Your search keyword '"ENERGY infrastructure"' showing total 3,683 results

1. Insight into the photocatalytic and photothermal effect in plasmon-enhanced water oxidation property of AuTNP@MnOx core–shell nanoconstruct.

Author

Paital, Diptiranjan, Bansal, Tarun, Kaushik, Tannu, Joshi, Gayatri, Sett, Soumyadip, and Khatua, Saumyakanti

Subjects

*PHOTOTHERMAL effect, *OXIDATION of water, *ENERGY infrastructure, *HOT carriers, *PHOTOELECTROCHEMICAL cells, *CATALYTIC activity, *OXYGEN evolution reactions

Abstract

The development of robust and efficient photocatalytic constructs for boosting the water oxidation reaction (WOR) is needed for establishing a sunlight-driven renewable energy infrastructure. Here, we synthesized plasmonic core–shell nanoconstructs consisting of triangular gold nanoprism (AuTNP) core with mixed manganese oxide (MnOx) shell for photoelectrocatalytic WOR. These constructs show electrocatalytic WOR with a low onset overpotential requirement of 270 mV at pH 10. Photoexcitation showed further enhancement of their catalytic activity resulting in ∼15% decrease of the onset overpotential requirement along with the generation of photocurrent density of up to 300 μA/cm2. We showed that such light-driven enhancement of AuTNP@MnOx dyad's catalytic activity toward the WOR process includes contributions from both photocatalytic (hot carriers driven) and photothermal effects with photothermal effect playing the major role for wavelength between 532 and 808 nm. The contribution from the photocatalytic effect is appreciable only for high-energy excitations near the interband region, while the photothermal effect largely dominates for lower energy excitations near the LSPR wavelengths of the dyad. [ABSTRACT FROM AUTHOR]

Published

2023

2. Microgrids control: AC or DC, that is not the question.

Author

Cucuzzella, Michele, Scherpen, Jacquelien M. A., and Machado, Juan E.

Subjects

*MICROGRIDS, *DIRECT currents, *ENERGY infrastructure, *INFRASTRUCTURE (Economics), *VOLTAGE

Abstract

In these lecture notes, we delve into the models of the most commonly used DC-DC power converters: namely, the buck converter and the boost converter. Furthermore, we derive models for a DC microgrid consisiting of multiple buck and/or boost converters interconnected via (dynamic) resistive-inductive power lines and supplying the so-called ZIP loads, which are characterized by the parallel combination of constant impedance (Z), current (I), and power (P) load components. Furthermore, we introduce the primary control objectives in DC microgrids, focusing on voltage regulation and current sharing. Finally, we explore the most advanced control techniques to achieve these objectives. Importantly, these lecture notes are not intended to advocate total replacement of Alternating Current (AC) power systems with their Direct Current (DC) counterparts, but rather aim to offer a balanced perspective between them, acknowledging the historical dominance of AC power systems while underscoring the contemporary relevance of DC microgrids, which, with their inherent advantages, represent a viable complement to the existing infrastructure, fostering innovation and resilience in modern power networks. [ABSTRACT FROM AUTHOR]

Published

2024

3. Heat and the city: Thermal control, governance and health in urban Asia.

Author

Clancey, Gregory, Chang, Jiat-Hwee, and Chee, Liz PY

Subjects

*URBAN heat islands, *CITIES & towns, *CLIMATE change, *ENERGY infrastructure, *SOLAR radiation

Abstract

This special issue focuses on the under-studied but increasingly pressing issue of urban heat. Cities are getting hotter, both due to the global crisis of climate change, and the related phenomena of Urban Heat Islands, which locally amplify increased global temperatures and exposure to solar radiation. We know a great deal about how heat is affecting cities from a scientific and public health perspective. Urban studies scholarship, however, has been slower to foreground heat as a social, spatial, and political category of analysis, at least in comparison to discussions of carbon emissions and their control, energy and infrastructure, rising sea levels or flooding, and activism towards sustainability. While many of these themes also figure in this collection, our focus is on the varied phenomena of urban dwellers feeling, avoiding, suffering under, mitigating, culturally interpreting and attempting to anticipate and plan for, the reality of elevated air temperatures and solar radiation. What we call thermal control, governance, and health is the multi-level and multivalent social and material response to uncomfortable and potentially injurious temperatures, an elusive topic this special issue makes visible and constitutes what we hope will be an ongoing urban research agenda. [ABSTRACT FROM AUTHOR]

Published

2024

4. Urban energy landscape in practice: Architecture, infrastructure and the material culture of cooling in post-reform Chongqing, China.

Author

Kobi, Madlen

Subjects

*BUILT environment, *ENERGY infrastructure, *LANDSCAPE architecture, *URBAN climatology, *ROOFTOP construction

Abstract

Until the 1990s and the spread of air-conditioning, cooling down during the hot, humid and windless summers in the city of Chongqing (Southwest China) was mainly practised outdoors: sleeping on the rooftops of multistorey buildings, playing mah-jongg in the streets, fanning oneself with a hand fan or installing bamboo beds in the compounds' leafy courtyards. With the availability of affordable electricity and the popularisation of mechanical cooling, refreshing oneself has been relocated to the indoors. The transforming practices in and around the house have led not only to an increasing dependency on electricity for cooling but also to a socio-economic stratification. This paper traces the history of heat mitigation in Chongqing since the 1950s. Based on five months of anthropological fieldwork, semi-structured interviews, and oral history, I analyse how Chongqing residents cope with heat in and around the built environment. Practices of cooling are closely intertwined with the architectural history of the city, for example, building design, construction materials, green spaces, or the arrangement of houses. Staying cool in the socialist era buildings from the 1960s meant something different compared to the high-rise buildings in the early-21st century. Theoretically, the paper engages with urban energy landscapes as 'connective tissue' where everyday heat mitigating practices are intertwined with the locally built environment including architecture, energy infrastructure and technologies. By focusing on the material culture involved in cooling, I shift our perspective from the large infrastructure to the small objects that co-constitute the energy landscape of urban heat mitigation. [ABSTRACT FROM AUTHOR]

Published

2024

5. Integration of disamenity costs and equality considerations regarding onshore wind power expansion and distribution into energy system optimization models.

Author

Lohr, C., Peterssen, F., Schlemminger, M., Bensmann, A., Niepelt, R., Brendel, R., and Hanke-Rauschenbach, R.

Subjects

ENERGY infrastructure, SOCIAL acceptance, WIND power, SOCIAL integration, MATHEMATICAL optimization

Abstract

Background: Social acceptance of energy infrastructure projects affects public support for the energy transition and is essential for the transition's sustainability and success. Despite extensive research focusing on the social acceptance of renewable energy, and on the acceptance of onshore wind power in particular, energy system models have largely prioritized techno-economic aspects. This focus has created a gap between model results and decision-makers' needs. In this study, we offer recommendations for integrating disamenity costs and equality considerations—two critical social aspects related to onshore wind power—into energy system optimization. To achieve this, we use a spatially distributed model from a climate-neutral Germany and explore various implementations and trade-offs of these two social aspects. Results: We identified effective linear formulations for both disamenity costs and equality considerations as model extensions, notably outperforming quadratic alternatives, which exhibit longer solution times (+ 50–115%). Our findings reveal that the endogenous consideration of disamenity costs in the optimization approach can significantly reduce the human population's exposure to wind turbines, decreasing the average disamenity per turbine by 53%. Drawing on notions of welfare economics, we employ two different approaches for integrating equality into the optimization process, permitting the modulation of the degree of equality within spatial distributions in energy system models. The trade-offs of the two social aspects compared to the cost-optimal reference are moderate, resulting in a 2–3% increase in system costs. Conclusions: Disamenity costs emerge as a predominant factor in the distribution of onshore wind power in energy system optimization models. However, existing plans for onshore wind power distribution in Germany underscore equality as the driving factor. The inclusion of social aspects in energy system models facilitates the identification of socially superior wind turbine locations. Neglecting disamenity costs and equality considerations leads to an overestimation of the practical solution space for decision-makers and, consequently, the resulting energy system designs. [ABSTRACT FROM AUTHOR]

Published

2024

6. Resource Nexus for decision-making: an industry-community synergistic approach for textile wastewater management.

Author

Gomes, Kamol, Morris, Jon, Miggelbrink, Judith, Guenther, Edeltraud, and Caucci, Serena

Subjects

*INDUSTRIAL wastes, *SEWAGE purification, *CLEAN energy, *SUSTAINABILITY, *ENERGY infrastructure

Abstract

Although the textile industry is crucial to economic development, it is a significant polluter of global water sources through its wastewater discharge, which endangers aquatic ecosystems and neighboring communities. This study focuses on stakeholder perceptions from farming and fishing communities related to wastewater management in the Bangladesh textile industry. Using focus group discussions with stakeholders that focused on sustainability values and a Resource Nexus framing, the results emphasise the adverse effects of textile wastewater on neighbouring communities, spanning agriculture, livestock, and ecological resources. The findings also underscore a significant need for collaboration between the textile industry and neighbouring communities, emphasising the ongoing obligation of governance resources, such as monitoring, regulations, and proactive measures and advocates for engaging different stakeholders in the formulation of robust policies, stringent regulations, and concerted efforts across industry, government, and communities to deliver improved governmental monitoring, enforcement of regulations and transparency in wastewater management practices in the textile industry of Bangladesh. The study suggests that a Water-Energy-Ecosystems-Food (WEEF) Resource Nexus approach can enhance decision-making, promoting sustainable energy infrastructure, encourage increased treated wastewater reuse, and facilitate effective management for environmental resilience and socio-ecological systems sustainability. This study contributes valuable insights elicited from a WEEF Resource Nexus approach, offering guidance for policymakers, industry practitioners, and researchers in the textile industry and beyond, aiding in the understanding of resilient industry-community ecosystems. [ABSTRACT FROM AUTHOR]

Published

2024

7. PROSPECTS OF ORGANIZATIONAL AND LEGAL PROVISION OF ENERGY SECURITY OF UKRAINE IN THE CONDITIONS OF MODERN GEOPOLITICAL PROCESSES.

Author

V. I., Kodaniov

Subjects

ENERGY development, RUSSIAN invasion of Ukraine, 2022-, ENERGY infrastructure, ENERGY security, ENERGY industries

Abstract

The scientific article is devoted to one of the important objects of national security – energy security. The organizational and legal approaches to the regulation of energy security are singled out and certain aspects of state regulation of energy efficiency are outlined, taking into account modern geopolitical processes. The definition of energy security is formulated, its global nature is indicated, which determines its provision through the joint efforts of all countries of the world, taking into account the internal characteristics and needs of the industry. It was emphasized that energy security as an object of state policy in the conditions of armed aggression against Ukraine requires proper legal regulation and continuous coordinated state management influence in order to ensure the energy independence of the country and the stable operation of energy infrastructure facilities. The analysis of the legal provision of energy security in Ukraine allowed us to come to the conclusion about the ramifications of the legislation in the specified area, the lack of optimization and systematization of energy legislation, its conflict and tolerance for the monopoly position of energy market participants. In the conditions of the war in Ukraine, the main direction of legislative regulation of the energy market is the introduction of tax benefits, temporary special taxation regimes. It was concluded that the introduction of the Institute of the Authorized President of Ukraine on Energy Safety, the development of the Institute of Public Control in the specified field is considered a promising direction for improving the national institutional mechanism for ensuring energy security. Arguments are also given that the institutional and legal mechanisms for ensuring energy security should provide for: permanent strategic planning of the development of the energy sector; coordination of energy policy with other areas of state policy; elimination of illegal administrative influence on energy market participants; taking measures to improve energy efficiency; creation of conditions for the development of technological innovations in the field of functioning of the energy infrastructure; increasing the effectiveness of preventing cyber threats; taking measures to reduce the level of corruption and the influence of the political will of elites on the energy market of Ukraine, state deregulation and demonopolization of the energy resources market. [ABSTRACT FROM AUTHOR]

Published

2024

8. Energy Poverty Alleviation in the Era of Energy Transition—Case Study of Poland and Sweden.

Author

Janikowska, Olga, Generowicz-Caba, Natalia, and Kulczycka, Joanna

Subjects

*GREENHOUSE gas mitigation, *SOCIAL networks, *ENERGY infrastructure, *ENERGY consumption, *RURAL poor, LITERATURE reviews

Abstract

The energy transition, aimed at significantly reducing greenhouse gas emissions to combat climate change, presents both opportunities and challenges in addressing energy poverty. This article explores the differing approaches of Poland and Sweden in energy poverty alleviation within the context of this transition. Poland, with its historical dependence on coal, faces considerable obstacles as it seeks to shift towards cleaner energy sources while minimizing the impact on vulnerable populations. Conversely, Sweden, supported by its advanced energy infrastructure and strong welfare systems, has implemented effective strategies that have largely mitigated energy poverty, though challenges persist for low-income households, especially in rural areas. The article delves into the definitions, drivers, and alleviation strategies of energy poverty in both countries. Through a comprehensive literature review and the analysis of key initiatives such as Poland's Clean Air Program and Sweden's Warm Rent scheme, the study underscores the potential for policy interventions to address energy poverty. It concludes with recommendations on how both countries can further reduce energy poverty, highlighting the critical role of energy efficiency, social support systems, and the integration of renewable energy in achieving a fair and equitable energy transition. [ABSTRACT FROM AUTHOR]

Published

2024

9. Using Time-Series Databases for Energy Data Infrastructures †.

Author

Hadjichristofi, Christos, Diochnos, Spyridon, Andresakis, Kyriakos, and Vescoukis, Vassilios

Subjects

*ENERGY infrastructure, *INFRASTRUCTURE (Economics), *DATABASES, *ENERGY industries, *INFORMATION storage & retrieval systems

Abstract

The management of energy market data, such as load, production, forecasts, and prices, is critical for energy market participants, who develop in-house energy data infrastructure services to aggregate data from many sources to support their business operations. Energy data management frequently involves time sensitive operations, including rapid data ingestion, real-time querying, filling in gaps from missing or delayed data, and updating large volumes of timestamped and loosely structured data, all of which demand high processing power. Traditional relational database management systems (RDBMSs) often struggle with these operations, whereas time series databases (TSDBs) appear to be a more efficient solution, providing enhanced scalability, reliability, real-time data availability and superior performance. This paper examines the advantages of TSDBs over RDBMS for energy data management, demonstrating that TSDBs can either replace or complement RDBMSs. We present quantitative improvements in digestion, integration, architecture, and performance, demonstrating that operations such as importing and querying time-series energy data, along with the overall system's efficiency, can be significantly improved, achieving up to 100 times faster operations compared to relational databases, all without requiring extensive modifications to the existing information system's architecture. [ABSTRACT FROM AUTHOR]

Published

2024

10. Trend Analysis of Cross-Border Electricity Trading in Pan-European Network.

Author

Venizelou, Venizelos and Poullikkas, Andreas

Subjects

*ENERGY infrastructure, *POWER resources, *ENERGY development, *RENEWABLE energy transition (Government policy), *ENERGY industries

Abstract

The long-term global target of facilitating energy security and optimizing resource utilization while supporting the transition to sustainable energy systems has led the pathway towards regional cooperation in the context of energy infrastructures and trading. Recent trends highlight the development of transnational energy grids, pipelines, and renewable energy projects, facilitating efficient distribution of electricity, gas, and other energy forms. These advancements offer benefits such as increased reliability of energy supply, cost savings through shared resources, and strengthened relationships between countries. However, challenges persist, including regulatory differences, geopolitical tensions, alignment of market rules as well as substantial investment requirements in infrastructure and technology. Addressing these challenges necessitates harmonized policies, robust legal frameworks, and cooperative international governance, which are crucial for effective cross-border energy trading. The aim of the work is to present the current landscape as well as analyze the latest trends and developments in the dynamic field of electricity interconnectors, providing insights into its trajectory and implications for the European internal energy market. [ABSTRACT FROM AUTHOR]

Published

2024

11. Seasonal forecasting of the European North-West shelf seas: limits of winter and summer sea surface temperature predictability.

Author

Atkins, Jamie R. C., Tinker, Jonathan, Graham, Jennifer A., Scaife, Adam A., and Halloran, Paul R.

Subjects

*OCEAN temperature, *ATMOSPHERIC circulation, *ENERGY infrastructure, *LEAD time (Supply chain management), *DYNAMICAL systems

Abstract

The European North-West shelf seas (NWS) support economic interests and provide environmental services to adjacent countries. Expansion of offshore activities, such as renewable energy infrastructure, aquaculture, and growth of international shipping, will place increasingly complex demands on the marine environment over the coming decades. Skilful forecasting of NWS properties on seasonal timescales will help to effectively manage these activities. Here we quantify the skill of an operational large-ensemble ocean-atmosphere coupled global forecasting system (GloSea), as well as benchmark persistence forecasts, for predictions of NWS sea surface temperature (SST) at 2–4 months lead time in winter and summer. We identify sources of and limits to SST predictability, considering what additional skill may be available in the future. We find that GloSea NWS SST skill is generally high in winter and low in summer. GloSea outperforms simple persistence forecasts by adding information about atmospheric variability, but only to a modest extent as persistence of anomalies in the initial conditions contributes substantially to predictability. Where persistence is low – for example in seasonally stratified regions – GloSea forecasts show lower skill. GloSea skill can be degraded by model deficiencies in the relatively coarse global ocean component, which lacks dynamic tides and subsequently fails to robustly represent local circulation and mixing. However, "atmospheric mode matched" tests show potential for improving prediction skill of currently low performing regions if atmospheric circulation forecasts can be improved. This underlines the importance of coupled atmosphere-ocean model development for NWS seasonal forecasting applications. [ABSTRACT FROM AUTHOR]

Published

2024

12. Reliability of Open Public Electric Vehicle Direct Current Fast Chargers.

Author

Rempel, David, Cullen, Carleen, Matteson Bryan, Mary, and Vianna Cezar, Gustavo

Subjects

*INFRASTRUCTURE (Economics), *CONSUMER confidence, *ELECTRIC vehicle charging stations, *ZERO emissions vehicles, *ENERGY infrastructure, *ELECTRIC motors

Abstract

Objective: The aim was to systematically evaluate the usability of all public electric vehicles (EV) direct current fast chargers (DCFC) in the San Francisco region. Background: To achieve a rapid transition to EVs, a highly reliable and easy to use charging infrastructure is critical to building confidence among consumers. Methods: The functionality and usability of all 182 open, public DCFC charging stations with CCS connectors (combined charging system) in the 9 counties of the Bay Area were tested (655 electric vehicle service equipment (EVSE) ports). An EVSE was classified as functional if it charged an EV for 2 minutes. Results: Overall, 73.3% of the 655 EVSEs were functional. The causes of the nonfunctioning EVSEs (23.5%) were blank or unresponsive screens or error messages; payment system failures; charge initiation failures; network failures; or broken connectors. In addition, the cable was too short to reach the EV inlet for 3.2% of the EVSEs. A random sampling of 10% of the EVSEs, approximately 8 days after the first evaluation, found no overall change in functionality. Conclusions: The level of functionality found with field testing conflicts with the 95–98% uptime reported by the EV service providers (EVSPs) who operate the EV charging stations. There is a need for precise and verifiable definitions of uptime, downtime, and excluded time, as applied to public EV chargers. Application: The level of failure of the existing public EV DCFC charge infrastructure highlights the importance of improving the system design and maintenance to improve adoption of EVs. [ABSTRACT FROM AUTHOR]

Published

2024

13. The Potential for the Use of Hydrogen Storage in Energy Cooperatives.

Author

Sołtysik, Maciej, Kozakiewicz, Mariusz, and Jasiński, Jakub

Subjects

HYDROGEN as fuel, RENEWABLE energy sources, ENERGY storage, ENERGY infrastructure, ENERGY security, HYDROGEN storage

Abstract

According to the European Hydrogen Strategy, hydrogen will solve many of the problems with energy storage for balancing variable renewable energy sources (RES) supply and demand. At the same time, we can see increasing popularity of the so-called energy communities (e.g., cooperatives) which (i) enable groups of entities to invest in, manage, and benefit from shared RES energy infrastructure; (ii) are expected to increase the energy independence of local communities from large energy corporations and increase the share of RES. Analyses were conducted on 2000 randomly selected energy cooperatives and four energy cooperatives formed on the basis of actual data. The hypotheses assumed in the research and positively verified in this paper are as follows: (i) there is a relationship between hydrogen storage capacity and the power of RES, which allows an energy community to build energy independence; (ii) the type of RES generating source is meaningful when optimizing hydrogen storage capacity. The paper proves it is possible to build "island energy independence" at the local level using hydrogen storage and the efficiency of the power-to-power chain. The results presented are based on simulations carried out using a dedicated optimization model implemented by mixed integer programming. The authors' next research projects will focus on optimizing capital expenditures and operating costs using the Levelized Cost of Electricity and Levelized Cost of Hydrogen methodologies. [ABSTRACT FROM AUTHOR]

Published

2024

14. Full Road Transport Sector Transition Towards 100% Autonomous Renewable Energy Supply in Isolated Systems: Tenerife Island Test Case.

Author

Santana-Méndez, Itziar, García-Afonso, Óscar, and González-Díaz, Benjamín

Subjects

POWER resources, RENEWABLE energy transition (Government policy), ENERGY infrastructure, RENEWABLE energy sources, ENERGY consumption

Abstract

The transition towards sustainable energy systems is a key challenge faced by society. Among the different sectors, road transport becomes one of the most difficult due to the large energy consumption and infrastructure requirements. In this context, although zero-tailpipe-emission vehicle adoption is seen as a promising route, the energy provision through renewable sources is still uncertain, especially with hydrogen. This paper explores a 100% renewable energy supply scenario for both power-generation and road transport sectors in the isolated system of Tenerife. With this aim, the island's energy system has been modelled in the software EnergyPLAN. Taking as reference the current renewable technology roadmap in the island, the impact of a full deployment of zero-tailpipe-emission vehicles on the energy system has been evaluated, providing the power and energy storage capacity requirements. The obtained results indicate the need for 6 GW of renewable power (nearly 20 times the current figures) and 12 GWh of a yet non-existent storage capacity. This deployment must be accompanied with approximately 1 GW of dispatchable sources and 1.3 GW of electrolysis capacity to carry out a complete decarbonisation of the transport sector in the island. Finally, a series of recommendations to policy makers are suggested to support the definition of future roadmaps. [ABSTRACT FROM AUTHOR]

Published

2024

15. The restriction of Japan’s coal-fired power plants export: explaining the shift in Abe Shinzō’s posture towards the overseas promotion of energy infrastructure.

Author

Yamamoto, Raymond and Sasada, Hironori

Subjects

*COAL-fired power plants, *RENEWABLE energy transition (Government policy), *ADVOCACY coalition framework, *ENERGY infrastructure, *ENERGY levels (Quantum mechanics)

Abstract

AbstractIn 2019, Japan’s Ministry of Environment (MoE), led by Koizumi Shinjirō, embarked on a quest to end the country’s ‘coal addiction’ against the coal industry’s interests, as represented by the powerful Ministry of Economy, Trade and Industry (METI). Against all expectations, Prime Minister Abe Shinzō sided with MoE and implemented restrictions. It initiated the end of Japan’s government support for ‘unabated’ coal-fired power plant exports despite their continued high demand from overseas. This article uses the Advocacy Coalition Framework to explain the importance of the MoE and Environment Minister Koizumi Shinjirō in shifting Abe’s posture towards the global energy transition. [ABSTRACT FROM AUTHOR]

Published

2024

16. From petroleum to power sources: Big Oil and the technopolitics of energy conversion.

Author

Eisler, Matthew N.

Subjects

*RENEWABLE energy transition (Government policy), *ELECTRIC batteries, *ENERGY infrastructure, *ENERGY conversion, *FUEL cells

Abstract

This paper explores spillover into advanced energy conversion technologies as an oil industry response to US energy and environmental policies from the last third of the twentieth century. These policies initiated the ‘quasi-planned’ renovation of energy infrastructure through an uncoordinated mixture of regulation and innovation/industrial stimulus intended to develop all forms of primary energy and the technologies that could efficiently and cleanly convert that energy. Influenced by this sweeping public policy objective as well as the global consumer electronic industry’s increasing demand for petroleum-derived inputs from the late 1970s, Western oil interests doing business in the US engaged the technoscience of advanced energy conversion. Big Oil researched, developed, and in some cases manufactured materials and components associated with power sources including fuel cells, galvanic batteries, and photovoltaic arrays in projects that illustrate the affinities and antagonisms between enterprises of naturally stored primary energy, energy conversion, and flows and carriers of energy. Case studies of Big Oil’s involvement with these technologies illustrate how public policies supporting all-of-the-above energy and energy conversion limited the extent of oil spillover into advanced energy conversion systems and complicated the transition to a fossil fuel-free future. [ABSTRACT FROM AUTHOR]

Published

2024

17. Effect of temperature on seasonal wind power and energy potential estimates in Nordic climates.

Author

Markus, Salmelin, Hannu, Karjunen, and Jukka, Lassila

Subjects

RENEWABLE energy sources, WIND power, ENERGY infrastructure, WIND measurement, POWER transmission

Abstract

A major obstacle standing in the way of full‐scale adoption of renewable energy sources is their intermittency and seasonal variability. To better understand the power generation dynamics, the effect of air density due to temperature on power and energy generation figures was modelled. The model uses historical ERA5 data and considers changes in weather patterns in a subarctic climate where seasonal changes are most pronounced. The power generation figures of using a mean and a dynamic air density value were compared and the results show that power generation estimates may be under‐ and overestimated by on average 5% up to 10% in winter and summer, respectively. This can have implications for the sizing of power transmission infrastructure and energy storage in both on‐grid and off‐grid applications as well as power availability. The topic is highly relevant in the Nordic countries where roughly 10% of new global added wind capacity is installed annually. [ABSTRACT FROM AUTHOR]

Published

2024

18. On-Grid Hybrid Wind–Solar Power Plants in Ukraine's Residential Sector: Economic Justification of Installation Under Different Support Schemes.

Author

Kurbatova, Tetiana, Sotnyk, Iryna, Perederii, Tetiana, Prokopenko, Olha, Wit, Bogdan, Pysmenna, Uliana, and Kubatko, Oleksandra

Subjects

*RENEWABLE energy sources, *ENERGY industries, *HYBRID power, *ENERGY infrastructure, *DISTRIBUTED power generation

Abstract

On-grid hybrid wind–solar systems are one of the best sustainable solutions for developing distributed generation, as they can provide a stable and reliable electricity supply, effectively using the potential of the two most common renewable energy resources. In Ukraine, promoting the development of on-grid hybrid wind–solar power plants takes on particular importance under conditions of electricity shortages caused by the large-scale destruction of the energy infrastructure due to the ongoing hostilities. This article examines the economic efficiency of installing such power plants in the residential sector of Ukraine under different state support schemes. This study was conducted for on-grid hybrid wind–solar systems of various configurations and installed capacities with different equity and debt capital proportions involved in implementing investment projects. This study's results highlight the economic efficiency of the feed-in tariff compared to the net billing for households investing in such facilities and emphasize the need to improve policy measures to increase their investment attractiveness. [ABSTRACT FROM AUTHOR]

Published

2024

19. Effect of Energy Poverty Alleviation on High-Quality Economic Development: An Empirical Study Based on China.

Author

Yang, Fang and Gan, Qinfan

Subjects

*ECONOMIC development, *REGIONAL development, *ENERGY infrastructure, *ENERGY development, *INCOME inequality

Abstract

High-quality development (HQD) has been listed as the first and foremost task in building a modern socialist country in all respects and also an overarching issue of China's economic and social development in the new era. To achieve economic HQD, a key approach lies in integrating energy development with poverty alleviation and fully leveraging the foundational role of energy infrastructure and supply services in reducing poverty. Using the provincial panel data from 2007 to 2017, this paper analyzes the impact of energy poverty alleviation on economic HQD from multiple dimensions in an empirical way and draws the following conclusions: first, energy poverty alleviation drives the economic growth of China's eastern region and western region, but it cannot effectively promote the synchronous economic growth of the central region, thereby resulting in a greater imbalance in regional development; second, energy poverty alleviation has an effect on reducing the urban–rural income inequality, and such an effect is more significant in the western region; and finally, energy poverty alleviation has a significant effect on promoting economic HQD, and the effect is more significant in the central region and the western region. Furthermore, the transmission mechanism of energy poverty alleviation driving HQD is tested. It is found that energy poverty alleviation can drive HQD by promoting urbanization and technological progress. [ABSTRACT FROM AUTHOR]

Published

2024

20. Lightning damage assessment on solar panels using in-house portable infrared thermography camera with Convolutional Neural Network (CNN) algorithm.

Author

Chandrasegaran, Ormiila, Mustapha, Faizal, Abdullah, Mohd Na’im, Anwar, Murniwati, Mustapha, Mazli, and Adzis, Zuraimy

Subjects

*CONVOLUTIONAL neural networks, *IMAGE recognition (Computer vision), *RENEWABLE energy sources, *SOLAR panels, *ENERGY infrastructure

Abstract

As the demand for renewable energy sources increases, the vulnerability of solar panels to lightning strikes becomes a critical concern. This research explores the correlation between lightning-induced voltage fluctuations and the resultant damage intensity on solar panels. The study adopts a systematic approach, first investigating the correlation between lightning-induced voltage assessment using 30kV, 60kV and 90 kV impulse voltage with multi-stage Marx impulse generator and the damage intensity on monocrystalline and polycrystalline solar panels. A portable active infrared thermography equipment with tCam-Mini was employed to conduct this research with wireless streaming. Furthermore, the study integrates Convolutional Neural Network (CNN)-based image classification techniques to enhance the efficiency of damage assessment. The results highlight the potential of neural networks in improving the accuracy and speed of image classification for damaged and undamaged samples. The findings contribute valuable insights into enhancing the resilience of solar panel systems against lightning strikes, ultimately advancing the reliability and sustainability of solar energy infrastructure. A new CNN model was developed to classify the images obtained from thermography with 90.21% accuracy for greyscale and 85.31% accuracy on thermal images. [ABSTRACT FROM AUTHOR]

Published

2024

21. Paradigm on Levenberg–Marquardt neural algorithm analysis of heat conduction optimization for ternary hybrid nanofluid with entropy generation.

Author

Qureshi, Hamid, Shah, Zahoor, Raja, Muhammad Asif Zahoor, Shoaib, Muhammad, Khan, Waqar Azeem, and Muhammad, Taseer

Subjects

*ENERGY storage, *FERRIC oxide, *ETHYLENE glycol, *ENERGY infrastructure, *BROWNIAN motion

Abstract

The significance of the present article is to enhance the thermal management and energy efficiency of complex engineering infrastructures such as energy storage systems, modern electric vehicles, thermal insulations, heavy‐duty machinery, and production units. This research aims to understand the intricate relationship between the thermal conductivity performance of ternary (SiO2+Fe2O3+TiO2+H2O+C2H6O2${\mathrm{SiO}}_2 + {\mathrm{Fe}}_2{{\mathrm{O}}}_3 + {\mathrm{TiO}}_2 + {\mathrm{H}}_2{\mathrm{O}} + {{\mathrm{C}}}_2{{\mathrm{H}}}_6{{\mathrm{O}}}_2$) hybrid nanomaterial and entropy generation to optimize material design and efficacy. A synergetic combination of three distinct nanomaterials silicon dioxide, ferric oxide, and titanium oxide with ethylene glycol and water in the ratio 3:2 as a base solvent is comprised of contributing unique thermophysical properties. To elucidate the impact of this hybrid composition on thermal conductivity, various factors are analyzed. The advanced computational technique of Artificial intelligent feed‐forward neural network (AIFFNN) is utilized. The problem governed the system of PDEs, which is transformed into ODEs by dimensionless similarity. Adams method provided the dataset which is filtered and embedded into Marquardt–Levenberg Algorithm (LMA). The study examines the role of nanomaterial constituents, morphology, and boundary conditions on thermal performance and entropy generation. Graphical analysis of velocity, temperature, and entropy is provided with respect to varying parameters, including surface absorption (λ), magnetic strength (Tesla M), radiation parameter (Rd), Brownian motion (Br), and Eckert number (Ec). The findings have practical significance for optimizing material design in engineering and industrial applications. [ABSTRACT FROM AUTHOR]

Published

2024

22. Temperature-dependent hydrogen-induced crack propagation behaviour and mechanism in polycrystalline α-iron: Insights from molecular dynamics simulations.

Author

Li, Jiaqing, Wu, Ziyue, Yin, Pengbo, Teng, Lin, Zhang, Che, Deng, Guanyu, Luo, Yu, and Jiang, Lilong

Subjects

*PHASE transitions, *INFRASTRUCTURE (Economics), *CRACK propagation (Fracture mechanics), *ENERGY infrastructure, *MOLECULAR dynamics

Abstract

Understanding the interactions between hydrogen and material integrity in polycrystalline α-Fe is essential for advancing the reliability of critical infrastructure and energy systems. In this study, molecular dynamics simulations were implemented to pinpoint the crack propagation behaviour and mechanism in polycrystalline α-Fe under various hydrogen concentrations and temperatures. The results show that a phase transition from body-centred cubic to face-centred cubic structure first occurs at the crack tip, followed by grain boundary-mediated plasticity activities at room temperature devoid of hydrogen. A limited amount of hydrogen atoms (H/Fe atomic ratio<1%) induces twinning emission from the tip, and increasing temperature further enhances dislocation plasticity as a consequence of decreased unstable stacking fault energy, thereby leading to the blunting of the crack tip. At high hydrogen concentrations (H/Fe atomic ratio>1%), the formed hydrides ahead of the crack tip suppress the phase transition, and concurrently temperature-enhanced dislocation plasticity disappears. As a consequence, the crack propagation proceeds via grain boundary cavity nucleation and growth, and ultimately evolves into intergranular fracture. These findings provide an atomistic-level explanation for temperature-dependent hydrogen-crack interaction mechanisms, and reveal a transition in the fracture mode from ductile transgranular to intergranular failure associated with locally high hydrogen concentrations found in the experiments. • Illumination of temperature-dependent hydrogen-induced cracking in polycrystalline α-iron. • Low hydrogen concentrations induce twin emission after phase transition at the crack tip. • Increasing temperature enhances dislocation plasticity, thus blunting the crack tip. • High hydrogen concentrations encourage the formation of hydrides, and facilitate the crack propagation. • The initial crack coalesces with GB cavities, ultimately leading to an intergranular fracture. [ABSTRACT FROM AUTHOR]

Published

2024

23. Advances in energy harnessing techniques for smart highways: a review.

Author

Warsi, Mohammad Hamzah and Nandha Kumar, T.

Subjects

*CLEAN energy, *ENERGY harvesting, *ENERGY infrastructure, *POWER resources, *SUSTAINABLE transportation, *SOLAR technology

Abstract

This review paper examines the burgeoning field of energy harvesting on highways, consolidating insights from various technologies: piezoelectric, thermoelectric, pyroelectric, electromagnetic, and solar. By summarising and comparing multiple papers, this review provides a valuable resource for researchers, engineers, and policymakers. The surveyed papers encompass theoretical modelling and practical experiments, showcasing the feasibility of highway energy harvesting. Some works introduce innovative ideas, expanding the field's boundaries. This review presents concise overviews of each technology's principles, workings, challenges, as well as their respective pros and cons. By offering a balanced assessment, it informs future research, investment, and policy decisions. The convergence of these technologies on highways offers a pathway to a more sustainable and efficient transportation system, minimising environmental impact while generating valuable energy resources. This review contributes to the dialogue on energy sustainability and infrastructure development. [ABSTRACT FROM AUTHOR]

Published

2024

24. Impact of City-Wide Diesel Generator Use on Air Quality in Quito, Ecuador, during a Nationwide Electricity Crisis.

Author

Zalakeviciute, Rasa, Diaz, Valeria, and Rybarczyk, Yves

Subjects

*SUSTAINABILITY, *ENERGY infrastructure, *ELECTRIC power failures, *URBAN pollution, *DIESEL electric power-plants, DEVELOPING countries

Abstract

As climate change intensifies and 2023 sets the record for the hottest year, the Amazonian region faces severe drought, leading to a hydroelectricity crisis. This study examines the effects of using environmentally harmful backup power solutions, which are all too common in developing countries—specifically, diesel-powered generators—on urban air quality in Quito, Ecuador, during the hydroelectric crisis of 2023/2024. The impact of the blackouts on air pollution is assessed by comparing it to a reference period before the crisis and to an earlier year with similar weather conditions. The findings indicate that extended blackouts (up to 8 h per day) considerably increased concentrations of SO2 (180%), CO (43%), NO2 (39%), and PM2.5 (20%) compared to 'normal' conditions. Conversely, O3 pollution levels decreased (−6%). Our findings suggest potential respiratory and cardiovascular health risks for the urban population, highlighting the urgent need for improved energy infrastructure and cleaner backup power solutions in the developing world. Addressing these challenges is critical for ensuring a healthier and more sustainable urban future amidst climate change projections. [ABSTRACT FROM AUTHOR]

Published

2024

25. Enhancing Energy Systems and Rural Communities through a System of Systems Approach: A Comprehensive Review.

Author

Soussi, Abdellatif, Zero, Enrico, Bozzi, Alessandro, and Sacile, Roberto

Subjects

*REAL-time computing, *ENERGY infrastructure, *MACHINE learning, *PHOTOVOLTAIC power systems, *SMART cities

Abstract

Today's increasingly complex energy systems require innovative approaches to integrate and optimize different energy sources and technologies. In this paper, we explore the system of systems (SoS) approach, which provides a comprehensive framework for improving energy systems' interoperability, efficiency, and resilience. By examining recent advances in various sectors, including photovoltaic systems, electric vehicles, energy storage, renewable energy, smart cities, and rural communities, this study highlights the essential role of SoSs in addressing the challenges of the energy transition. The principal areas of interest include the integration of advanced control algorithms and machine learning techniques and the development of robust communication networks to manage interactions between interconnected subsystems. This study also identifies significant challenges associated with large-scale SoS implementation, such as real-time data processing, decision-making complexity, and the need for harmonized regulatory frameworks. This study outlines future directions for improving the intelligence and autonomy of energy subsystems, which are essential for achieving a sustainable, resilient, and adaptive energy infrastructure. [ABSTRACT FROM AUTHOR]

Published

2024

26. Evaluation of the Suitability of Geodetic Databases to Support the Process of Locating Renewable Energy Investments.

Author

Front-Dąbrowska, Teresa and Kwartnik-Pruc, Anita

Subjects

*HYDROELECTRIC power plants, *RENEWABLE energy sources, *LITERATURE reviews, *GEODATABASES, *ENERGY infrastructure

Abstract

Enhancing the production of energy from renewable energy sources (RES) has been a consistently important issue for many years, both in Poland and other countries around the world. Selecting sites for devices that convert renewable energy into electricity requires various spatial data, especially during the initial design stage when optimal investment locations are identified. The article presents a new method for assessing the usefulness of publicly accessible Polish geodetic databases—the Topographic Objects Database (Polish name: BDOT10k) and the Digital Elevation Model (DEM, Polish name: NMT)–in the process of renewable energy infrastructure siting. This study is the first to jointly assess these two databases from the user's perspective rather than the creator's or administrator's viewpoint. User requirements for spatial data were defined through research factors identified in a literature review. The methodology developed includes checking the availability of Polish geodetic databases and evaluating the quality of spatial data. Analyses were performed in a GIS environment for eighteen research areas in Poland. A suitability coefficient was developed to determine the usefulness of the databases studied. The obtained value of the suitability coefficient in each area was above 50% of its maximum value, which was taken as a threshold value proving the suitability of the analyzed databases for the purpose specified in the study. The databases are fully useful for a group of province and poviat capital cities—there the suitability coefficient value exceeds 80% of its maximum value. The studies confirmed the validity of using publicly accessible BDOT10k and DEM geodetic databases in GIS analyses for the search for sites for solar, wind, and small hydroelectric power plants. [ABSTRACT FROM AUTHOR]

Published

2024

27. Optimizing distributed energy resources in microgrid SCUC through seq2seq scheduling algorithms.

Author

Nishtar, Zuhaib, NA Li, Zahid, Muhammad, Soomro, Abdul Razzaque, and Afzal, Jamil

Subjects

RENEWABLE energy sources, ENERGY infrastructure, ENERGY consumption, POWER resources, ELECTRIC power distribution grids, DEMAND forecasting

Abstract

In order to optimize Distributed Energy Resources (DERs) inside a microgrid's Security-Constrained Unit Commitment framework, this study investigates the use of Seq2Seq (Sequence-to-Sequence) scheduling methods (SCUC). The Seq2Seq model manages uncertainties in renewable energy production and demand forecasts by leveraging historical data and real-time inputs to learn patterns in the temporal evolution of these variables. The attention mechanism embedded in the Seq2Seq architecture focuses on relevant parts of the input sequences, such as past demand spikes or periods of intermittent generation. There is a growing consensus that microgrids are an important part of the future of the electric grid because of the advantages they provide in terms of reliability, renewable energy integration, and overall efficiency. In the context of complicated SCUC issues, efficient scheduling and optimization of DERs are essential for realizing their full potential. Seq2Seq models, a kind of deep learning approach, have shown impressive performance in several applications requiring sequence prediction. Uncertainty in renewable energy production, energy demand forecasts, and security limitations are all addressed in this work as Seq2Seq algorithms are applied to microgrid SCUC. Significant gains in economic efficiency, ecological viability, and compliance with security constraints have been shown. This study lays the way for the development of more effective, sustainable, and resilient energy infrastructure by contributing to the advancement of the area of microgrid optimization. [ABSTRACT FROM AUTHOR]

Published

2024

28. The political economy of development: analysing Daqing's contribution to the formation and technocratic evolution of China's socialist state.

Author

Zhang, Yan

Subjects

ENERGY infrastructure, POLITICAL development, ECONOMIC models, OIL fields, ENERGY development

Abstract

This essay critically examines Building for Oil, a comprehensive study of the Daqing Oil Field and its role in the evolution of China's socialist state. It acknowledges the narrative's intricate exploration of Daqing's role in China's early-stage industrialization, highlighting its unique approach to urbanization and worker-peasant village formation, and Daqing's symbolic significance in reflecting Communist ideals and Mao Zedong's revolutionary ethos. However, this essay also identifies critical gaps in the book's narrative, notably the absence of pronounced connections between Daqing's historical significance and contemporary China's economic and energy infrastructure. The review argues for the necessity of incorporating discussions on the evolution of China's economic model, energy transition and the role of technocracy and leadership in shaping these dynamics. Concluding, the review acknowledges the book's significance while highlighting areas for further exploration to enrich the narrative, particularly in the context of China's ongoing transformation and global impact. [ABSTRACT FROM AUTHOR]

Published

2024

29. Optimal and Robust Load Frequency Control for Hybrid Power System Integrated with Energy Storage Device by Sine Cosine Algorithm.

Author

Saini, Narender and Ohri, Jyoti

Subjects

PARTICLE swarm optimization, RENEWABLE energy sources, PID controllers, ENERGY infrastructure, ENERGY storage

Abstract

New challenges arise in maintaining the reliability, safety, and security of power networks as they expand to include renewable energy sources and interconnect with other areas. Existing and future energy infrastructure were considered, and a control technique for controlling and improving the functioning of two hybrid models was presented in this work. The ability to control the load frequency is a critical part of any power system. So, a PID controller for load frequency control was suggested using the Sine Cosine Algorithm (SCA). The article focuses on non-linearities such as the boiler dynamics, the Generation Rate Constraint, and Governor Dead Band. The impact of energy storage devices on either power system is also examined. When compared to the outcomes of other optimization strategies, such as the Grey Wolf Optimization, Genetic Algorithm, Gorilla Troop Optimization, Particle Swarm Optimization, and other techniques, the SCA-based PID controller delivers higher performance in terms of undershoot, settling time, overshoot and Integral Time Absolute Error values. Finally, the robustness of the discussed optimization technique is tested through sensitivity analysis by varying the parameters of the tested system, i.e., governor and turbine time constant, and both at same time, within a range of ± 25% from their nominal values.Please confirm the corresponding author is correctly identified.It is confirmed that the corresponding auther is correctly identified [ABSTRACT FROM AUTHOR]

Published

2024

30. Are cities ready for low‐carbon inclusive strategies? Household energy management under heterogeneous socioeconomic conditions.

Author

Verma, Pramit, Chodkowska‐Miszczuk, Justyna, and Raghubanshi, Akhilesh Singh

Subjects

CITIES & towns, ENERGY infrastructure, INFRASTRUCTURE policy, ENERGY policy, SUSTAINABLE urban development

Abstract

Energy is an indispensable resource for economic development and the well‐being of society. Due to heterogeneity in socioeconomic conditions, households consume direct energy and produce emissions differently. Analysing energy emissions from heterogeneous socioeconomic groups helps to identify foci for intervention and create policies for sustainable cities. This study aimed to measure household emissions in Varanasi city and investigate the impact of heterogeneous socioeconomic variables on household emissions. Varanasi represents a million‐plus rapidly urbanising city. Analysis of variance (ANOVA) and non‐parametric regression revealed the relationship between end‐use energy emissions and socioeconomic variables for five income classes. Biomass‐based fuels constituted a significant proportion of energy (about 16%–20%) in low‐ to middle‐income groups, however, electricity consumption dominated in upper‐middle‐ and high‐income groups. A fuel‐stacking pattern was found, particularly in cooking activities. LPG was critical to replace solid biomass‐based fuels. To meet the present needs and absorb the impact of a growing population, energy policies and infrastructure should focus on accessibility and efficiency. An inclusive low‐carbon policy with a specialised focus on socioeconomic differences is needed for energy sustainability. [ABSTRACT FROM AUTHOR]

Published

2024

31. Beyond fossil: the synthetic fuel surge for a green-energy resurgence.

Author

Janaki, Sreejaun Thothaathiri, Madheswaran, Dinesh Kumar, Naresh, G, and Praveenkumar, Thangavelu

Subjects

SYNTHETIC fuels, CLEAN energy, WATER supply, ENERGY infrastructure, ENERGY consumption, RENEWABLE energy sources

Abstract

This review offers a comprehensive overview of synthetic fuels as promising alternatives to conventional fossil fuels. The carbon-neutral potential of synthetic fuels when produced using renewable energy and captured CO2, offering significant opportunities to mitigate CO2 emissions, is discussed. Moreover, the efficiency of synthetic fuels is presented, as they do not require dedicated agricultural land or substantial water resources, addressing concerns related to the land-use change and water scarcity associated with traditional biofuels. The economic viability of synthetic fuels is explored, highlighting the advancements in technology and decreased renewable-energy costs, coupled with their independence from food crops, mitigating concerns about potential impacts on food prices. Major investments by industry leaders such as Porsche, Highly Innovative Fuels Global, and ExxonMobil, totalling $1 billion, aimed at achieving an annual production of 550 million litres by 2026, are covered in detail. This study is further extended by emphasizing the scalability of synthetic fuel production through modular processes, enabling tailored facilities to meet regional demands and contribute to a decentralized and resilient energy infrastructure. Additionally, the 'drop-in' nature of synthetic fuels that are seamlessly compatible with existing fuel storage, pipelines, and pumps, facilitating a smooth transition without requiring extensive infrastructure changes, is highlighted. Challenges such as the current high cost of synthetic fuel production are acknowledged, necessitating supportive government policies and incentives for widespread adoption. Overall, synthetic fuels have emerged as promising contenders in the pursuit of sustainable and adaptable energy solutions, with tangible benefits for the environment, economy, and existing energy infrastructure. [ABSTRACT FROM AUTHOR]

Published

2024

32. Pathways to sustainable development: an overview of the progress and obstacles of hydroelectric power production in Angola.

Author

Francisco, Domingos Joaquim, Cordeiro, Mikael Jhordan Lacerda, Uhr, Daniel de Abreu Pereira, and Uhr, Júlia Gallego Ziero

Subjects

WATER power, ENERGY infrastructure, POSTWAR reconstruction, ENERGY policy, ENERGY futures

Abstract

This article offers an in-depth examination of the historical trajectory of Angola's hydroelectric energy sector, contextualizing its evolution within the country's political and economic landscape. It begins by tracing the origins of hydroelectric development. Subsequently, it delves into the post-independence era marked by political turmoil and civil conflict, elucidating the challenges faced by the energy infrastructure amidst the ravages of war. Moreover, the article scrutinizes Angola's post-conflict reconstruction efforts, particularly in revitalizing hydroelectric facilities and formulating strategic energy policies. It assesses the regulatory framework governing the energy sector, identifying deficiencies and proposing avenues for enhancement to ensure transparency and efficiency. This study explores the prospects and challenges associated with the Baynes Binational Hydroelectric Project on the Angola–Namibia border, highlighting its potential to foster regional cooperation and bolster energy security. The article underscores institutional reforms and strategic investments to propel Angola towards a more resilient and inclusive energy future. [ABSTRACT FROM AUTHOR]

Published

2024

33. Green hydrogen landscape in North African countries: Strengths, challenges, and future prospects.

Author

Bayssi, Oussama, Nabil, Nouhaila, Azaroual, Meryeme, Bousselamti, Loubna, Boutammachte, Noureddine, Rachidi, Samir, and Barberis, Stefano

Subjects

*GREEN fuels, *CLEAN energy, *ENERGY infrastructure, *RENEWABLE energy sources, *ENVIRONMENTAL policy

Abstract

This work examines the diverse strengths and weaknesses of North African countries in exploiting their renewable energy potential and adopting green hydrogen initiatives. The study focuses on Morocco, Algeria, Tunisia, Egypt, and Mauritania and highlights their respective contributions and challenges in the context of renewable energy and green hydrogen production. It examines Morocco's remarkable achievements in renewable energy, Algeria's potential for economic diversification, Tunisia's commitment to sustainability, Egypt's regional leadership, and the emerging role of Mauritania. The policy and regulatory landscape is assessed, highlighting the need for legal frameworks to support green hydrogen initiatives. Each country's unique approach to green hydrogen as well as their roadmaps and strategies are discussed, highlighting the importance of international collaborations and research and development. Additionally, the report looks at the evolving energy infrastructure and highlights the potential for transporting hydrogen from North Africa to Europe, including adapting existing pipelines and building new pipelines. [Display omitted] • Policies and the progress of green hydrogen projects have been assessed. • Green hydrogen represents a transformative technology for the North African region. • Morocco and Egypt appear to be the most advanced countries. • The other countries studied are still in the early stages of hydrogen development. [ABSTRACT FROM AUTHOR]

Published

2024

34. Financial stability and environment degradation in Turkey: evidence from fourier ARDL approach.

Author

Topalcık, Olgun and Kirikkaleli, Dervis

Subjects

CARBON dioxide mitigation, ENERGY infrastructure, FINANCIAL security, INFRASTRUCTURE (Economics), ENERGY consumption

Abstract

This study investigates the impact of financial stability on environmental degradation in Turkey, controlling for economic growth, renewable energy consumption, and primary energy consumption between 1990 and 2019. The study employs various statistical methodologies, including LS Unit Root, Fourier ARDL, DOLS, and FMOLS tests. The findings reveal an inverse relationship between financial stability and environmental degradation. Both economic growth and primary energy consumption are found to exacerbate environmental degradation. This study recommends that policymakers incorporate financial stability into policies aimed at reducing CO2 emissions. Furthermore, it emphasizes the importance of investing in renewable energy infrastructure and the transportation sector to effectively mitigate environmental degradation. [ABSTRACT FROM AUTHOR]

Published

2024

35. Comparative Analysis and Performance Evaluation of Underwater Cable Detection and Tracking Techniques: A Comprehensive Survey.

Author

Unal, P., Hatipoglu, O. I., Turker, A., Unal, A. F., Deveci, B. U., Kirci, P., Ozbayoglu, M., and C., Dhanamjayulu

Subjects

*SUBMARINE cables, *ENERGY infrastructure, *CONVOLUTIONAL neural networks, *TRANSFORMER models, *DATA integration, *DEEP learning

Abstract

This survey provides a comprehensive review of underwater cable detection and tracking literature, identifying key problem types and highlighting unique underwater challenges. It emphasizes the critical role of underwater cable detection in global communications and energy infrastructures, addressing complexities like low visibility and variable sea conditions. The analysis compares the efficacy of various models, particularly deep learning approaches like CNNs and Transformers, in adapting to underwater imagery challenges. A new roadmap for efficient cable detection and tracking systems is proposed, focusing on multimodal data integration and nonoptical detection methods. Importantly, the study includes performance evaluations of state‐of‐the‐art models on custom underwater datasets, offering practical insights. The survey's findings are validated through an implementation of an underwater object‐tracking model incorporating effective algorithms from the literature. [ABSTRACT FROM AUTHOR]

Published

2024

36. Comprehensive Assessment of Context-Adaptive Street Lighting: Technical Aspects, Economic Insights, and Measurements from Large-Scale, Long-Term Implementations.

Author

Pasolini, Gianni, Toppan, Paolo, Toppan, Andrea, Bandiera, Rudy, Mirabella, Mirko, Zabini, Flavio, Bonata, Diego, and Andrisano, Oreste

Subjects

*SMART cities, *ENERGY infrastructure, *STREET lighting, *PAVEMENTS, TRAFFIC flow measurement

Abstract

This paper addresses the growing importance of efficient street lighting management, driven by rising electricity costs and the need for municipalities to implement cost-effective solutions. Central to this study is the UNI 11248 Italian regulation, which extends the European EN 13201-1 standard introduced in 2016. These standards provide guidelines for designing, installing, operating, and maintaining lighting systems in pedestrian and vehicular traffic areas. Specifically, the UNI 11248 standard introduces the possibility to dynamically adjust light intensity through two alternative operating modes: (a) Traffic Adaptive Installation (TAI), which dims the light based solely on real-time traffic flow measurements; and (b) Full Adaptive Installation (FAI), which, in addition to traffic measurements, also requires evaluating road surface luminance and meteorological conditions. In this paper, we first present the general architecture and operation of an FAI-enabled lighting infrastructure, which relies on environmental sensors and a heterogeneous wireless communication network to connect intelligent, remotely controlled streetlights. Subsequently, we examine large-scale, in-field FAI infrastructures deployed in Vietnam and Italy as case studies, providing substantial measurement data. The paper offers insights into the measured energy consumption of these infrastructures, comparing them to that of conventional light-control strategies used in traditional installations. The measurements demonstrate the superiority of FAI as the most efficient solution. [ABSTRACT FROM AUTHOR]

Published

2024

37. GIS-based fuzzy logic technique for mapping landslide susceptibility analyzing in a coastal soft rock zone.

Author

Wang, Yanli and Nanehkaran, Yaser A.

Subjects

ENERGY infrastructure, INFRASTRUCTURE (Economics), FUZZY logic, EMERGENCY management, LAND cover, LANDSLIDES, LANDSLIDE hazard analysis

Abstract

Coastal landslides pose significant threats to critical infrastructure in energy-dependent regions like the Assaluyeh anticline. To safeguard communities and economic stability, it is crucial to address uncertainties in coastal landslide susceptibility assessments. This necessity extends beyond scientific exploration and requires pioneering fuzzy logic methodologies, to enhance predictive accuracy. The Assaluyeh anticline is in the Persian Gulf's Zagros intercontinental region is of paramount importance, influencing Iran's energy infrastructure. To comprehend coastal landslide risk, our innovative study focuses on the Assaluyeh anticline's coastal areas. We combine 13 conditioning factors, blending traditional geological characteristics with advanced technology, including lithology, land-cover, topographic wetness index (TWI), elevation, and slope angle, using AI-driven modeling to create predictive landslide susceptibility maps. This approach surpasses conventional techniques, offering improved early warning systems and disaster management. Our research's groundbreaking aspect is its forward-looking approach, utilizing fuzzy logic to adapt to real-world conditions by embracing imprecision and uncertainty in data. We integrate historical development data, local knowledge, and forward-thinking fuzzy logic techniques to promote community-driven risk management and resilience in coastal environments. This study envisions the future, revolutionizing coastal landslide assessment and management, inspiring interdisciplinary collaboration, community engagement, and fuzzy logic-driven innovation in coastal disaster risk reduction on a global scale. [ABSTRACT FROM AUTHOR]

Published

2024

38. Impact of urban form on carbon emissions of residents in counties: evidence from Yangtze River Delta, China.

Author

Guo, Ran, Leng, Hong, Yuan, Qing, and Song, Shiyi

Subjects

ENERGY infrastructure, CARBON emissions, STRUCTURAL equation modeling, BUILT environment, PUBLIC transit

Abstract

Urban form is a key factor affecting carbon emissions. Accurately estimating the impact of urban form on the carbon emissions of residents (CER) is an important prerequisite for China to adopt effective low-carbon spatial planning strategies and respond to climate change. However, counties mainly account for China's energy consumption, and the relationship between their urban form and the CER remains unclear, limiting their low-carbon development. Therefore, in this study, the PLS-SEM model and data from 90 counties in the Yangtze River Delta are used to determine the extent and ways that urban form affects the CER. The model considers the impact of both geometric-aspect urban form factors (urban scale, compactness, spatial structure, and urban shape) and built environment-aspect urban form factors (public service facilities, urban greening, road traffic, public transportation, and urban energy infrastructure) on the CER. The results indicate that urban form factors related to the built environment (public service facilities, urban greening, road systems, and municipal infrastructure) have a direct impact on the CER. Geometric-aspect urban form factors (size, compactness, spatial structure, and shape) not only directly affect the CER but also indirectly affect the CER by altering built environment-aspect urban form factors. This study identifies the complex relationship between urban form and the CER, facilitating the coordinated integration of multiple elements and providing a basis for the formulation of low-carbon spatial planning strategies for counties. [ABSTRACT FROM AUTHOR]

Published

2024

39. Planning framework for establishment of hydrogen hubs incorporating the path towards net-zero-driven policies.

Author

Tabandeh, Abbas, Hossain, M.J., Khalilpour, Kaveh, and Huang, Zhenguo

Subjects

*GREEN fuels, *CARBON emissions, *ENERGY infrastructure, *POWER resources, *ELECTRIC power production

Abstract

Hydrogen hubs are emerging as strategic solutions to meet governmental emission reduction targets. A critical aspect of hydrogen hub design involves diversifying end uses, encompassing mobility, backup/storage, heating and cooling provision, onsite electricity generation, and grid energy supply. This paper introduces a comprehensive hydrogen hub model catering to these varied applications. Additionally, a novel multi-stage planning framework is proposed to assist hub operators in making informed decisions regarding the integration of diverse renewable energy sources and infrastructure. This framework addresses varying demands efficiently and economically. Moreover, to align with governmental emission reduction policies leading to net-zero targets, a proactive strategy is suggested. Through zoning for commercial, residential, educational, and healthcare sectors, the Sydney hydrogen hub is envisioned under two scenarios: business-as-usual and towards-net-zero design. Notably, CO 2 emissions are projected to decrease from 18.3 ktonnes in the former to 4.7 ktonnes in the latter scenario. [Display omitted] • Introduces a comprehensive hydrogen hub model catering to varied applications. • Multi-stage planning framework to assist hub operators in making informed decisions. • A proactive strategy aligning with governmental emission reduction/net-zero policy. • Determines optimal sizing, scheduling, and timing for a mix of technologies. • Designing Sydney H 2 hub zoned for commercial, residential, and educational tenants. [ABSTRACT FROM AUTHOR]

Published

2024

40. The water–energy–food–ecosystem nexus in North Africa dryland farming: a multi-criteria analysis of climate-resilient innovations in Morocco.

Author

Kertolli, Emirjona, Prosperi, Paolo, Harbouze, Rachid, Moussadek, Rachid, Echchgadda, Ghizlane, and Belhouchette, Hatem

Subjects

CLIMATE change adaptation, DRY farming, ENERGY infrastructure, FARMS, WATER efficiency

Abstract

Smallholder farmers, who mostly engage in low-value agriculture in the drylands of Northern Africa, were the first to have felt the effects of climate change, with threats to their livelihoods and food security. The increasing costs of agricultural production, poor water and energy infrastructure, loss of agricultural land due to urban expansion, fragmented resource management, and unsustainable management practices all contribute to this vulnerability to climate change. This highlights the urgent need for innovative practices in farming systems. Within the framework of the water–energy–food–ecosystem nexus, this paper explores innovative practices in dryland farming systems, by assessing their impact on water, energy, food, and ecosystem through stakeholder perception. In this work, we aim to present a systems approach for assessing the resilience of the water–energy–food–ecosystem nexus in arid and semiarid regions. By using a multi-criteria analysis (MCA) approach, the study—which focuses on the Fès–Meknès region in Morocco—involves local actors to help researchers identify the key variables in order to assist farmers in their adaptation to climate change. The findings revealed different priorities between farmers and other stakeholders regarding the adoption of agricultural innovations. Farmers prioritize innovations that guarantee higher profitability and more market opportunities, such as integrating olive trees with cereal crops, by highlighting the importance of sustainable income sources. Meanwhile, stakeholders, such as researchers, engineers, government officials, and agribusiness entrepreneurs, prioritize innovations that emphasize high water use efficiency, which is crucial for the resilience of dryland farming areas: for instance, rainwater harvesting or the use of drought-resistant crop varieties that directly address the need for water conservation. But in doing so they are overlooking broader aspects within the water–energy–food–ecosystem nexus. [ABSTRACT FROM AUTHOR]

Published

2024

41. Expedited Proton Relay in Enzyme‐Inspired Cobaloximes Facilitate Organic Transformations.

Author

Panja, Subir, Nandi, Chandan, Guria, Somnath, Pan, Avishek, Das, Chandan, Das, Srewashi, Ghorai, Santanu, Dutta, Arnab, and Maiti, Debabrata

Subjects

*ENERGY infrastructure, *COBALOXIMES, *ORGANIC synthesis, *RENEWABLE energy sources, *CATALYSTS

Abstract

Developing a water‐soluble, oxygen‐tolerant, and acid‐stable synthetic H2 production catalyst is vital for renewable energy infrastructure. To access such an effective catalyst, we strategically incorporated enzyme‐inspired, multicomponent outer coordination sphere elements around the cobaloxime (Cl−Co−X) core with suitable axial coordination (X). Our cobaloximes with axial imidazole or L‐histidine coordination in photocatalytic HAT including the construction of anilines via a non‐canonical cross‐coupling approach is found superior compared to commonly used cobaloxime catalysts. The reversible Co(II)/Co(I) process is influenced by the axial N ligand's nature. Imidazole/L‐histidine with a higher pKa promptly produces H2 upon irradiation, leading to the improved reactivity compared to previously employed axial (di)chloride or pyridine analogue. [ABSTRACT FROM AUTHOR]

Published

2024

42. Political Geographies of Rural Electrification: The Tennessee Valley Energy Region.

Author

Rutenberg, Micah

Subjects

*ENERGY infrastructure, *RURAL geography, *RURAL electrification, *POLITICAL geography, *ARCHIVAL resources

Abstract

The Tennessee Valley Authority (TVA) played a central role in delineating the Tennessee Valley as an energy region. Utilizing mapping as critical practice, this study delves into the spatial history of the region, examining how the construction of an integrated network of hydroelectric dams by the TVA underpinned a regime of techno-environmental development. By bringing together historical cartographic information and archival sources, mapping reveals how environmental, technological, and social infrastructures intertwined to create a complex geopolitical terrain. The emergent geography of the region demonstrates the TVA's belief that techno-environmental region-building could serve as a vehicle for progressive social change and provide a substitute for existing racialized political geographies. However, despite the TVA's public intentions, the benefits of development were unevenly distributed, ultimately perpetuating racial disparities and socioeconomic inequities. As our need to rethink energy infrastructure gains urgency, the map and accompanying text hope to provide reflection on the infrastructural underpinnings of the Tennessee Valley, offering potential insight for contemporary discussion on energy transitions. [ABSTRACT FROM AUTHOR]

Published

2024

43. 中国氢能产业的地方实践及启示.

Author

邓绍林, 刘琦, 许苏予, 胡鹏飞, and 何太碧

Subjects

*DISTRIBUTED power generation, *ENERGY development, *FUEL cell vehicles, *ENERGY infrastructure, *HYDROGEN production, *HYDROGEN as fuel

Abstract

objective The role and development path of China's hydrogen energy industry in achieving the strategic goal of "carbon peaking and carbon neutrality" is explored in-depth. Methods The current state of domestic and international hydrogen energy industry development is analyzed, and based on the perspective of industrial chain stability, the hydrogen energy industry practices in the Sichuan-Chongqing region are examined. Results Provinces and cities are actively planning and implementing hydrogen energy development plans, with a commitment to covering the entire industry chain, emphasizing the integration and innovation of technologies, and promoting the synergistic growth of the industry. In the short term, hydrogen energy applications will focus on the field of fuel cell vehicles, while in the medium to long term, expand to diverse scenarios such as distributed power generation and combined heat and power. Local governments support the hydrogen energy industry through subsidies and incentive policies. Subsidies focus on the promotion of fuel cell vehicles and the construction and operation of hydrogen refueling stations, while incentive policies follow a "reward instead of subsidy" approach. In many regions, local hydrogen energy infrastructure approval methods have already been formulated, relaxing the construction requirements for hydrogen production and refueling projects. Conclusions It is imperative to strengthen policy guarantees and improve the system, establish a cross-departmental coordination mechanism for the hydrogen energy industry, formulate top-level policies at the national level and explore regulatory sandbox systems. Breaking through the bottlenecks in the industry's development, clarifying hydrogen gas safety management and attribute definitions, relaxing land management, and establishing dedicated hydrogen energy management institutions are crucial steps. Embracing an adaptive strategy tailored to local conditions, avoiding policy homogeneity, and strengthening local characteristics and top-level design are essential. Emphasis should be placed on expanding hydrogen energy application scenarios in the transportation sector and using demonstration projects to drive widespread application. Accelerating the construction of a nationwide hydrogen energy infrastructure network is vital to support industry development. [ABSTRACT FROM AUTHOR]

Published

2024

44. Modeling and observations of North Atlantic cyclones: Implications for U.S. Offshore wind energy.

Author

Wang, Jiali, Hendricks, Eric, Rozoff, Christopher M., Churchfield, Matt, Zhu, Longhuan, Feng, Sha, Pringle, William J., Biswas, Mrinal, Haupt, Sue Ellen, Deskos, Georgios, Jung, Chunyong, Xue, Pengfei, Berg, Larry K., Bryan, George, Kosovic, Branko, and Kotamarthi, Rao

Subjects

*EXTREME weather, *WIND power, *ENERGY infrastructure, *WEATHER, *WIND turbines, *CYCLONES, *TROPICAL cyclones

Abstract

To meet the Biden-Harris administration's goal of deploying 30 GW of offshore wind power by 2030 and 110 GW by 2050, expansion of wind energy into U.S. territorial waters prone to tropical cyclones (TCs) and extratropical cyclones (ETCs) is essential. This requires a deeper understanding of cyclone-related risks and the development of robust, resilient offshore wind energy systems. This paper provides a comprehensive review of state-of-the-science measurement and modeling capabilities for studying TCs and ETCs, and their impacts across various spatial and temporal scales. We explore measurement capabilities for environments influenced by TCs and ETCs, including near-surface and vertical profiles of critical variables that characterize these cyclones. The capabilities and limitations of Earth system and mesoscale models are assessed for their effectiveness in capturing atmosphere–ocean–wave interactions that influence TC/ETC-induced risks under a changing climate. Additionally, we discuss microscale modeling capabilities designed to bridge scale gaps from the weather scale (a few kilometers) to the turbine scale (dozens to a few meters). We also review machine learning (ML)-based, data-driven models for simulating TC/ETC events at both weather and wind turbine scales. Special attention is given to extreme metocean conditions like extreme wind gusts, rapid wind direction changes, and high waves, which pose threats to offshore wind energy infrastructure. Finally, the paper outlines the research challenges and future directions needed to enhance the resilience and design of next-generation offshore wind turbines against extreme weather conditions. [ABSTRACT FROM AUTHOR]

Published

2024

45. The politics of percentage: Informating justice in the US clean energy rush.

Author

Smith, Jessica M.

Subjects

*INFORMATION technology auditing, *ENERGY infrastructure, *GOVERNMENT agencies, *CLEAN energy, *ENERGY research

Abstract

Within days of taking office in January 2021, President Biden signed an executive order establishing the Justice40 initiative, which directed federal agencies to ensure that at least 40% of the benefits of federal investments flow to historically marginalized communities. This article traces how Justice40, as interpreted and enacted by government bureaucrats, academics, industry researchers, and activists, intervenes in the governance of the energy transition it seeks to put into motion. Drawing from ongoing critical participation in energy research and development arenas and taking inspiration from Kim Fortun's notion of the "informating of environmentalism," this article argues that Justice40 can be understood as an attempt to informate justice, rendering it into problems that can be understood, manipulated, and audited through information systems. Scrambling to manage their accountabilities to the executive branch, Congress, and the American taxpayers footing the bill for massive infrastructure investments, Department of Energy programs are rolling out intricate systems of quantification, whose objectives of commensurability obscure local conceptions and prioritizations of justice. While Justice40 articulates lofty goals of energy transition enhancing the wellbeing of people who have otherwise been harmed by or excluded from the country's existing energy infrastructure, its everyday practice has the ironic effect of undermining both epistemic and procedural justice. [ABSTRACT FROM AUTHOR]

Published

2024

46. Impact of Artificial Intelligence on the Planning and Operation of Distributed Energy Systems in Smart Grids.

Author

Arévalo, Paul and Jurado, Francisco

Subjects

*ARTIFICIAL intelligence, *ENERGY infrastructure, *ELECTRIC power distribution grids, *MACHINE learning, *INDUSTRIAL efficiency, *COGNITIVE computing

Abstract

This review paper thoroughly explores the impact of artificial intelligence on the planning and operation of distributed energy systems in smart grids. With the rapid advancement of artificial intelligence techniques such as machine learning, optimization, and cognitive computing, new opportunities are emerging to enhance the efficiency and reliability of electrical grids. From demand and generation prediction to energy flow optimization and load management, artificial intelligence is playing a pivotal role in the transformation of energy infrastructure. This paper delves deeply into the latest advancements in specific artificial intelligence applications within the context of distributed energy systems, including the coordination of distributed energy resources, the integration of intermittent renewable energies, and the enhancement of demand response. Furthermore, it discusses the technical, economic, and regulatory challenges associated with the implementation of artificial intelligence-based solutions, as well as the ethical considerations related to automation and autonomous decision-making in the energy sector. This comprehensive analysis provides a detailed insight into how artificial intelligence is reshaping the planning and operation of smart grids and highlights future research and development areas that are crucial for achieving a more efficient, sustainable, and resilient electrical system. [ABSTRACT FROM AUTHOR]

Published

2024

47. Sustainable Biodiesel Production via Biogenic Catalyzed Transesterification of Baobab Oil Methyl Ester and Optimization Process.

Author

Etim, Anietie and Musonge, Paul

Subjects

*RENEWABLE energy sources, *SUSTAINABILITY, *ENERGY infrastructure, *HETEROGENEOUS catalysts, *FRUIT skins, *BIOGENIC amines, *BANANAS

Abstract

Biomass diesel is one of the sustainable and renewable sources of energy envisaged to hold a prominent position in the world energy infrastructure. In this study, biodiesel was produced from baobab seed oil by transesterification using biogenic heterogeneous catalyst, derived from mixed wastes of white chicken eggshells and banana fruit peels. The production process was statistically analyzed using Box-Behnken Design-Response Surface Methodology (BBD-RSM). The influential transesterification reaction parameters investigated with their ranges include reaction time (40–80 min), molar ratio of oil to methanol (1:9–1:15) and catalyst weight (3–5 wt%). The nano-catalyst (CaO-BFP-850 NPs) was prepared by calcination at high temperature of 850 °C for 4 h, and its properties were found to contain majorly the basic elements of Ca and K when investigated with analytical instruments such as SEM, EDS, DSC-TGA, FT-IR, and XRD. The regeneration test of the CaO-BFP-850 NPs conducted showed it could be reused for more than four cycles with less catalytic efficiency reduction. The ideal conditions instituted by BBD-RSM was 75 min of reaction time, 12.8:1 molar ratio of oil to methanol, and 4.08 wt% CaO-BFP-850 at 65 °C and 650 rpm constant temperature and agitation speed respectively, with the validated biodiesel yield of 96.70 wt%. The assessment of the quality of the biodiesel produced showed compliance with the standard specifications of ASTM D6751, EN 14241, and SANS 833. [ABSTRACT FROM AUTHOR]

Published

2024

48. Development of a Cost-Driven, Real-Time Management Strategy for e-Mobility Hubs Including Islanded Operation.

Author

Leal, Wagner Coelho, Godinho, Marcelo Oliveira, Kraemer, Rodrigo Antonio Sbardeloto, Cardoso, Beatriz Batista, Neto, Durval da Silva, and Dobes, Mauricio Ibarra

Subjects

*BATTERY storage plants, *ELECTRIC vehicle charging stations, *ENERGY infrastructure, *ELECTRIC power distribution grids, *PEAK load

Abstract

The installation of electric vehicle supply equipment (EVSE) increases demand and peak loads, potentially straining existing energy distribution infrastructure. Dispersed and inadequately planned placement of charging points (CPs) can disrupt the electrical grid, surpass contracted demand thresholds, and require infrastructure upgrades, thereby incurring unfeasible costs for Distribution System Operators (DSOs). In this context, it is necessary to recognize the role of business models in enabling effective electrification of the transportation sector. In response to these challenges, this paper introduces a novel e-mobility hub management strategy, tailored for implementation in the Brazilian context. The proposed strategy revolves around a microgrid configuration encompassing dispatchable and photovoltaic generation, a battery energy storage system (BESS), EVSE infrastructure, and local loads. Moreover, this centralized controller facilitates the implementation of dynamic pricing and demand-response mechanisms, integral to business models seeking to integrate EVSE into the distribution grid. To validate the efficacy of the proposed solution, hardware-in-the-loop (HIL) simulations of the microgrid system are conducted. These simulations, incorporating the centralized controller, serve as a tool for assessing system performance and viability before on-site equipment deployment. Finally, this paper concludes with the insights gleaned from test analysis and its discussion through a selection of the most expressive scenarios, including islanded and connected operation modes. [ABSTRACT FROM AUTHOR]

Published

2024

49. 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

50. Renewable, Flexible, and Storage Capacities: Friends or Foes?

Author

Peng, Xiaoshan, Wu, Owen Q., and Souza, Gilvan C.

Subjects

STOCHASTIC control theory, BUSINESS schools, ENERGY infrastructure, INDUSTRIAL capacity, ELECTRIC utilities

Abstract

Problem definition: More than 99% of the new power generation capacity to be installed in the United States from 2023 to 2050 will be powered by wind, solar, and natural gas. Additionally, large-scale battery systems are planned to support power systems. It is paramount for policymakers and electric utilities to deepen the understanding of the operational and investment relations among renewable, flexible (natural gas-powered), and storage capacities. In this paper, we optimize both the joint operations and investment mix of these three types of resources, examining whether they act as investment substitutes or complements. Methodology/results: Using stochastic control theory, we identify and prove the structure of the optimal storage control policy, from which we determine various pairs of charging and discharging operations. We find that whether storage complements or substitutes other resources hinges on the operational pairs involved and whether executing these pairs is constrained by charging or discharging. Through extensive numerical analysis using data from a Florida utility, government agencies, and industry reports, we demonstrate how storage operations drive the investment relations among renewable, flexible, and storage capacities. Managerial implications: Storage and renewables substitute each other in meeting peak demand; storage complements renewables by storing surplus renewable output; renewables complement storage by compressing peak periods, facilitating peak shaving and displacement of flexible capacity. These substitution and complementary effects often coexist, and the dominant effect can alternate as costs change. A thorough understanding of these relations at both operational and investment levels empowers decision makers to optimize energy infrastructure investments and operations, thereby unlocking their full potential. Funding: This research was supported in part by Lilly Endowment, Inc., through its support for the Indiana University Pervasive Technology Institute. This research was also supported by Kelley School of Business, Indiana University, and Haslam College of Business, University of Tennessee. O. Q. Wu thanks Grant Thornton for their generous support. Supplemental Material: The online appendix is available at https://doi.org/10.1287/msom.2023.0068. [ABSTRACT FROM AUTHOR]

Published

2024