Vol. 4 No. 2 (2026): In Progress

Open Access

Article

Article ID: 4141

Overview of Integrated Packaging Single-Cell Technology for Hydrogen Proton Exchange Membrane Fuel Cells
by Ji Pu, Qianya Xie, Kai Li, Zhanfeng Wang, Chunyu Li, Jun Li, Ziliang Zhao

Energy Storage and Conversion, Vol.4, No.2, 2026;

DOI: https://doi.org/10.59400/esc4141

Proton exchange membrane fuel cells (PEMFCs) are gaining significant traction as a promising clean energy technology due to their high efficiency and low-temperature operation. Especially, the integrated single-cell technology is beginning to become the future trend in system applications. This paper provides a systematic review of the technological innovations and design optimizations in membrane electrodes, bipolar plates, and overall packaging for single-cell. It critically analyzes the advantages and limitations of current single-cell solutions from the perspectives of cost, performance, and durability. It provides theoretical support for the engineering application and large-scale production of PEMFC single-cell technology.They shall not contain displayed mathematical equations, numbered reference citations, nor footnotes. They should include three or four different keywords or phrases, as this will help readers to find it. It is important to avoid over-repetition of such phrases as this can result in a page being rejected by search engines. Ensure that your abstract reads well and is grammatically correct.

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Open Access

Article

Article ID: 4074

Performance comparison of PI and AI-based controllers for solar PV-fed fast electric vehicle battery charging systems
by Apoorva Srivastava, Vikas Yadav, Vinit Yadav, Tarun Nayyar, Shailesh Kumar Yadav, Ayush Asthana

Energy Storage and Conversion, Vol.4, No.2, 2026;

DOI: https://doi.org/10.59400/esc4074

The rapid growth of electric vehicles (EVs) has created a strong demand for efficient and fast charging solutions. However, conventional charging methods are time-consuming and place significant stress on the power grid when deployed on large scale. To address these challenges, this study proposes a standalone solar photovoltaic (PV)-based DC microgrid for fast EV charging. The system is designed to regulate charging using a DC-DC boost converter controlled by two strategies: a conventional Proportional-Integral (PI) controller and an Artificial Neural Network (ANN)-based controller. A detailed simulation model is developed in MATLAB/Simulink, including PV system parameters, converter specifications, and a lithium-ion battery modeled using a Thevenin equivalent circuit. The ANN controller is trained using real-time operating conditions such as irradiance, temperature, and state of charge (SoC). Performance is evaluated based on transient response, overshoot, settling time, steady-state error, and total harmonic distortion (THD). Results show that the ANN controller significantly improves system performance. Voltage overshoot is reduced from 10% to 2%, current overshoot from 20% to 4%, and THD from 6.8% to 2.1%. Additionally, the settling time is improved by approximately 57% compared to the PI controller. These findings demonstrate that AI-based control strategies provide a more efficient, stable, and reliable solution for renewable energy-based EV charging systems. The ANN controller reduced voltage overshoot from 10% to 2%, current overshoot from 20% to 4%, and THD from 6.8% to 2.1%, while improving settling time by up to 57%.

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Open Access

Article

Article ID: 4190

Resource transparency and energy transition: The role of SEC oil and gas reserve reporting in future energy systems
by Guoquan Fan, Mengyue Guo, Yun Wang

Energy Storage and Conversion, Vol.4, No.2, 2026;

DOI: https://doi.org/10.59400/esc4190

The world energy paradigm shift is changing the manner in which oil and gas resources are rated, regulated, and reported. The review studies the purpose of the U.S. Securities and Exchange Commission (SEC) oil and gas reserve reporting as one of the main transparency tools of resources and evaluates its applicability in future energy systems. Conventionally, the SEC reserve reporting has minimized information asymmetry in the capital markets through standardization of disclosure of economically viable production of hydrocarbon reserves and therefore, facilitated the protection of investors, asset-pricing, and corporate responsibility. Nonetheless, the article states that the traditional reasoning behind reserve reporting is being more and more questioned by decarbonization, financial risk associated with climate, carbon limits, and shifting capital allocation trends. Even with reported reserves, technical, and commercial producibility may remain, but innovation does not entirely account for transition-related risk conditions like stranded asset risk, fossil entrapment, emissions exposure, and demand decline in low-carbon systems. With a combination of the views of reserve classification, securities regulation, energy governance, and transition finance, this review indicates that SEC reserve reporting is still needed but not sufficient as a standalone transparency measure. The article identifies the necessity to revise the reserve disclosure by incorporating more deeply into climate-related reporting, scenario-based analysis, and better addressing uncertainty. It comes to a conclusion that reserve reporting needs to be redesigned as a fossil asset-centric accounting system into one that is more dispositionally inclusive of transition to control resource value in the decarbonization of energy systems.

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Open Access

Article

Article ID: 4186

Modeling and optimization of a grid-connected PV–wind–fuel cell hybrid system with hydrogen storage
by Youssef El Baqqal, Mohammed Ferfra, Souleymane Kientega

Energy Storage and Conversion, Vol.4, No.2, 2026;

DOI: https://doi.org/10.59400/esc4186

This paper presents a comprehensive techno-economic and environmental assessment of a grid-connected hybrid renewable energy system (HRES) integrating photovoltaic (PV), wind turbine (WT), and fuel cell (FC) technologies for a case study in Dakhla, Morocco. A detailed modeling framework is developed, including renewable generation, electrolyzer operation, hydrogen storage, and fuel cell conversion, combined with an energy management strategy to coordinate power flows between system components and the utility grid. The system design is formulated as a constrained optimization problem aiming to minimize the total annual cost while incorporating reliability and grid stability requirements through a penalty-based approach. The optimization is performed using a particle swarm optimization (PSO) algorithm to evaluate three system configurations: PV–WT–FC, WT–FC, and PV–FC. The results show that the PV–WT–FC configuration provides the best overall performance, achieving a total annual cost of 186,957 USD, a levelized cost of energy (LCOE) of 0.1472 USD/kWh, and a high renewable energy fraction (REF) of 88.32%. This configuration also ensures excellent reliability (LPSP = 0%) and stable grid operation. In contrast, the WT–FC configuration achieves a lower LCOE of 0.1164 USD/kWh when considering component costs alone; however, it results in significant grid instability, leading to a high penalty cost of 700,588 USD and reduced overall feasibility. Similarly, the PV–FC configuration shows a higher total annual cost (255,425 USD) and lower renewable penetration (60%), making it less competitive. These findings highlight the importance of integrating grid stability and reliability constraints within the optimization framework. The proposed approach effectively identifies balanced system configurations that ensure cost efficiency, high renewable penetration, and stable operation, confirming the robustness and practical applicability of the PV–WT–FC system for sustainable energy deployment.

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Editor-in-Chief

Prof. Xiaohu Yang

Xi'an Jiaotong University, China

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3029-2778

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Academic Publishing insists on taking academic exchange and publication as the main line, carrying out comprehensive management based on science and technology, and fully exploring excellent international publishing resources. Within 5 years, it will form a strategic framework and scale with science (S), technology (T), medicine (M), education (E), and humanities and arts (H) as the main publishing fields. Academic Publishing is headquartered in Singapore and based in Malaysia, with the United States and China providing the main scientific and academic resources. At the same time, it has established long-term good cooperative relations with other publishing companies, scientific research communities, and academic organizations in more than a dozen countries and regions. Academic Publishing uses English and Chinese as its main publishing languages, mainly publishing books, journals, and conference papers in print and online. The vast majority of publications follow the international open access policy, providing stable and long-term quality and professional publications. With the joint efforts of the expert team and our professional editorial team, our publications will gradually be indexed by international databases in stages to provide convenient and professional retrieval for various scholars. At the same time, manuscripts we accept will be subject to the peer review principle, and cutting-edge and innovative research articles will be preferentially accepted for peer reference and discussion. All kinds of our publications are welcome for peer to contribute, access, and download.

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Volume Arrangement

2026

2025

2024

2023

Featured Articles

Nitrided Copper-Iron Composite Oxides Derived from Layered Double Hydroxides for Enhanced Carbon Dioxide Electroreduction to Methane and Formic Acid

The reduction of carbon dioxide to valuable chemical products is a promising solution to address carbon balance and energy issues. Herein, amorphous nitrided copper-iron oxides are prepared by gas-phase nitriding of Cu Fe-layered double hydroxide precursor s with urea as nitrogen source. Amorphous materials are more likely to generate defect vacancies during the reaction process, and these vacancies can function as active sites for catalytic reactions. Therefore, the obtained materials show high activity for CO 2 electroreduction to methane and formic acid, achieving a total Faraday efficiency of 74.7% at −0.7 V vs RHE and exhibiting a continuous 10 h durability in the H-cell. The uniformly distributed Cu + sites act as active sites by losing electrons to activate CO 2 . During the CO 2 electroreduction , CO 2 is converted to *COOH via proton-electron coupling, *COOH combines directly with a proton in solution to produce the HCOOH product, and the other part of *COOH undergoes a protonated dehydration process to form the *CHO intermediate which dehydrates again to form CH 4 . This study provides a new approach for designing CO 2 electroreduction catalysts.

AlZnO magnetron sputtered thin film for photovoltaic application

Aluminum zinc oxide (AZO) is a nontoxic and a low-cost material that finds application as a transparent conducting electrode in photovoltaic devices. In this study the (direct current) DC magnetron sputtering of AZO films is carried out at different deposition times of 5, 10, 15, 20 and 25 min’s at room temperature and it’s structural, optical, electrical and morphological properties are studied for its use as a front contact for thin film solar cell application. The structural study suggests that the preferred orientation of grains along (002) plane having hexagonal structure and the optical and the electrical studies suggest that the films show an average transmission of 70% and a resistivity of the order of 10 -4 Ωcm. On the other hand, the scanning electron microscopy (SEM) images suggest the formation of packed grains having a homogeneous surface. Moreover in order to study the optoelectronic properties of prepared samples, the electronic and optical calculations of the AZO are performed by the first-principles calculations using density functional theory (DFT).

Investigation of self-excited induction generator for supporting domestic loads and its extension to a microgrid

This study provides a technical and financial analysis for the incorporation of a microgrid structure with a wind energy conversion system for producing electricity. This study’s primary aim is to provide solutions for issues that arise when isolated induction generators are employed with microgrids. A closed-loop smart electronic load controller is used to regulate the loads in the system that are supplied by the generation. A switched variable capacitor bank is used to supply reactive power initially during a voltage dip at varying winds and loads to sustain the voltage profile. Additionally, a simple voltage control loop-based controller for the generator side converter maintains the voltage at a steady level. Using HOMER software, an economic study of the suggested wind-based microgrid structure is also presented. A laboratory experimental setup is used to support the MATLAB/Simulink study of the proposed method and its control. The findings back the feasibility of implementing the suggested plan in grid-isolated regions for supplying critical loads.

Research progress on ZnO/MoS₂/rGO ternary photocatalysts

Energy shortage and environmental pollution have become one of the important global issues, and semiconductor photocatalytic technology is considered as one of the effective means to solve these problems. As a new and efficient green material, ZnO has attracted wide attention. ZnO is widely used in the field of photocatalysis due to its non-toxicity, low cost, environmental friendliness, adjustable band gap, high electron density, and chemical stability. However, the recombination of photogenerated charge carriers in ZnO hinders its practical application and lowers the utilization efficiency of visible light. On the other hand, molybdenum disulfide/reduced graphene oxide (MoS₂ /rGO), as a binary non-precious metal co-catalyst, has a larger specific surface area, suitable band gap width, and visible light response capability compared to single-phase graphene co-catalyst. Therefore, introducing MoS₂ /rGO co-catalyst into the ZnO system can provide more active sites, reduce the probability of photogenerated charge carrier recombination, and improve the utilization efficiency of visible light. In this review, we summarize the hydrothermal synthesis methods for preparing this highly demanded nanocomposite material, including one-step and stepwise methods. Subsequently, we elaborate on the mechanism of enhancing light absorption and achieving efficient electron-hole separation behavior in the ternary system heterojunction structure during the photocatalytic process. Due to its significant advantages, this ternary system heterojunction structure has been widely applied in the field of photocatalysis, including applications such as pollutant degradation, sterilization, and water splitting.

Wind power forecasting technologies: A review

This study addresses the critical role of wind power forecasting in ensuring stable and reliable power system operations. Wind Power Forecasting is critical for the efficient operation of plant, time scheduling, and it’s balancing of power generation with grid integration systems. Due to its dependency on dynamic climatic conditions and associated factors, accurate wind power forecasting is challenging. The research delves into various aspects, including input data, input selection techniques, data pre-processing, and forecasting methods, with the aim of motivating researchers to design highly efficient online/offline models on weather-based data. The overarching goal is to enhance the reliability and stability of power systems while optimizing energy resource utilization. The analysis reveals that hybrid models offer more accurate results, highlighting their significance in the current era. This study investigates different Wind Power Forecasting (WPF) models from existing literature, focusing on input variables, time horizons, climatic conditions, pre-processing techniques, and sample sizes that affect model accuracy. It covers statistical models like ARMA and ARIMA, along with AI techniques including Deep Learning (DL), Machine Learning (ML), and neural networks, to estimate wind power.

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