A Case Study.

Author

Li, Qingchao, Li, Qiang, and Han, Ying

Subjects

ENERGY shortages, GAS wells, PETROLEUM industry, LEAKAGE, FLUIDS, GAS reservoirs

Abstract

The efficient exploitation of marine oil and gas resources holds significant potential to mitigate the current severe energy crisis. Regrettably, incidents, such as gas kick and even blowouts, can significantly impact normal development activities. The displacement kill method is one effective strategy for well control in deep-water areas. In this study, the detailed mathematical method for determining kill parameters involved in the kill operation by using the displacement kill method was proposed. Of course, this includes both cases: one where the kill fluid leaks during the kill process and another where no leakage occurs. Meanwhile, its applicability was verified through comparison with experimental results. Then, evolution characteristics of kill parameters, when killing fluid leakage occurs and when it does not occur, were analyzed. Finally, factors, such as pit gain and shut-in casing pressure, affecting the kill parameters of kill operation, were explored. It was found that the experimental and calculated results show great similarity, although there are slight differences between them. The total kill time in the simulation is 44 s shorter than that in the verification experiment. This indicates that the model established in this study is suitable for simulating the process of kill operation using the displacement kill method. In addition, the investigation results show that leakage of kill fluid increases the difficulty of the kill operation and prolongs the operation time. The number of kill cycles in the presence of kill fluid leakage is one more than that when there is no fluid leakage, resulting in an additional 70 min of total duration. Furthermore, the increase in pit gain and the rise in shut-in casing pressure can also pose challenges to the kill operations. The total kill time will be extended by 164 min when the mud pit gain increases from 20 m3 to 50 m3. The number of kill cycles rises by two when the shut-in casing pressure is increased from 5 MPa to 20 MPa. To ensure the safety of the drilling operation in abnormally high-pressure reservoirs, it is crucial to monitor parameters such as casing pressure during the drilling process and timely well control measures. [ABSTRACT FROM AUTHOR]

Published

2024

16. Experimental Study on the Vibration Characteristics of a Wave-Induced Oscillation Heaving Plate Energy Capture Device.

Author

Lian, Jijian, Wang, Xiaowei, Wang, Xiaoqun, Chen, Yanjia, Liu, Likun, Li, Xin, and Xu, Lingyue

Subjects

CLEAN energy, ENERGY shortages, GLOBAL warming, CARBON emissions, RESEARCH personnel, WAVE energy

Abstract

In order to develop green energy, reduce carbon emissions, and alleviate global warming and the green energy crisis, many researchers focus on wave energy, using a device to convert wave energy into electricity. The three main types of wave energy converters are the overtopping type, the oscillating water column type, and the oscillating body type, and for most of them, the power generation efficiency is low. The research team in this paper proposed a wave energy converter for a wave-induced oscillation heave plate. The plate vibrates up and down under the action of waves, and the captured energy of the vibrating plate transfers the energy to the generator, so as to generate electricity. There is electricity only when there is vibration; therefore, the vibration characteristic of the converter is crucial to power generation. So, the vibration characteristics of the energy capture structure of the converter were studied experimentally. The test results show that the energy harvesting device can vibrate, and the vibration effect is good, which further indicates that the device can generate electricity. The effects of different wave conditions and system stiffnesses on amplitude and corresponding amplitude were studied, and the amplitude increases with the increase in wave height and period and decreases with the increase in system stiffness. The amplitude response decreases with the increase in wave height and system stiffness. Under the test conditions, the maximum amplitude of the system is 6.23 cm (when the wave period is 1.40 s, the wave height is 0.25 m, and the system stiffness is 1735.62 N/m), and the maximum amplitude ratio is 0.34 (when the wave period is 1.1 s, the wave height is 0.10 m, and the system stiffness is 1735.62 N/m). [ABSTRACT FROM AUTHOR]

Published

2024

17. Impact of Energy Crises on Income Inequality: An Application of Piketty's Hypothesis to Pakistan.

Author

Hussain, Jibran, Siyal, Saeed, Ahmad, Riaz, Abbas, Qaiser, Yitian, Yu, and Jin, Liu

Subjects

REAL income, INCOME inequality, ENERGY shortages, ENERGY industries, POWER resources

Abstract

In Pakistan, the majority of people have access to energy supplies. However, people who are underprivileged, below the extreme poverty line, or part of the middle class often spend disproportionate portions of their income on energy supplies and services, to some extent because of higher upfront prices for energy supplies, expensive products, and expensive imported appliances. The nonavailability of low-cost energy supplies is mainly affecting underdeveloped regions that have mostly low-income households. We used the dynamic ordinary least squares method to look at the impact of the energy crisis on income inequality from 1997 to 2021. The results show that the energy crisis exacerbates income inequality as low-income groups end up spending more significant shares of their income on energy products, supplies, and services than higher-income groups. Fair and equal access to energy supplies and services is less likely to reduce income inequality if prices are not cost-efficient. Cautious deliberation regarding the structure of energy tariffs is inevitable; at the same time, safety nets and social security programs for the poorest groups need to be expanded. At this stage, the aim is to target energy prices that will achieve the objectives of reducing polarity and increasing real income. [ABSTRACT FROM AUTHOR]

Published

2024

18. Cost of Green Hydrogen.

Author

Kotowicz, Janusz, Baszczeńska, Oliwia, and Niesporek, Kamil

Subjects

*GREEN fuels, *MONTE Carlo method, *ENERGY shortages, *VARIABLE costs, PARIS Agreement (2016)

Abstract

Acting in accordance with the requirements of the 2015 Paris Agreement, Poland, as well as other European Union countries, have committed to achieving climate neutrality by 2050. One of the solutions to reduce emissions of harmful substances into the environment is the implementation of large-scale hydrogen technologies. This article presents the cost of producing green hydrogen produced using an alkaline electrolyzer, with electricity supplied from a photovoltaic farm. The analysis was performed using the Monte Carlo method, and for baseline assumptions including an electricity price of 0.053 EUR/kWh, the cost of producing green hydrogen was 5.321 EUR/kgH2. In addition, this article presents a sensitivity analysis showing the impact of the electricity price before and after the energy crisis and other variables on the cost of green hydrogen production. The large change occurring in electricity prices (from 0.035 EUR/kWh to 0.24 EUR/kWh) significantly affected the levelized cost of green hydrogen (LCOH), which could change by up to 14 EUR/kgH2 in recent years. The results of the analysis showed that the parameters that successively have the greatest impact on the cost of green hydrogen production are the operating time of the plant and the unit capital expenditure. The development of green hydrogen production facilities, along with the scaling of technology in the future, can reduce the cost of its production. [ABSTRACT FROM AUTHOR]

Published

2024

19. Semi-Empirical Model Based on the Influence of Turbulence Intensity on the Wake of Vertical Axis Turbines.

Author

Wang, Ziyao, Hou, Erhu, and Wu, He

Subjects

*HYDRAULIC turbines, *ENERGY development, *OCEAN turbulence, *TIDAL currents, *ENERGY shortages

Abstract

In the context of energy shortages and the development of new energy sources, tidal current energy has emerged as a promising alternative. It is typically harnessed by deploying arrays of multiple water turbines offshore. Vertical axis water turbines (VAWTs), as key units in these arrays, have wake effects that influence array spacing and energy efficiency. However, existing studies on wake velocity distribution models for VAWTs are limited in number, accuracy, and consideration of influencing factors. A precise theoretical model (Lam's formula) for wake lateral velocity can better predict wake decay, aiding in the optimization of tidal current energy array designs. Turbulence in the ocean, serving as a medium for energy exchange between high-energy and low-energy water flows, significantly impacts the wake recovery of water turbines. To simplify the problem, this study uses software ANSYS Fluent 2020 R2 for two-dimensional simulations of VAWT wake decay under different turbulence intensities, confirming the critical role of turbulence intensity in wake velocity decay. Based on the obtained data, a new mathematical approach was employed to incorporate turbulence intensity into Lam's wake formula for VAWTs, improving its predictive accuracy with a minimum error of 1%, and refining some parameter calculations. The results show that this model effectively reflects the impact of turbulence on VAWT wake recovery and can be used to predict wake decay under various turbulence conditions, providing a theoretical basis for VAWT design, optimization, and array layout. [ABSTRACT FROM AUTHOR]

Published

2024

20. Internet of Things-Based Multi-Agent System for the Control of Smart Street Lighting.

Author

Kouah, Sofia, Saighi, Asma, Ammi, Maryem, Naït Si Mohand, Aymen, Kouah, Marwa Ines, and Megías, David

Subjects

STREET lighting, ARTIFICIAL intelligence, MULTIAGENT systems, LIGHT pollution, ENERGY shortages

Abstract

The Internet of Things refers to a network of interconnected devices, objects, and systems, that can interact with one another without human intervention. The adoption of IoT technology has expanded rapidly, significantly impacting various fields, including smart healthcare, intelligent transportation, agriculture, and smart homes. This paper focuses on smart street lighting, which represents the core piece of the smart city and the key public service for citizens' safety. Nevertheless, it poses substantial challenges related to energy consumption, especially during energy crises. This work aims to provide an advanced solution that enables intelligent control of street lighting, enhances human safety, reduces CO2 emissions and light pollution, and optimizes energy consumption, as well as facilitates maintenance of the lighting network. The solution is twofold: First, it introduces IoT-based smart street lighting referential models; second, it presents a framework for controlling smart street lighting based on the referential models. The proposal uses an IoT-based fuzzy multi-agent systems approach to address the challenges of smart street lighting. The approach leverages the strengths and properties of fuzzy logic and multi-agent systems to address the system requirements. This is illustrated through a testbed case study conducted on a concrete IoT prototype. [ABSTRACT FROM AUTHOR]

Published

2024

21. HumanEnerg Hotspot: Conceptual Design of an Agile Toolkit for Human Energy Reinforcement in Industry 5.0.

Author

Onyemelukwe, Ifeoma Chukwunonso, Ferreira, José Antonio Vasconcelos, Ramos, Ana Luísa, and Direito, Inês

Subjects

ENERGY shortages, DESIGN science, CONCEPTUAL design, ENERGY industries, LABOR supply

Abstract

This paper presents the conceptual design of the HumanEnerg Hotspot, an agile toolkit aimed at addressing the human energy crisis in the context of Industry 5.0. The toolkit has been developed using a blend of Design Science Research (DSR) and Human-Centered Design (HCD) methodologies, enabling a comprehensive human-centered problem identification and solution-seeking approach. The toolkit includes a variety of strategies, techniques, frameworks, and resource recommendations for industry use and has been designed to be easily adaptable for use in diverse industry settings. The toolkit is intended to support the European Union's goal for industry to influence society through a human-centric approach to Industry 5.0 by prioritizing human energy reinforcement and creating a more resilient and productive workforce. The toolkit provides a valuable resource for employees and managers alike and offers a promising solution for addressing the human energy crisis in the era of Industry 5.0. [ABSTRACT FROM AUTHOR]

Published

2024

22. Spartina alterniflora -Derived Carbons for High-Performance Oxygen Reduction Reaction (ORR) Catalysts.

Author

Hao, Xinmeng, Zhou, Yougui, Guo, Lihua, Li, Huipeng, Shang, Hong, and Liu, Xuanhe

Subjects

*SPARTINA alterniflora, *CARBON-based materials, *OXYGEN reduction, *BIOMASS energy, *ENERGY shortages, *MELAMINE

Abstract

Being an alien species, Spartina alterniflora has occupied the living space of native animals and plants, causing irreversible damage to the environment. Converting Spartina alterniflora into carbon or its derivatives offers a valuable solution to manage both invasive biomass and an energy shortage. Herein, through a simple activation process, we successfully prepared Spartina alterniflora-derived carbon (SAC) and its N-doped derivative SANC, and used them as metal-free catalysts for an oxygen reduction reaction (ORR). SAC exhibits good electrochemical performance and holds significant potential in catalysis. After N-doping by melamine as a nitrogen source, electronegativity is redistributed in SANC, leading to enhanced performance (a half-wave potential of 0.716 V vs. RHE, and a four-electron transfer pathway with a H2O2 yield of only 2.05%). This work presents a straightforward and cost-effective approach to the usage of obsolete invasive biomass and shows great potential in energy generation. [ABSTRACT FROM AUTHOR]

Published

2024

23. Exploring the Dynamics of Charge Transfer in Photocatalysis: Applications of Femtosecond Transient Absorption Spectroscopy.

Author

Li, Na, Ma, Yanlong, and Sun, Wanjun

Subjects

*CHARGE transfer, *CHARGE exchange, *ENERGY shortages, *SOLAR energy, *PHOTOCATALYSTS, *PHOTOCATALYSIS

Abstract

Artificial photocatalytic energy conversion is a very interesting strategy to solve energy crises and environmental problems by directly collecting solar energy, but low photocatalytic conversion efficiency is a bottleneck that restricts the practical application of photocatalytic reactions. The key issue is that the photo-generated charge separation process spans a huge spatio-temporal scale from femtoseconds to seconds, and involves complex physical processes from microscopic atoms to macroscopic materials. Femtosecond transient absorption (fs-TA) spectroscopy is a powerful tool for studying electron transfer paths in photogenerated carrier dynamics of photocatalysts. By extracting the attenuation characteristics of the spectra, the quenching path and lifetimes of carriers can be simulated on femtosecond and picosecond time scales. This paper introduces the principle of transient absorption, typical dynamic processes and the application of femtosecond transient absorption spectroscopy in photocatalysis, and summarizes the bottlenecks faced by ultrafast spectroscopy in photocatalytic applications, as well as future research directions and solutions. This will provide inspiration for understanding the charge transfer mechanism of photocatalytic processes. [ABSTRACT FROM AUTHOR]

Published

2024

24. Exploring the Dynamic Behavior of Crude Oil Prices in Times of Crisis: Quantifying the Aftershock Sequence of the COVID-19 Pandemic.

Author

Siokis, Fotios M.

Subjects

*COVID-19 pandemic, *PETROLEUM sales & prices, *STOCK price indexes, *ABSOLUTE value, *ENERGY shortages

Abstract

Crude oil prices crashed and dropped into negative territory at the onset of the COVID-19 pandemic. This extreme event triggered a series of great-magnitude aftershocks. We seek to investigate the cascading dynamics and the characteristics of the series immediately following the oil market crash. Utilizing a robust method named the Omori law, we quantify the correlations of these events. This research presents empirical regularity concerning the number of times that the absolute value of the percentage change in the oil index exceeds a given threshold value. During the COVID-19 crisis, the West Texas Intermediate (WTI) oil prices exhibit greater volatility compared to the Brent oil prices, with higher relaxation values at all threshold levels. This indicates that larger aftershocks decay more rapidly, and the period of turbulence for the WTI is shorter than that of Brent and the stock market indices. We also demonstrate that the power law's exponent value increases with the threshold value's magnitude. By proposing this alternative method of modeling extreme events, we add to the current body of literature, and the findings demonstrate its practical use for decision-making authorities—particularly financial traders who model high-volatility products like derivatives. [ABSTRACT FROM AUTHOR]

Published

2024

25. An Empirical Investigation on the Visual Imagery of Augmented Reality User Interfaces for Smart Electric Vehicles Based on Kansei Engineering and FAHP-GRA.

Author

Lin, Jin-Long and Zheng, Meng-Cong

Subjects

*GREY relational analysis, *SCIENTIFIC method, *AUGMENTED reality, *USER interfaces, *ENERGY shortages

Abstract

Smart electric vehicles (SEVs) hold significant potential in alleviating the energy crisis and environmental pollution. The augmented reality (AR) dashboard, a key feature of SEVs, is attracting considerable attention due to its ability to enhance driving safety and user experience through real-time, intuitive driving information. This study innovatively integrates Kansei engineering, factor analysis, fuzzy systems theory, analytic hierarchy process, grey relational analysis, and factorial experimentation to evaluate AR dashboards' visual imagery and subjective preferences. The findings reveal that designs featuring blue planar and unconventional-shaped dials exhibit the best performance in terms of visual imagery. Subsequent factorial experiments confirmed these results, showing that drivers most favor blue-dominant designs. Furthermore, in unconventional-shaped dial designs, the visual effect of vertical 3D is more popular with drivers than horizontal 3D, while the opposite is true in round dials. This study provides a scientific evaluation method for assessing the emotional experience of AR dashboard interfaces. Additionally, these findings will help reduce the subjectivity in interface design and enhance the overall competitiveness of SEV vehicles. [ABSTRACT FROM AUTHOR]

Published

2024

26. Projections for the 2050 Scenario of the Mexican Electrical System.

Author

Toledo-Vázquez, Diocelina, Romero, Rosenberg J., Hernández-Luna, Gabriela, Cerezo, Jesús, and Montiel-González, Moisés

Subjects

*ELECTRIC power consumption, *ENERGY shortages, *ENERGY industries, *COVID-19 pandemic, *MODERN society

Abstract

Electricity is fundamental to modern societies and will become even more so as its use expands through different technologies and population growth. Power generation is currently the largest source of carbon-dioxide (CO2) emissions globally, but it is also the sector that is leading the transition to net zero emissions through the rapid rise of renewables. The impacts of COVID-19 on the electricity sector led to a reduction in the demand for electricity, while at the same time, the current global energy crisis has placed the security and affordability of electricity at the top of the political agenda in many countries. In this way, the decrease in the demand for electricity, as well as its gradual recovery, makes it necessary to carry out energy planning that considers the adverse effects caused by global events with a high socioeconomic impact. In this article, the Low Emission Analysis Platform (LEAP) 2020 software has been used to determine the distribution of energy sources to 2050 for Mexico. The variables that lead to the possible profiles for 2050 are social, economic, and technological. The results correspond to a possible future based on official data from the National Electric System (SEN) of Mexico. The forecast for 2050 indicates that the electricity sector will have almost double the current installed capacity; however, emissions do not correspond to twice as much: they are practically 50% higher. [ABSTRACT FROM AUTHOR]

Published

2024

27. A GIS-Based Approach for Urban Building Energy Modeling under Climate Change with High Spatial and Temporal Resolution.

Author

Chen, Liang, Zheng, Yuanfan, Yu, Jia, Peng, Yuanhang, Li, Ruipeng, and Han, Shilingyun

Subjects

*ENERGY consumption of buildings, *CLIMATE change models, *ENERGY consumption, *ENERGY shortages, *POWER resources

Abstract

The energy demand and associated greenhouse gas (GHG) emissions of buildings are significantly affected by the characteristics of the building and local climate conditions. While energy use datasets with high spatial and temporal resolution are highly needed in the context of climate change, energy use monitoring data are not available for most cities. This study introduces an approach combining building energy simulation, climate change modeling, and GIS spatial analysis techniques to develop an energy demand data inventory enabling assessment of the impacts of climate change on building energy consumption in Shanghai, China. Our results suggest that all types of buildings exhibit a net increase in their annual energy demand under the projected future (2050) climate conditions, with the highest increase in energy demand attributed to Heating, Ventilation, and Cooling (HVAC) systems. Variations in building energy demand are found across building types. Due to the large number of residential buildings, they are the main contributor to the increases in energy demand and associated CO2 emissions. The hourly residential building energy demand on a typical hot summer day (29 July) under the 2050 climate condition at 1 p.m. is found to increase by more than 40%, indicating a risk of energy supply shortage if no actions are taken. The spatial pattern of total annual building energy demand at the individual building level exhibited high spatial heterogeneity with some hotspots. This study provides an alternative method to develop a building energy demand inventory with high temporal resolution at the individual building scale for cities lacking energy use monitoring data, supporting the assessment of building energy and GHG emissions under both current and future climate scenarios at minimal cost. [ABSTRACT FROM AUTHOR]

Published

2024

28. Towpreg—An Advanced Composite Material with a Potential for Pressurized Hydrogen Storage Vessels.

Author

Trajkovska Petkoska, Anka, Samakoski, Blagoja, Samardjioska Azmanoska, Bisera, and Velkovska, Viktorija

Subjects

FILAMENT winding, MATERIALS science, HYDROGEN storage, CLIMATE change, ENERGY shortages

Abstract

Hydrogen is one of the critical components to address global challenges such as climate change, environmental pollution and global warming. It is a renewable source of energy that has many advantages compared to other renewables. Even though it may not be a "silver bullet" solution for the polluted world, there is still a big expectation that it can solve some of the energy crisis and challenges in the transportation, domestic and industry sectors. This study reviews the latest advancements in materials science, especially in the composite materials used for energy storage/transportation tanks. Special attention is given to towpreg material structures as the most promising ones for hydrogen storage. Various types of storage vessels are reviewed with emphasis on the most advanced type IV and type V vessels for energy (hydrogen) storage. The manufacturing processes, mainly filament winding (FW) and automatic fiber placement (AFP), are reviewed with their pros and cons. The sustainability aspects for the most promising hydrogen technologies, limitations and future challenges are also discussed. [ABSTRACT FROM AUTHOR]

Published

2024

29. Identifying Locations for Early Adoption of Zero Emission Fuels for Shipping—The UK as a Case Study.

Author

Baresic, Domagoj, Rehmatulla, Nishatabbas, and Smith, Tristan

Subjects

HYDROGEN as fuel, DOCUMENTARY evidence, ALTERNATIVE fuels, ENERGY shortages, ENERGY security

Abstract

The United Kingdom (UK) shipping industry is facing calls to set out more robust decarbonisation plans. In light of the economic challenges facing the country, including the cost-of-living crisis and energy security considerations, the UK government has outlined plans to spearhead several 'green' developments. It is of paramount importance to understand how best to integrate the domestic maritime sector into this process by promoting the adoption of low-carbon marine fuels such as hydrogen and ammonia. However, there is a limited understanding of what are the most suitable locations for the early adoption of such fuels in the UK. The sustainability transitions literature offers interesting insights into how marine fuel transitions can unfold, by combining the study of market factors with various non-market socio-technical forces. Previous academic work has shown the importance of location and proximity in facilitating alternative marine fuel transitions. This paper builds onto that work by applying a socio-technical transitions framework to develop a set of indicators to ascertain the suitability of potential locations for the early adoption of hydrogen and ammonia as marine fuels in the UK. This paper explores these dynamics by combining evidence from documentary sources, a UK ship voyages database, and interviews with key stakeholders. Furthermore, three specific case studies are analysed in detail to outline key drivers for the adoption of hydrogen and ammonia. The findings show that there is a significant difference across the UK in regional viability for the early adoption of hydrogen and ammonia, with some of the best suited sites being in the north of Scotland (Orkney), south of England (the Solent-Isle of Wight), and east of England (Felixstowe-Harwich). [ABSTRACT FROM AUTHOR]

Published

2024

30. Ferroelectric/Piezoelectric Materials in Energy Harvesting: Physical Properties and Current Status of Applications.

Author

Karageorgou, Maria-Argyro, Tsakmakidis, Kosmas, and Stamopoulos, Dimosthenis

Subjects

MORPHOTROPIC phase boundaries, PIEZOELECTRIC materials, CLEAN energy, PIEZOELECTRICITY, ENERGY shortages

Abstract

The inevitable feedback between the environmental and energy crisis within the next decades can probably trigger and/or promote a global imbalance in both financial and public health terms. To handle this difficult situation, in the last decades, many different classes of materials have been recruited to assist in the management, production, and storage of so-called clean energy. Probably, ferromagnets, superconductors and ferroelectric/piezoelectric materials stand at the frontline of applications that relate to clean energy. For instance, ferromagnets are usually employed in wind turbines, superconductors are commonly used in storage facilities and ferroelectric/piezoelectric materials are employed for the harvesting of stray energy from the ambient environment. In this work, we focus on the wide family of ferroelectric/piezoelectric materials, reviewing their physical properties in close connection to their application in the field of clean energy. Among other compounds, we focus on the archetypal compound Pb(Zr,Ti)O3 (or PZT), which is well studied and thus preferred for its reliable performance in applications. Also, we pay special attention to the advanced ferroelectric relaxor compound (1−x)Pb(Mg1/3Nb2/3)O3−xPbTiO3 (or PMN-xPT) due to its superior performance. The inhomogeneous composition that many kinds of such materials exhibit at the so-called morphotropic phase boundary is reviewed in connection to possible advantages that it may bring when applications are considered. [ABSTRACT FROM AUTHOR]

Published

2024

31. Diagnosing Energy Poverty in Portugal through the Lens of a Social Survey.

Author

Moura, Pedro, Fonseca, Paula, Cunha, Inês, and Morais, Nuno

Subjects

*INCOME, *QUALITY of life, *ENERGY shortages, *SOCIOECONOMIC factors, *ENERGY industries

Abstract

Energy poverty (EP) is a crucial socio-economic problem in current society, as it deprives people of a basic standard of living and quality of life. In general, EP is linked to various factors, but it is primarily associated with high energy costs, low household income, and inefficient building structures. Due to the recent energy crisis in Europe, the importance of these factors has escalated. Bearing in mind the above remarks, the REVERTER EU-funded LIFE project will develop and test nine roadmaps in four European countries (Brezovo—Bulgaria; Athens Urban area—Greece; Riga—Latvia; and Coimbra—Portugal) to alleviate EP by addressing the poor energy efficiency of dwellings. To directly observe real-life scenarios in designated pilot regions, questionnaire surveys were conducted, involving approximately 300 households in each pilot area. This paper presents and evaluates the outcomes of the survey conducted in the central region of Portugal. The findings allow for a deeper comprehension of the factors that impact energy poverty in Portugal, spanning socio-economic aspects, housing characteristics, mechanical systems, energy expenses, and behaviors, as well as the awareness of available support initiatives. Drawing from the survey's insights, novel strategies are suggested to alleviate energy poverty, with a primary emphasis on crafting tailored, efficient policies that address the genuine requirements of households and individuals. [ABSTRACT FROM AUTHOR]

Published

2024

32. Assessment of Single-Axis Solar Tracking System Efficiency in Equatorial Regions: A Case Study of Manta, Ecuador.

Author

Ponce-Jara, Marcos A., Pazmino, Ivan, Moreira-Espinoza, Ángelo, Gunsha-Morales, Alfonso, and Rus-Casas, Catalina

Subjects

*SUSTAINABILITY, *CLEAN energy, *ENERGY shortages, *STEPPING motors, *PHOTOVOLTAIC power systems

Abstract

Ecuador is grappling with a severe energy crisis, marked by frequent power outages. A recent study explored solar energy efficiency in the coastal city of Manta using an IoT real-time monitoring system to compare static photovoltaic (PV) systems with two single-axis solar tracking systems: one based on astronomical programming and the other using light-dependent resistor (LDR) sensors. Results showed that both tracking systems outperformed the static PV system, with net gains of 31.8% and 37.0%, respectively. The astronomical-programming-based system had a slight edge, operating its stepper motor intermittently for two minutes per hour, while the LDR system required continuous motor energization. The single-axis tracker using astronomical programming demonstrated notable advantages in energy efficiency and complexity, making it suitable for equatorial regions like Manta. The study also suggested potential further gains by adjusting solar positioning at shorter intervals, such as every 15 or 30 min. These findings enhance our understanding of solar tracking performance in equatorial environments, offering valuable insights for optimizing solar energy systems in regions with high solar radiation. By emphasizing customized solar tracking mechanisms, this research presents promising solutions to Ecuador's energy crisis and advances sustainable energy practices. [ABSTRACT FROM AUTHOR]

Published

2024

33. Navigating the Greek Energy Crisis through a Multidimensional Approach: A Review Article.

Author

Panagiotopoulos, Panagiotis P. and Roukanas, Spyros A.

Subjects

*RUSSIAN invasion of Ukraine, 2022-, *ENERGY shortages, *ECONOMIC impact of disease, *ENERGY consumption, *GREENHOUSE gases, *NATURAL gas

Abstract

Following the required adjustments made by the European Union (EU) to adequately absorb the negative social and economic impacts of the COVID-19 pandemic, the EU is once again confronting a crisis. The extended fiscal instability and environmental imbalance resulting from the energy crisis, primarily caused by rising energy prices owing to geopolitical upheavals (the Russian invasion in Ukraine), have been compounded by rising inflation. The main research objective of this paper is the analysis and evaluation of the effects of the current energy crisis on the Greek economy through the perspective of energy poverty, energy dependence, and climate change. Greece has been negatively impacted by the significant rise in energy costs. In 2022, the percentage of the general population that faced difficulties in paying energy bills exceeded the European average, reaching the level of 34.1%, while almost 19% of the population could not keep their homes sufficiently warm. Additionally, in 2022, Greece was one of the countries most energy-dependent on Russia. Greece achieved most of its targets regarding climate change, with the most representative example being the reduction of GHG emissions by 42% from 2000 to 2022. However, this reduction did not come from the successful green transformation of the Greek economy, but instead was due to the reduction in overall energy consumption that came from the prolonged economic crisis, combined with the restrictions of the COVID-19 pandemic. Nevertheless, the majority of Greek buildings are still not considered to be energy efficient, while the transportation industry continues to rely heavily on oil, coal, and natural gas. [ABSTRACT FROM AUTHOR]

Published

2024

34. Applications of Ni-Based Catalysts in Photothermal CO 2 Hydrogenation Reaction.

Author

Yuan, Zhimin, Sun, Xianhui, Wang, Haiquan, Zhao, Xingling, and Jiang, Zaiyong

Subjects

*CATALYTIC hydrogenation, *CATALYTIC activity, *ENERGY shortages, *GLOBAL warming, *GREENHOUSE gas mitigation

Abstract

Heterogeneous CO2 hydrogenation catalytic reactions, as the strategies for CO2 emission reduction and green carbon resource recycling, play important roles in alleviating global warming and energy shortages. Among these strategies, photothermal CO2 hydrogenation technology has become one of the hot catalytic technologies by virtue of the synergistic advantages of thermal catalysis and photocatalysis. And it has attracted more and more researchers' attentions. Various kinds of effective photothermal catalysts have been gradually discovered, and nickel-based catalysts have been widely studied for their advantages of low cost, high catalytic activity, abundant reserves and thermal stability. In this review, the applications of nickel-based catalysts in photothermal CO2 hydrogenation are summarized. Finally, through a good understanding of the above applications, future modification strategies and design directions of nickel-based catalysts for improving their photothermal CO2 hydrogenation activities are proposed. [ABSTRACT FROM AUTHOR]

Published

2024

35. Trends and Challenges after the Impact of COVID-19 and the Energy Crisis on Financial Markets.

Author

Basdekis, Charalampos, Christopoulos, Apostolos G., Katsampoxakis, Ioannis, and Xanthopoulos, Stylianos

Subjects

*COVID-19 pandemic, *RUSSIAN invasion of Ukraine, 2022-, *FINANCIAL crises, *RENEWABLE energy transition (Government policy), *ENERGY shortages, *CORPORATE sustainability

Abstract

This review aims to examine the impact of increasing energy costs on the global economy, social cohesion, economic growth, and capital markets, with a particular focus on the consequences of the COVID-19 pandemic and the energy crisis intensified by the war in Ukraine. The methodology involves an extensive review of recent academic literature to cast light on these impacts. The study identifies significant disruptions in supply chains and heightened volatility in international capital markets due to these crises. Furthermore, the findings highlight the resulting challenges for policymakers, academics, market analysts, and professionals in addressing corporate sustainability in an increasingly uncertain environment. This paper underscores the continued relevance of energy issues as a central concern, both independently and in connection with broader economic sectors. Additionally, it discusses the importance of policy measures to enhance energy security and the transition towards sustainable energy solutions to mitigate these challenges and foster economic resilience. [ABSTRACT FROM AUTHOR]

Published

2024

36. Advancement of Bioenergy Technology in South Africa.

Author

Obileke, KeChrist, Mukumba, Patrick, and Lesala, Mahali Elizabeth

Subjects

*RENEWABLE energy sources, *POWER resources, *ENVIRONMENTAL health, *BIOMASS energy, *ENERGY shortages

Abstract

South Africa has been experiencing an energy crisis since 2007 and continues to the present. This has resulted in load-shedding (action to interrupt electricity supply to avoid excessive load on the generating plant). One way to address this problem is to further explore the potential and contribution of bioenergy through research conducted and implementing energy reports. Therefore, the study aims to provide the state of bioenergy and its contribution to the country's economic sector and to enhance the replacement of fossil fuels with bioenergy resources and technology. A total blackout of 15,913 h has been experienced since 2014, according to the weekly system status report released by ESKOM. The power utility (Eskom) responsible for power generation and utility has attributed this problem to insufficient generation and capacity. Based on this, the country is embarking on solving this problem. Although the country is dominated by coal (fossil fuel), constituting 73.8% of the total energy supply, this poses a serious environmental risk and health hazard. Renewable energy is considered an alternative energy source, and its introduction and implementation look promising in reducing and solving the current energy crisis. With abundant renewable energy potential, representing 8.7% of the total energy supply, around 85% is bioenergy. This review's findings revealed that bioenergy contributed mainly towards heat, and fuels admit other energy sources, which is recommended. Therefore, its deployment on a large scale is promising and possible. This study will guide and further encourage the deployment of bioenergy projects in South Africa. [ABSTRACT FROM AUTHOR]

Published

2024

37. Development of Energy Poverty and Its Solutions through the Use of Renewables: The EU Case with a Focus on Slovakia.

Author

Taušová, Marcela, Domaracká, Lucia, Čulková, Katarína, Tauš, Peter, and Kaňuch, Pavol

Subjects

*RENEWABLE energy sources, *ENERGY development, *ENERGY shortages, *ENERGY consumption, *ENERGY industries

Abstract

The problem of energy poverty (EP), when energy becomes unaffordable for some population groups, is not only a problem for developing countries, but this phenomenon is appearing more and more often in European countries. In Europe, it is estimated that 50 to 125 million people are living in energy poverty. We hear more and more about energy poverty in connection with the current energy crisis and rising energy prices, but also because of insufficient renewable use. Due to increasing energy prices, we are increasingly hearing about the deepening energy poverty in Slovakia. This study aims to evaluate the development of energy poverty in Slovakia compared to other EU countries. The situation is studied from the view of the number of heating and cooling days, the percentage of the population that cannot maintain adequate heat at home, the percentage of the population that lacks heat, and the percentage of residents without enough heat. During the research, we used distribution analysis, trend analysis, analysis of variance, and one-way analysis. The main results show that the heating degree days (HDD) index recorded a decrease, the cooling degree days (CDD) index recorded an increase, and energy poverty is most obvious in a low-income group of inhabitants, having shortage of heat, when renewable energy sources (RES) use contributes to the mitigation of energy poverty. Solving the unfavorable situation of energy poverty is possible by increasing the share of renewables used in the gross final energy consumption for heating and cooling, primarily in residential buildings. The results provide information for policymakers regarding the triple bottom line approach (people, planet, and profit). [ABSTRACT FROM AUTHOR]

Published

2024

38. Fundamental Barriers to Green Energy Production in Selected EU Countries.

Author

Wardal, Witold Jan, Mazur, Kamila, Barwicki, Jan, and Tseyko, Mikhail

Subjects

*ENERGY conservation, *ENERGY development, *RENEWABLE energy sources, *ENERGY consumption, *ENERGY shortages

Abstract

Most EU countries are trying to develop new sources of energy to meet local power requirements due to energy shortages. The most popular renewable energy developments include biogas stations, wind turbines, water turbines, and solar systems. This article focuses on reviewing studies concerning the utilization of solar energy systems, especially photovoltaic (PV) ones, in European countries such as Germany, Italy, Spain, and Poland, which are leaders in PV installations. The review identifies factors influencing the development of PV investments and the energy situation in these countries. Economic, market, environmental, and infrastructural barriers, as well as driving factors, are presented. In all countries, the majority of installations were in the prosumer sector, with only a very small percentage in the state-owned sector. The methodology of the study covered the mentioned barriers, which were identified using scientific databases such as Scopus, Web of Science, and branch organizations websites like the International Renewable Energy Agency (IRENA). The novelty of the article lies in its examination of special barriers concerning green energy production in chosen EU countries. Normally, when reading articles on PV installations, as presented in the References section, one primarily observes a description of the construction process without deep involvement in the presented ideas. [ABSTRACT FROM AUTHOR]

Published

2024

39. Thermal Exfoliation and Phosphorus Doping in Graphitic Carbon Nitride for Efficient Photocatalytic Hydrogen Production.

Author

Chen, Lu, Zhang, Linzhu, Xia, Yuzhou, Huang, Renkun, Liang, Ruowen, Yan, Guiyang, and Wang, Xuxu

Subjects

*CARBON-based materials, *ELECTRON diffusion, *DOPING agents (Chemistry), *ENERGY shortages, *VISIBLE spectra

Abstract

Photocatalytic H2 evolution has been regarded as a promising technology to alleviate the energy crisis. Designing graphitic carbon nitride materials with a large surface area, short diffusion paths for electrons, and more exposed reactive sites are beneficial for hydrogen evolution. In this study, a facile method was proposed to dope P into a graphitic carbon nitride framework by calcining melamine with 2-aminoethylphosphonic acid. Meanwhile, PCN nanosheets (PCNSs) were obtained through a thermal exfoliation strategy. Under visible light, the PCNS sample displayed a hydrogen evolution rate of 700 μmol·g−1·h−1, which was 43.8-fold higher than that of pure g-C3N4. In addition, the PCNS photocatalyst also displayed good photostability for four consecutive cycles, with a total reaction time of 12 h. Its outstanding photocatalytic performance was attributed to the higher surface area exposing more reactive sites and the enlarged band edge for photoreduction potentials. This work provides a facile strategy to regulate catalytic structures, which may attract great research interest in the field of catalysis. [ABSTRACT FROM AUTHOR]

Published

2024

40. Catalyst Development for Biogas Dry Reforming: A Review of Recent Progress.

Author

Hu, Wei, Wu, Jundao, Huang, Zeai, Tan, Hao, Tang, Yifan, Feng, Zilong, Deng, Rui, Zhang, Hongwei, Zairov, Rustem, and Pan, Zhicheng

Subjects

*RENEWABLE energy sources, *ENERGY consumption, *METAL catalysts, *ENERGY shortages, *CATALYTIC activity, *BIOGAS

Abstract

Amidst the rapid expansion of the global economy, the demand for energy has escalated. The depletion of traditional energy sources coupled with environmental pollution concerns has catalyzed a shift towards the development and utilization of clean, renewable energy. Biogas, as a renewable energy source, provides diverse applications and holds the potential to alleviate energy shortages. Recently, biogas dry reforming technology has garnered substantial attention as a significant pathway for renewable energy utilization, particularly in the development and optimization of catalysts. Contemporary research predominantly focuses on enhancing the activity and stability of catalysts, with particular emphasis on their resistance to coking and sintering. This review delineates the classification of biogas dry reforming catalysts, their catalytic activity, and issues related to carbon deposition, contrasting biogas dry reforming with traditional dry reforming in catalyst design. It synthesizes numerous studies from recent years aimed at mitigating carbon deposition during the biogas dry reforming process and boosting catalytic activity via active components, carriers, and promoters in both precious and non-precious metal catalysts. Furthermore, it discusses the current challenges of biogas dry reforming technology and outlines prospective future development trends. This discussion provides an in-depth understanding of biogas dry reforming technology and catalyst design, offering insights and recommendations for future research and industrial applications. [ABSTRACT FROM AUTHOR]

Published

2024

41. Realized Volatility Spillover Connectedness among the Leading European Currencies after the End of the Sovereign-Debt Crisis: A QVAR Approach.

Author

Nerantzidis, Michail, Stoupos, Nikolaos, and Tzeremes, Panayiotis

Subjects

HUNGARIAN forint, POUND sterling, SWISS franc, ENERGY shortages, MARKET volatility, EUROPEAN Sovereign Debt Crisis, 2009-2018

Abstract

This paper examines the time-varying spillover effects and connectedness between the euro and other EU and non-EU currencies after the end of the sovereign-debt crisis. We employ the Quantile Vector Autoregression connectedness approach using intraday data for seven currencies (the euro, the British pound, the Swiss franc, the Polish zloty, the Hungarian forint, the Czech koruna, and the Norwegian krone) spanning from 1 January 2016 to 30 November 2022. The results indicate that, almost in all quantiles, the currencies of Eastern European Group countries (i.e., Czech Republic, Hungary, and Poland) are net contributors of information spillovers to other currencies, while currencies of non-EU countries (Switzerland, UK, and Norway) are net takers. Further, we find that the euro is the highest transmitter of net information spillovers to all other currencies until 2021. Interestingly, after 2021, the euro changes to net information spillover taker from all other currencies; highlighting that external shocks (e.g., COVID-19, the energy crisis) have significant risk spillover effects on the European currency market. Policymakers and market participants could benefit from knowing which currency drives developments to avoid unexpected consequences. [ABSTRACT FROM AUTHOR]

Published

2024

42. Electrocatalytic Nanomaterials Improve Microbial Extracellular Electron Transfer: A Review.

Author

Wang, Xiaopin, Li, Xu, and Zhu, Qisu

Subjects

CHARGE exchange, ENERGY shortages, PRECIOUS metals, RESOURCE exploitation, ELECTROCATALYSIS, TRANSITION metal oxides

Abstract

Microbial electrochemical systems that integrate the advantages of inorganic electrocatalysis and microbial catalysis are expected to provide sustainable solutions to the increasing energy shortages, resource depletion, and climate degradation. However, sluggish extracellular electron transfer (EET) at the interface between electroactive microorganisms and inorganic electrode materials is a critical bottleneck that limits the performance of systems. Electrocatalytic nanomaterials are highly competitive in overcoming this obstacle due to their effective association with microbial catalysis. Therefore, this review focuses on the cutting-edge applications and enhancement mechanisms of nanomaterials with electrocatalytic activity in promoting microbial EET. First, the EET mechanism of microbial electrocatalysis in both microbial anodes and cathodes is briefly introduced, and then recent applications of various electrocatalytic nanomaterials in diverse microbial electrochemical systems are summarized, including heteroatom-doped carbons and precious metal, as well as transition metal oxides, sulfides, carbides, and nitrides. The synergistic effects of nanomaterial electrocatalysis and microbial catalysis on enhancing interfacial EET are analyzed. Finally, the challenges and perspectives of realizing high-performance microbial electrochemical systems are also discussed in order to offer some reference for further research. [ABSTRACT FROM AUTHOR]

Published

2024

43. Enhancing Efficiency in Hybrid Marine Vessels through a Multi-Layer Optimization Energy Management System.

Author

Truong, Hoai Vu Anh, Do, Tri Cuong, and Dang, Tri Dung

Subjects

PROTON exchange membrane fuel cells, ENERGY management, INDUSTRIAL efficiency, ENERGY shortages, POWER transmission

Abstract

Configuring green power transmissions for heavy-industry marines is treated as a crucial request in an era of global energy and pollution crises. Following up on this hotspot trend, this paper examines the effectiveness of a modified optimization-based energy management strategy (OpEMS) for a dual proton exchange membrane fuel cells (dPEMFCs)-battery-ultra-capacitors (UCs)-driven hybrid electric vessels (HEVs). At first, the summed power of the dual PEMFCs is defined by using the equivalent consumption minimum strategy (ECMS). Accordingly, a map search engine (MSE) is proposed to appropriately split power for each FC stack and maximize its total efficiency. The remaining power is then distributed to each battery and UC using an adaptive co-state, timely determined based on the state of charge (SOC) of each device. Due to the strict constraint of the energy storage devices' (ESDs) SOC, one fine-corrected layer is suggested to enhance the SOC regulations. With the comparative simulations with a specific rule-based EMS and other approaches for splitting power to each PEMFC unit, the effectiveness of the proposed topology is eventually verified with the highest efficiency, approximately about 0.505, and well-regulated ESDs' SOCs are obtained. [ABSTRACT FROM AUTHOR]

Published

2024

44. A Systematic Review on the Risk of Overheating in Passive Houses.

Author

Farrokhirad, Ensiyeh, Gao, Yun, Pitts, Adrian, and Chen, Guo

Subjects

HOUSING development, RISK perception, VERTICAL gardening, ENERGY shortages, THERMAL comfort

Abstract

The rise in energy-efficient building strategies, driven by the intensifying energy crisis, has encouraged the development of the passive house (PH) approach. However, existing research highlights a potential downside, the perception of the overheating risk in hot periods, particularly when design and construction methods fail to incorporate adequate mitigation strategies. This study examines the pressing necessity of addressing overheating risks in PHs through a systematic review. The aim is to identify key factors reported as contributing to overheating, to evaluate recommended solutions across diverse global regions, and to identify methods to reduce the risk. This review indicates that PHs are considered at risk of overheating in the hot periods of the year across many climatic regions, exacerbated by the impacts of climate change. Architectural features, climate conditions, inhabitants' behaviors, and perceptions of the quality of indoor spaces are important factors affecting PH overheating and should be considered at the design stage. It is concluded that the urban context, building envelope characteristics, and their impacts require greater attention. Based on the knowledge gaps identified, green walls are proposed as a nature-based solution with good potential for mitigating overheating in PHs. More integrated consideration of all factors and solutions can minimize current and future risks. [ABSTRACT FROM AUTHOR]

Published

2024

45. Energy-Saving Evaluation and Comprehensive Benefit Analysis of Power Transmission/Distribution System Based on Cloud Model.

Author

Liu, Xuan, Tang, Lei, Lu, Yan, Xiang, Jing, Qin, Huifang, Zhou, Geqian, Liu, Chengwei, and Qin, Bo

Subjects

*GRIDS (Cartography), *POWER transmission, *ENERGY conservation, *ENERGY shortages, *ELECTRIC lines, *ANALYTIC hierarchy process

Abstract

The current situation of the energy crisis requires various industries around the world to seek technological upgrades to achieve energy conservation. The renovation of power grid lines, transformers, and substations significantly affects the comprehensive benefits of power transmission/distribution systems, and the optimization of specific parameters of these elements plays a critical role in their operational performance. In order to determine the effects of these parameters and realize their accurate optimization, herein, we establish a method combining an analytic hierarchy process and an entropy weight method to calculate the weightings of the indexes, and then evaluate the comprehensive benefits through a cloud model. Based on the evaluation system above, a case study was utilized to analyze the power transmission/distribution system of a designated area in Wuhan City, and the results showed that the comprehensive benefits increased by around 5.4% compared to 2022, and could be upgraded to level IV in the cloud model with the technical transformation. This exhibits the effectiveness and the application feasibility of this evaluation system. [ABSTRACT FROM AUTHOR]

Published

2024

46. Examining the Evolution of Energy Storing in the Ecuadorian Electricity System: A Case Study (2006–2023).

Author

Oscullo Lala, José, Carvajal Mora, Henry, Orozco Garzón, Nathaly, Vega, José, and Ohishi, Takaaki

Subjects

*ELECTRIC power production, *HYDROELECTRIC power plants, *ENERGY shortages, *ELECTRIC power distribution grids, *POTENTIAL energy, *DAMS

Abstract

Ensuring a balance between supply and demand is critical within electricity grids, requiring a supply composition that guarantees consistent service provision in the short and medium term. Between 2008 and 2017, Ecuador's electricity generation capacity expanded significantly, with an investment of approximately USD 8150 million into harnessing the potential energy of water. This led to the construction of five high-capacity hydroelectric projects by 2017, contributing 33.4% of the sector's energy output by 2023. However, it is important to note that if installed hydroelectric projects operate as run-of-river plants, with limited reservoir capacity, they can only regulate water use for electricity generation on an hourly basis. As of 2023, these run-of-river plants represent 68.8% of Ecuador's total hydroelectric capacity within the National Interconnected System (SNI). Consequently, during periods of low inflows, supplementary energy from other power generation plants is necessary to prevent energy crises. This paper addresses the impact on energy storing for electricity generation resulting from the evolution of hydroelectric power plant entry from 2006 to 2023. This aspect has not been thoroughly examined in hydrothermal systems, which primarily focus on potential energy obtained from dams. Our approach involves a statistical analysis of hydroelectric dam reservoir operational levels. We further explore the influence on demand service within Ecuador's electricity system, particularly during observed energy crises towards the end of 2023. [ABSTRACT FROM AUTHOR]

Published

2024

47. A Review on the Impact of Transmission Line Compensation and RES Integration on Protection Schemes.

Author

Mazibuko, Ntombenhle, Akindeji, Kayode T., and Moloi, Katleho

Subjects

*RENEWABLE energy sources, *ELECTRIC lines, *ENERGY consumption, *POWER resources, *ENERGY shortages

Abstract

South Africa is currently experiencing an energy crisis because of a mismatch between energy supply and demand. Increasing energy demand necessitates the adequate operation of generation and transmission facilities to maintain the reliability of the power system. Transmission line compensation is used to increase the ability to transfer power, thereby enhancing system stability, voltage regulation, and reactive power balance. Also, in recent years, the introduction of renewable energy sources (RES) has proven to be effective in supporting the grid by providing additional energy. As a result, the dynamics of power systems have changed, and many developing nations are adopting the integration of renewable energy into the grid to increase the aspect ratio of the energy availability factor. While both techniques contribute to the grid's ability to meet energy demand, they frequently introduce technical challenges that affect the stability and protection of the systems. This paper provides a comprehensive review of the challenges introduced by transmission line compensation and the integration of renewable energy, as well as the various techniques proposed in the literature to address these issues. Different compensation techniques, including fault detection, classification, and location, for compensated and uncompensated transmission lines, including those connected to renewable energy sources, are reviewed. This paper then analyzes the adaptive distance protection schemes available in the literature to mitigate the impact of compensation/integration of RES into the grid. Based on the literature reviewed, it is essential for protection engineers to understand the dynamics introduced by network topology incorporating a combination of RES and heavily compensated transmission lines. [ABSTRACT FROM AUTHOR]

Published

2024

48. The Impact of Load-Shedding on Scheduled Water Delivery Services for Mohlaba-Cross Village, Greater Tzaneen, South Africa.

Author

Machimana, Lebogang Irene, Gumbo, Anesu Dion, Moyo, Hloniphani, and Mugari, Ephias

Subjects

RENEWABLE energy sources, SUPPLY & demand, WATER management, ENERGY shortages, WATER security

Abstract

Reliable potable water is essential for sustaining livelihoods and promoting human well-being, yet many rural communities in South Africa have disrupted and inadequate access. This has been exacerbated by the energy crisis that led to frequent load-shedding. As a water-scarce country, the South African government considers sustainable management of resources as critical to sustaining lives and livelihoods. The lengthy load-shedding schedules prompted the need to investigate how they disrupt scheduled water delivery services using the case of Mohlaba-Cross Village in Limpopo Province. This study investigated the challenges load-shedding poses for water access in already water-deprived communities. Quantitative and qualitative data were collected through structured questionnaires, key informant interviews, focus group discussions, observations, and review of documents. Results indicate that load-shedding significantly disrupts scheduled water delivery services, hence daily household chores, livelihoods, local businesses, and economic activities. Some community members resorted to buying water from private vendors, which is unsustainable, especially for low-income households and small businesses. Despite understanding the limitations caused by load-shedding, proactive measures were hindered by a lack of communication and collaboration among key stakeholders. Low pumping capacity and a lack of adaptability in water management posed additional limitations. The study underscores the importance of supply-side interventions by water authorities, such as investing in alternative energy sources and improving pumping capacity to address the interconnected energy and water security challenges. Managing the demand side through promoting water conservation and embracing adaptive management strategies requires effective collaboration by all stakeholders. However, this requires the water authorities to initiate the process. Our study contributes to understanding the energy-water nexus in rural communities and the need for stakeholder engagement to address emerging challenges. It provides insights for policymakers, water managers, businesses, and communities to foster sustainable water management practices and improve the well-being of all. [ABSTRACT FROM AUTHOR]

Published

2024

49. Mapping the Wholesale Day-Ahead Market Effects of the Gas Subsidy in the Iberian Exception.

Author

González-de Miguel, Carlos, Wunnik, Lucas van, and Sumper, Andreas

Subjects

*DEMAND function, *SUBSIDIES, *ENERGY shortages, *ELECTRICITY markets, *WHOLESALE trade, *NATURAL gas

Abstract

Amidst the global energy crisis in 2022, the Spanish and Portuguese governments introduced a subsidy to natural gas ("the Iberian exception"), attempting to lower the wholesale electricity market prices, with the understanding that gas-fired-combined cycle gas turbines (CCGTs) are price-setting technologies most of the time, directly or indirectly. The subsidy succeeded in lowering the market price but induced several other effects, such as (1) the increase in cleared energy in the Spanish market (mostly produced with gas), (2) the bias in the import/export cross-border position between Spain and France (Spain became a net exporter to France immediately), or (3) the consequent increase in congestion rents, which serve to lightly finance the subsidy, among other effects. This paper provides a framework for clustering the different effects based on the market participation phases: the subsidy, the market bidding, the market results, and surplus and rents. Moreover, this paper builds on the theoretical market models, with and without subsidies, and with and without cross-border exchanges. Based on the real market bids, the subsidies, and the generators' data, we reconstruct the supply and demand curves and simulate the counterfactual market scenarios in order to illustrate and quantify the effects. We highlight the quantification of the theoretical effect of the transfer of rents, from non-fossil to fossil fuel producers, induced by the gas subsidy. [ABSTRACT FROM AUTHOR]

Published

2024

50. Comparison of Scenedesmus obliquus in CO 2 Capture, Biolipid Production and Nutrient Removal.

Author

Cao, Wenwen, Yu, Hongfei, Dong, Wei, Rong, Zijia, Peng, Dianbao, Chen, Fukun, and Li, Lixin

Subjects

*CARBON sequestration, *SEWAGE, *CARBON dioxide fixation, *SCENEDESMUS obliquus, *ENERGY shortages

Abstract

The cultivation of microalgae from municipal wastewater, while simultaneously removing nutrients from the water column, has the potential to aid biodiesel production and carbon dioxide fixation, thereby alleviating the pressure of energy shortages. In this research, different ratios of sodium bicarbonate and glucose were used to prepare simulated municipal wastewater. The results demonstrated that microalgae were most effectively treated under one-stage direct treatment conditions. During direct culture, the most effective treatment was observed for IAA-3, which exhibited a dry weight of 1.4363 g/L and a lipid content of 25.05% after stimulation with 0.0005 M NaHCO3. In contrast, NaHCO3-2 demonstrated optimal performance during the secondary culture, with a dry weight of 1.6844 g/L and a lipid content of 18.05%. Finally, the economic, social and environmental benefits of direct treatment (IAA-3) and secondary treatment NaHCO3-2 were analyzed. The benefits of direct treatment were found to be USD 0.50989/L, while those of secondary treatment were USD 0.43172/L. For each tonne of municipal wastewater treated, the carbon sequestration benefits of IAA-3 during direct treatment and NaHCO3-2 during secondary treatment were USD 0.45645 and USD 0.85725, respectively. [ABSTRACT FROM AUTHOR]

Published

2024