Energies

20 pages, 4281 KB

Open AccessArticle

Sustainable Energy Transition Challenges: Limits to the Integration of Core Energy System Components—Reliability Perspective

by Wojciech Uchman, Michał Jurczyk, Jakub Ochmann and Leszek Remiorz

Energies 2026, 19(5), 1232; https://doi.org/10.3390/en19051232 (registering DOI) - 1 Mar 2026

Abstract

The rapid expansion of non-dispatchable renewable energy sources (VRE) and energy storage technologies raises fundamental questions regarding the structural limits of their integration into power systems. This study aims to determine, from a structural reliability perspective, the adequate penetration limits of VRE in [...] Read more.

The rapid expansion of non-dispatchable renewable energy sources (VRE) and energy storage technologies raises fundamental questions regarding the structural limits of their integration into power systems. This study aims to determine, from a structural reliability perspective, the adequate penetration limits of VRE in a synthetic power system and to assess how firm generation share, storage capacity, and wind–solar technology mix influence system reliability. A synthetic annual load profile reflecting current European conditions was developed from real-life data, along with a set of indicators enabling the consistent characterization and comparison of demand profiles. A deterministic system model was then applied to evaluate power and energy balance under parametrized configurations of firm generation, variable renewable capacity, and storage. Reliability performance was assessed using proposed indices (RIs) covering, among others, capacity margin, loss of load duration, frequency, etc. The results demonstrate the existence of structural penetration limits of non-dispatchable renewables that cannot be eliminated solely by increasing storage capacity, but only shifted. The technological composition of VRE is shown to be as important as total penetration: higher wind shares improve seasonal alignment and reduce reliability risks, whereas PV-dominated configurations increase curtailment and storage dependence. Moderate overcapacity, combined with a balanced wind–solar mix, provides the most favorable structural reliability conditions. These findings underscore the importance of incorporating reliability-based structural constraints into long-term energy transition planning, beyond purely economic optimization criteria. Full article

(This article belongs to the Special Issue Green Innovation and Sustainable Energy Transition: Opportunities and Challenges)

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37 pages, 20396 KB

Open AccessArticle

Comparative Analysis of Peer-to-Peer Energy Trading with Multi-Objective Optimization in Rooftop Photovoltaics-Powered Residential Community

by Mohammad Zeyad, Berk Celik, Timothy M. Hansen, Fabrice Locment and Manuela Sechilariu

Energies 2026, 19(5), 1231; https://doi.org/10.3390/en19051231 (registering DOI) - 1 Mar 2026

Abstract

The rapid growth of distributed solar energy, such as rooftop photovoltaics (PVs), has revolutionized conventional power systems into more distributed networks, enabling end-users to engage in and trade within the energy market. Maximizing the benefits of rooftop PV panels for residential end-users, including [...] Read more.

The rapid growth of distributed solar energy, such as rooftop photovoltaics (PVs), has revolutionized conventional power systems into more distributed networks, enabling end-users to engage in and trade within the energy market. Maximizing the benefits of rooftop PV panels for residential end-users, including increased renewable energy use and reduced reliance on the utility grid, remains an essential challenge in conventional centralized markets. Moreover, reducing energy consumption may lead to increased peak demand, decreased self-consumption, reduced system flexibility, and reduced grid stability. Therefore, this study presents a transactive energy market framework that integrates home energy management systems (HEMSs) with multi-objective optimization and an aggregator-based, distributed peer-to-peer (P2P) trading strategy to increase rooftop PV utilization and reduce grid dependency within an intra-residential community. The HEMS is structured to integrate rooftop PV production, battery energy storage systems, and smart appliances to offer flexibility through demand response programs in balancing supply and demand by scheduling appliances during periods of rooftop PV production and lower grid prices. Multi-objective (i.e., minimizing energy consumption cost and peak load) optimization problems are solved using the Non-Dominated Sorting Genetic Algorithm-II (NSGA-II) by achieving a Pareto-optimal solution. To validate the reliability and optimality of the NSGA-II results, the same problem formulation is solved using a mixed-integer linear programming approach. Moreover, a Strategic Double Auction with Dynamic Pricing (SDA-DP) strategy is proposed to support P2P trading among consumers and prosumers and thereafter compared with a rule-based zero-intelligence strategy with market-matching rules to analyze the trading performance of the proposed SDA-DP. The results of this comparative analysis (for 10 households, year-long simulation with 15 min time resolution) demonstrate that compared to the baseline case, integrating NSGA-II optimization with SDA-DP trading significantly enhances rooftop PV utilization by 35.11%, reduces grid dependency by 34.04%, and reduces electricity consumption costs by 30.53%, with savings of €1.93 to €6.67 for a single day after participating in the proposed P2P market. Full article

(This article belongs to the Special Issue New Trends in Photovoltaic Power System)

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48 pages, 2095 KB

Open AccessReview

Research Progress on Thermophysical Properties and Convection Heat Transfer Enhancement of Molten Salts

by Taotao Huang, Xing Huang, Xiaoming Fang, Ziye Ling and Zhengguo Zhang

Energies 2026, 19(5), 1230; https://doi.org/10.3390/en19051230 (registering DOI) - 1 Mar 2026

Abstract

Molten salts are essential heat transfer and storage media in high-temperature applications such as Concentrated Solar Power (CSP), owing to their high boiling points, low vapor pressures, and excellent thermal stability. The overall performance of such systems is largely governed by the convective [...] Read more.

Molten salts are essential heat transfer and storage media in high-temperature applications such as Concentrated Solar Power (CSP), owing to their high boiling points, low vapor pressures, and excellent thermal stability. The overall performance of such systems is largely governed by the convective heat transfer characteristics of molten salt fluids. This review systematically synthesizes recent advances over the past five years in enhancing the thermophysical properties and convective heat transfer of molten salts, focusing on two primary strategies: improving the intrinsic properties of molten salts through nanoparticle doping, and optimizing the structural design of heat exchangers. The enhancement of thermophysical properties is mainly achieved by preparing molten salt-based nanofluids. Dispersing low concentrations (typically 0.1–1.0 wt.%) of nanoparticles such as SiO₂, Al₂O₃, and carbon nanotubes (CNTs) can yield significant improvements—thermal conductivity increases of up to ~100% (e.g., 0.5 wt% SiO₂ in NaNO₃-KNO₃) and specific heat capacity enhancements of 20–30% (e.g., 1.0 wt% Al₂O₃ in carbonates). Multiscale simulations, particularly molecular dynamics (MD), have revealed key enhancement mechanisms, including the formation of ordered ionic layers on nanoparticle surfaces that create efficient nanoscale heat conduction pathways, and the modulation of ion–ion interactions. Concurrently, significant heat transfer enhancement can be achieved through structural optimization. Single-method technologies, such as enhanced heat transfer tubes, improve performance by disrupting the thermal boundary layer. For instance, spirally grooved tubes can increase the Nusselt number (Nu) by 19% for Re > 25,000, while twisted tape inserts can enhance laminar flow heat transfer by up to 8.6 times. Composite strategies that couple nanofluids with enhanced geometries demonstrate superior overall performance, with Performance Evaluation Criterion (PEC) values reaching up to 1.48 for converging–diverging tubes with SiO₂ nanofluids and 1.21 for trefoil-shaped U-tubes with Cu-based nanofluids. Compact heat exchangers (CHEs) offer high efficiency, achieving PEC values of 1.07–1.4 in optimized designs, but face challenges such as clogging risks in large-scale applications. Future research directions include the development of advanced composite molten salts, the application of artificial intelligence and multiscale simulations for mechanistic analysis and design optimization, the fabrication of novel heat exchanger structures via additive manufacturing, and cross-disciplinary integration for full-chain system optimization. These concerted efforts are essential for realizing efficient, cost-effective, and reliable molten salt-based energy systems. Full article

(This article belongs to the Special Issue Advancements in Energy Storage Technologies)

16 pages, 1897 KB

Open AccessArticle

Frequency Dependence of Air Breakdown and Investigation of Its Electro-Optical Characteristics

by Ya Wang, Bin Liu, Wenbin Zhao, Xinzhe Yu, Jiangang Bi and Chao Ding

Energies 2026, 19(5), 1229; https://doi.org/10.3390/en19051229 (registering DOI) - 1 Mar 2026

Abstract

With the expanding frequency range of power equipment, understanding the frequency-dependent insulation performance of air becomes crucial. To address this, this paper establishes an integrated electrical–optical measurement platform for air breakdown to study the variation patterns of electrical and spectral characteristics of air [...] Read more.

With the expanding frequency range of power equipment, understanding the frequency-dependent insulation performance of air becomes crucial. To address this, this paper establishes an integrated electrical–optical measurement platform for air breakdown to study the variation patterns of electrical and spectral characteristics of air breakdown at different frequencies. The effects and underlying mechanisms of different frequencies (20 Hz, 50 Hz, and 1 kHz) on the breakdown voltage are explored. Experimental results indicate that the air breakdown voltage increases with frequency as follows: from 17.7 kV at 20 Hz to 18.0 kV at 50 Hz (1.7% increase) and further to 18.9 kV at 1 kHz (5.0% increase from 50 Hz), representing a total increase of 6.8% across the 20 Hz to 1 kHz range. Regarding spectral characteristics, the spectral line intensity enhances with an increase in frequency. Compared to 20 Hz and 50 Hz, the spectral lines of nitrogen ions and oxygen ions become distinctly visible at 1 kHz, the Stark broadening phenomenon intensifies, and transitions from higher vibrational energy levels are enhanced relative to those from lower levels. Analysis via the Boltzmann plot method reveals a negative correlation between electron temperature (Te) and frequency, while the ionization degree (η) shows a positive correlation. Concurrently, the electron drift velocity (v_d) increases with frequency, whereas the mean free path decreases (λ). Based on the parallel-plate capacitor model, the air breakdown under the experimental conditions of this study is dominated by collision ionization. As frequency increases, dielectric recovery slows down, and the memory effect strengthens. The interplay between these two competing factors leads to an increase in breakdown voltage with an increase in frequency within the 20 Hz to 1 kHz range. The findings of this study demonstrate that air breakdown exhibits significant frequency dependence, and its breakdown voltage shows statistical distribution characteristics (Weibull parameters) that vary with frequency. This article provides a reference basis for the design of sinusoidal air insulation in the 20 Hz to 1 kHz frequency range. Full article

(This article belongs to the Section F6: High Voltage)

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20 pages, 1166 KB

Open AccessArticle

Optimal Bidding Strategy for Horizontal Pumped Storage-Wind-Solar Hybrid Systems in Day-Ahead Markets: A Hybrid Uncertainty Modeling Approach

by Zhiyu Zheng, Lei Yang, Dalong Dong, Congyue Qian, Rihui An, Xiangzhen Wang and Chao Wang

Energies 2026, 19(5), 1228; https://doi.org/10.3390/en19051228 (registering DOI) - 1 Mar 2026

Abstract

This paper addresses the multi-source uncertainties faced by horizontal pumped storage-wind-solar (HWS) hybrid systems in the day-ahead market by proposing a hybrid stochastic-robust optimization model for bidding and scheduling. The model employs a scenario-based method to capture the randomness of wind and solar [...] Read more.

This paper addresses the multi-source uncertainties faced by horizontal pumped storage-wind-solar (HWS) hybrid systems in the day-ahead market by proposing a hybrid stochastic-robust optimization model for bidding and scheduling. The model employs a scenario-based method to capture the randomness of wind and solar power output, utilizes Information Gap Decision Theory (IGDT) to handle the epistemic uncertainty in runoff inflow forecasting, and constructs a price-acceptance probability function based on historical statistics to characterize the market mechanism. By maximizing the system’s tolerable uncertainty immunity gap, the model co-optimizes generation schedules, pumped-storage operation, and market bids while ensuring that revenue under the worst-case inflow scenario does not fall below a predefined threshold. Simulation results based on an actual project in Hubei Province demonstrate that the proposed method effectively balances revenue and risk, showing significant advantages in both revenue stability and robustness compared to the system before retrofitting. This study provides practical decision-making support for hybrid systems with horizontal pumped storage participating in electricity markets. Full article

(This article belongs to the Special Issue Optimal Schedule of Hydropower and New Energy Power Systems)

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15 pages, 4018 KB

Open AccessArticle

Verification of the Filtration Efficiency of a Group of Single-Tuned Passive Harmonic Filters

by Ryszard Klempka and Chamberlin Stéphane Azebaze Mboving

Energies 2026, 19(5), 1227; https://doi.org/10.3390/en19051227 (registering DOI) - 1 Mar 2026

Abstract

Currently, the installation of distributed energy sources is growing rapidly, especially renewable sources, for which the goal is to increase energy self-sufficiency across certain parts of the distribution network. The optimization of electricity production and distribution is key to achieving this goal. To [...] Read more.

Currently, the installation of distributed energy sources is growing rapidly, especially renewable sources, for which the goal is to increase energy self-sufficiency across certain parts of the distribution network. The optimization of electricity production and distribution is key to achieving this goal. To optimize the energy distribution system, filters are increasingly being installed to compensate for reactive power, mitigate voltage unbalance, and reduce higher harmonics in small parts of the electrical system and even for single loads. This article verifies the filtration efficiency of a group of single-tuned passive harmonic filters. Two groups are investigated: a group of real filters and a designed optimal filter. This investigation was performed in three important parts: Firstly, measurements of the power quality parameters were taken in a real system (laboratory measurements). Secondly, the configuration of the optimal filter group was calculated, assuming the same reactive power and tuning frequencies as in a real system. In the group structure of such filters, the biggest problem is properly sharing the total reactive power between the filter branches. Thirdly, both filter structures (real and optimal) are compared based on harmonic reduction indexes and the filter efficiency index. Full article

(This article belongs to the Special Issue The Impact of Distributed Energy Resources (DERs) on Supply Network and Energy Market)

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28 pages, 982 KB

Open AccessArticle

Mitigating Disruptions in the Distribution Centre for the Australian Household Hydrogen Supply Chain

by Pranto Chakrabarty, Sanjoy Kumar Paul, Andrea Trianni and Suvash C. Saha

Energies 2026, 19(5), 1226; https://doi.org/10.3390/en19051226 (registering DOI) - 28 Feb 2026

Abstract

Australia is committed to achieving net-zero emissions by 2050, a goal that may require a major transformation of the household energy sector. Hydrogen can, however, be deployed as a complementary energy source to electricity by displacing natural gas. But the potential for hydrogen [...] Read more.

Australia is committed to achieving net-zero emissions by 2050, a goal that may require a major transformation of the household energy sector. Hydrogen can, however, be deployed as a complementary energy source to electricity by displacing natural gas. But the potential for hydrogen to make this transition is dependent on building a credible Australian household hydrogen supply chain (HHSC), which includes national distribution centres (NDCs), regional distribution centres (RDCs) and local distribution centres (LDCs). The HHSC is particularly vulnerable to operational disruptions under rapid adoption pathways and in perfect-competition market conditions, where infrastructure, supply, and pricing decisions are decentralised. Hydrogen flows may be disrupted at the NDCs and RDCs, leading to failure to meet demand and monetary losses across the HHSC. While many studies have assessed vulnerabilities within hydrogen supply chains, there is little attention paid to the consequences of distribution-level failures. This research aims to quantify the impacts associated with distribution centre (DC) disruptions in the HHSC using a multi-period network optimisation model to assess three operational situations: ideal situations, disrupted-DC situations without mitigation strategies, and disrupted-DC situations with suitable mitigation strategies. The results indicate that without mitigation strategies, demand fulfilment could potentially drop to zero, penalty costs could increase drastically, and profitability could decrease due to not meeting demand. In contrast, the implications of suitable mitigation strategies, including rerouting hydrogen through alternate, unaffected NDCs or RDCs, using spare capacity by increasing operating hours, and maintaining safety stock at RDCs, significantly increase HHSC performance. In these situations, demand fulfilment increases to up to 95%, and profitability improves substantially. This study contributes to the hydrogen supply chain literature by demonstrating how HHSCs can be planned and replanned to manage disruptions in DCs. The study also provides practical insights for policymakers and managers for a sustainable HHSC. Full article

(This article belongs to the Special Issue Energy Economics, Finance and Policy Towards Sustainable Energy: 2nd Edition)

21 pages, 805 KB

Open AccessArticle

Multidimensional Impact Assessment of Social Welfare Incorporating Dynamic Cross Subsidy and Tiered Carbon Trading

by Ya-Juan Cao, Bin-Yang Qiu, Qiu-Jie Wang, Yi-Hui Luo and Yun-Xiang Zhang

Energies 2026, 19(5), 1225; https://doi.org/10.3390/en19051225 (registering DOI) - 28 Feb 2026

Abstract

In the context of advancing two pivotal national commitments, namely the “Dual Carbon” goals and the common prosperity strategy, energy policy formulation must move beyond purely economic or environmental considerations and adopt integrated social welfare assessments. This study develops an optimal dispatch model [...] Read more.

In the context of advancing two pivotal national commitments, namely the “Dual Carbon” goals and the common prosperity strategy, energy policy formulation must move beyond purely economic or environmental considerations and adopt integrated social welfare assessments. This study develops an optimal dispatch model for a multi-microgrid system that incorporates dynamic cross subsidy and tiered carbon trading. From the perspective of welfare economics, the socioeconomic impacts of the proposed model are then systematically evaluated. First, a unified operational framework is established, combining dynamic electricity tariff cross subsidy with a tiered carbon trading mechanism. Next, a quantitative model for electricity tariff cross subsidy is proposed, and a dynamic subsidy rate linked to renewable energy output is designed to guide electricity consumption behavior. Finally, a comparative simulation is conducted across three scenarios: no subsidy, traditional cross subsidy, and the proposed dynamic cross subsidy. The results demonstrate that the proposed dynamic mechanism reduces system carbon emissions by 17.05% compared to the non-subsidy baseline while significantly optimizing total costs. Full article

(This article belongs to the Special Issue Digital Modeling, Operation and Control of Sustainable Energy Systems)

21 pages, 5047 KB

Open AccessArticle

Mechanism of Suppressing DFIG Shafting–Grid-Connected Oscillations Through Coordinated Optimization of Dual Damping Terms Under Frequency Coupling

by Zheng Wang and Yimin Lu

Energies 2026, 19(5), 1224; https://doi.org/10.3390/en19051224 (registering DOI) - 28 Feb 2026

Abstract

Sub-synchronous oscillations (SSOs) induced by the interaction between doubly fed induction generators (DFIGs) and weak grids pose a critical threat to the grid-connected stability of DFIG-based wind power systems. In this paper, a dual-damping-term compensation filter based on the concept of motion-induced amplification [...] Read more.

Sub-synchronous oscillations (SSOs) induced by the interaction between doubly fed induction generators (DFIGs) and weak grids pose a critical threat to the grid-connected stability of DFIG-based wind power systems. In this paper, a dual-damping-term compensation filter based on the concept of motion-induced amplification (MIA), together with an optimized design method using a linear quadratic regulator (LQR), is applied to the DFIG system. The effectiveness of the proposed approach in suppressing DFIG shafting oscillations and mitigating grid-connected frequency coupling is verified, and the underlying mechanisms are thoroughly investigated. By establishing a shafting dynamics model for the DFIG and a frequency-coupled oscillation impedance model, this study focuses on revealing the differentiated impacts of the dual damping parameters (

Z_{p}

and

Z_{q}

) on system stability under two operating modes: maximum power point tracking (MPPT) and constant power operation. Stability analysis based on the generalized Nyquist criterion (GNC), together with time-domain simulations, demonstrates that coordinated optimization of the dual damping terms can effectively suppress shafting oscillations and frequency coupling, thereby significantly enhancing the grid-connected stability of DFIG systems. Full article

(This article belongs to the Special Issue Advances in Integration of Renewable Energy Technologies and Distribution Systems: 2nd Edition)

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27 pages, 1264 KB

Open AccessArticle

Energy Management of PV-Enabled Battery Charging Swapping Stations for Electric Vehicles in Active Distribution Systems Under Uncertainty

by Haram Kim, Sangyoon Lee and Dae-Hyun Choi

Energies 2026, 19(5), 1223; https://doi.org/10.3390/en19051223 (registering DOI) - 28 Feb 2026

Abstract

In this paper, we propose a data-driven distributionally robust optimization (DRO) framework that ensures the economical and robust operation of solar photovoltaic (PV)-integrated battery charging swapping stations (BCSSs) for electric vehicles (EVs) under uncertainties in active distribution systems with stand-alone PV systems. In [...] Read more.

In this paper, we propose a data-driven distributionally robust optimization (DRO) framework that ensures the economical and robust operation of solar photovoltaic (PV)-integrated battery charging swapping stations (BCSSs) for electric vehicles (EVs) under uncertainties in active distribution systems with stand-alone PV systems. In the proposed framework, multiple inventory batteries in each BCSS are used through their charging and discharging real and/or reactive power scheduling to perform Volt/VAR control (VVC) along with stand-alone PV systems, and to reduce the BCSS operational cost via battery-to-battery (B2B)-based real power exchange and demand response (DR) while satisfying the desired EV battery swapping load. To handle the uncertainties in both PV generation outputs and DR-induced maximum demand reduction capability, the proposed framework is formulated as a data-driven DRO problem based on the Wasserstein metric using historical samples of the probability distributions of the uncertainties. Using a duality theory, the original Wasserstein-based DRO problem is reformulated into a tractable optimization problem that calculates the distributionally robust bounds of uncertainties using their support information. The effectiveness of the proposed framework was assessed on an IEEE 33-node power distribution system in terms of real power loss reduction via VVC and BCSS operational cost savings via B2B/DR capability. Full article

(This article belongs to the Special Issue Optimized Energy Management Technology for Electric Vehicle)

22 pages, 365 KB

Open AccessArticle

A Cost Optimization Model Utilizing Real-Time Aggregated EV Flexibility to Address Forecast Uncertainty in Demand Response Markets

by Yi-An Chen, Wente Zeng, Thibaud Cambronne, Adil Khurram and Jan Kleissl

Energies 2026, 19(5), 1222; https://doi.org/10.3390/en19051222 (registering DOI) - 28 Feb 2026

Abstract

This paper presents a novel optimization algorithm for electric vehicle (EV) aggregators aiming to maximize net revenue in demand response markets. Aggregated EV charging stations are modeled as a battery with time-varying capacity, enabling participation in these markets. Due to uncertainties in EV [...] Read more.

This paper presents a novel optimization algorithm for electric vehicle (EV) aggregators aiming to maximize net revenue in demand response markets. Aggregated EV charging stations are modeled as a battery with time-varying capacity, enabling participation in these markets. Due to uncertainties in EV plug-in duration and energy demand, it is challenging for aggregators to fulfill bid capacities in real-time (RT). To address this, EV users specify minimum acceptable service levels, allowing aggregators to optimize both charging timing and energy demand in RT. The model is composed of two layers: (1) a Day-Ahead (DA) optimizer that determines optimal EV scheduling and DA demand response market bidding, and (2) a two-stage RT optimizer that fine-tunes the charging schedule using real-time flexibility to mitigate forecast errors. The RT optimizer leverages Model Predictive Control (MPC) in a two-stage structure to address the problem’s non-convexity, which arises from two coupled unknowns: the charging time and the charging energy demand. In the first stage, it determines a cost-optimal charging schedule that ensures full service levels. In the second stage, it optimizes the charging energy demand within a feasible range, bounded above by the first-stage trajectory and below by user-defined minimum service levels, to maximize demand response market revenue. A realistic baseline and a penalty term are integrated into the demand response market revenue term of the cost function to more accurately reflect real-world conditions. Simulation results demonstrate that the proposed method yields a net economic profit at least five times higher than that of immediate (or `dumb’) charging. During one month of simulations, the aggregator achieves revenue equivalent to $0.21 per kWh of demand reduction under forecast uncertainty, totaling $3441. Full article

(This article belongs to the Section E: Electric Vehicles)

32 pages, 3297 KB

Open AccessArticle

Extensive Validation of the Three-Branch Model in Simulating the Static and the Dynamic Behavior of EDLC Supercapacitors

by Mauro Zucca, Melika Hassanzadeh, Ornella Conti, Valter Giusio and Umberto Pogliano

Energies 2026, 19(5), 1221; https://doi.org/10.3390/en19051221 (registering DOI) - 28 Feb 2026

Abstract

This study demonstrates the response of the three-branch equivalent circuit model in reproducing the terminal voltage of a supercapacitor that undergoes dynamic galvanostatic pulse trains for frequencies from 0.1 Hz to 100 Hz and signal amplitudes of 1 A, significantly wider than the [...] Read more.

This study demonstrates the response of the three-branch equivalent circuit model in reproducing the terminal voltage of a supercapacitor that undergoes dynamic galvanostatic pulse trains for frequencies from 0.1 Hz to 100 Hz and signal amplitudes of 1 A, significantly wider than the sinusoidal signals used in impedance spectroscopy. Clean and accurate pulse trains were generated at different frequencies using a transconductance power amplifier, and the voltages at the supercapacitor terminals of three different sizes of supercapacitors were successfully compared with the model. The latter was also utilized to check its ability to accurately reproduce charging and self-discharging processes and the ability to simulate voltammetric cycles. This was verified for six supercapacitor sizes from 1 F (rated 1 mWh, 10 W) up to a large 130 F module (rated 70 Wh, 144 kW). In all cases, the relative difference, with respect to the rated voltage, between the terminal voltage provided by the measurements and that yielded by the model simulations did not exceed 3.5%. This extensive multi-level validation demonstrates how the identified three-branch model based on state equations can provide an accurate electrical design tool and a reference for standards. Full article

(This article belongs to the Special Issue Supercapacitors and Their Applications: Advances and Challenges)

21 pages, 1517 KB

Open AccessArticle

Calculation Method and Characteristic Analysis of Short-Circuit Current for Grid-Forming VSGs Under Symmetrical Faults

by Shan Cheng, Bo Lin, Zhenshi Tian and Chunyang Gu

Energies 2026, 19(5), 1220; https://doi.org/10.3390/en19051220 (registering DOI) - 28 Feb 2026

Abstract

With the increasing penetration of renewable energy, grid-forming inverters that provide voltage and frequency support are receiving significant attention. However, due to the voltage source characteristics of grid-forming Virtual Synchronous Generators (VSGs), they are prone to excessive short-circuit currents during three-phase grid faults. [...] Read more.

With the increasing penetration of renewable energy, grid-forming inverters that provide voltage and frequency support are receiving significant attention. However, due to the voltage source characteristics of grid-forming Virtual Synchronous Generators (VSGs), they are prone to excessive short-circuit currents during three-phase grid faults. Moreover, conventional short-circuit current analysis methods developed for grid-following inverters cannot be directly applied to VSG-based systems. Consequently, research on fault current calculation for grid-forming VSGs has become critically important. To address this issue, this paper employs mathematical analysis to derive a short-circuit current calculation method for VSG grid-connected systems under three-phase fault conditions. Based on the derived analytical expressions, the short-circuit current characteristics of the VSG system are systematically analyzed. The correctness of the proposed analytical expressions is validated through simulations conducted on the MATLAB/Simulink(R2024b) platform. Simulation results show that the error between the analytical and simulated values remains within 8%, and decreases to below 3% after 2–3 cycles, indicating that the proposed analytical model can effectively capture the dynamic behavior of the fault current. Full article

(This article belongs to the Section F3: Power Electronics)

24 pages, 35412 KB

Open AccessArticle

Environmental Heat Source Potentials for Decentralized Heat Pumps: A GIS-Based Analysis

by Şirin Alibaş, Songmin Yu and Pia Manz

Energies 2026, 19(5), 1219; https://doi.org/10.3390/en19051219 (registering DOI) - 28 Feb 2026

Abstract

Heat pumps are an essential part of decarbonization of buildings, providing efficient and sustainable heat. Analyzing the future contribution of decentralized heat pumps requires an estimation of the potential of local environmental heat sources at high spatial resolution. These heat sources are mainly [...] Read more.

Heat pumps are an essential part of decarbonization of buildings, providing efficient and sustainable heat. Analyzing the future contribution of decentralized heat pumps requires an estimation of the potential of local environmental heat sources at high spatial resolution. These heat sources are mainly ambient heat and shallow geothermal heat, and the analysis needs to account for the space available around the building, noise immissions due to the heat pump, and heat exchange rate with the ground. So far, no consistent analysis of available heat sources for both residential and non-residential buildings is publicly available. In this study, we present a GIS-based methodology developed for estimating the maximum achievable heating capacities with heat pumps and publish them at building level. It can be shown that buildings in rural areas have a median air-source heat pump potential of 30 to 85 kW, while the median in urban areas is roughly 100 kW, with quieter options up to 300 kW. This shows that even in big cities, heat pumps have potential. In most regions, the potential for air-source heat pumps is higher than ground-source heat pumps. This study lays the foundation for investigating the competitiveness of heat pumps compared to other heating options. Full article

(This article belongs to the Section G: Energy and Buildings)

27 pages, 6913 KB

Open AccessArticle

Dynamic Operation and Optimization Analysis of an Innovative Distributed Energy System Based on Full-Spectrum Solar Energy Cascade Utilization

by Rong Zeng, Jinran Peng and Xianglin Tang

Energies 2026, 19(5), 1218; https://doi.org/10.3390/en19051218 (registering DOI) - 28 Feb 2026

Abstract

The cascade utilization of spectral beam splitting represents an effective method for enhancing the efficiency of solar energy utilization. However, most research has been conducted under stable conditions, and the impacts across different climatic zones have not been taken into account. Therefore, this [...] Read more.

The cascade utilization of spectral beam splitting represents an effective method for enhancing the efficiency of solar energy utilization. However, most research has been conducted under stable conditions, and the impacts across different climatic zones have not been taken into account. Therefore, this paper investigates an innovative distributed energy system utilizing full-spectrum solar cascade in three different climate zones. A full-spectrum solar model is established in MATLAB 2023, and the corresponding photovoltaic model files are invoked in the TRNSYS 18. After operation, the performance of full-spectrum frequency division solar energy is obtained. The equivalent carbon emissions (ECE), self-sufficiency ratio (SS), self-consumption ratio (SC) and levelized cost of energy (LCOE) are adopted as indicators to assess the environmental, energy and economic benefits of each system. The results show that the net present value (NPV) in Chengdu is the highest (186,674.19 USD), while that in Beijing is the lowest (171,458.75 USD), and that in Guangzhou is in the middle (180,650.23 USD). After optimization, Beijing achieves the lowest LCOE and the highest SS, Guangzhou achieves the highest SC and the lowest ECE, Chengdu achieves a balanced configuration where moderate on-site generation meets nearly half of the total demand. Full article

28 pages, 5203 KB

Open AccessArticle

Energy Performance of a Gravity Flow Rack with Energy Recovery: Modelling and Validation

by Paweł Zając

Energies 2026, 19(5), 1217; https://doi.org/10.3390/en19051217 (registering DOI) - 28 Feb 2026

Abstract

This paper presents a patented design of a gravity flow rack with an energy recovery system, intended for pallet storage in first-in–first-out (FIFO) and last-in–first-out (LIFO) modes. Compared with conventional flow racks, the proposed solution integrates control of load-unit motion dynamics with energy [...] Read more.

This paper presents a patented design of a gravity flow rack with an energy recovery system, intended for pallet storage in first-in–first-out (FIFO) and last-in–first-out (LIFO) modes. Compared with conventional flow racks, the proposed solution integrates control of load-unit motion dynamics with energy recovery, thereby reducing losses and stabilising pallet flow. A Rack Energy Performance Index (REPI) is proposed to enable quantitative assessment of the energy consumption of storage racks in intralogistics applications. The research methodology comprised: (i) development of the mechanical architecture and pallet guidance principles; (ii) numerical modelling in the MSC Adams environment at Technology Readiness Level 3 (TRL-3); and (iii) validation using a full-scale prototype installed in a logistics centre. Operational tests confirmed stable operation, the required throughput, and the capability for energy compensation and recovery during storage cycles. The results indicate that energy-recovering racks can support the design of energetically passive warehouses. Full article

23 pages, 13605 KB

Open AccessArticle

Sequence Impedance Modeling and Stability Analysis of dVOC-Based Grid-Forming Inverters with Different Inner-Loop Control Structures

by Jiwei Cui and Guobin Jin

Energies 2026, 19(5), 1216; https://doi.org/10.3390/en19051216 (registering DOI) - 28 Feb 2026

Abstract

To elucidate the stability mechanisms of grid-forming (GFM) inverters governed by dispatchable virtual oscillator control (dVOC), this paper develops a comprehensive sequence-impedance modeling and stability analysis framework for dVOC-based GFM inverters with different inner-loop control structures. Three representative configurations are investigated: open-loop dVOC [...] Read more.

To elucidate the stability mechanisms of grid-forming (GFM) inverters governed by dispatchable virtual oscillator control (dVOC), this paper develops a comprehensive sequence-impedance modeling and stability analysis framework for dVOC-based GFM inverters with different inner-loop control structures. Three representative configurations are investigated: open-loop dVOC control, dVOC with dual-loop voltage–current control (DLC), and dVOC with virtual admittance control (VAC). For each configuration, unified positive-sequence impedance models are derived and analytically validated. Based on these models, the stability characteristics are first analyzed in a single-inverter grid-connected system under different grid strengths. The analysis is then extended to a mixed inverter system consisting of grid-forming and grid-following (GFL) inverters. Particular attention is paid to the impedance interaction between GFM impedance shaping and the capacitive negative damping introduced by GFL inverters under weak-grid conditions. Quantitative analyses reveal that the dVOC–DLC configuration significantly enhances oscillation damping in mixed systems. Under benchmark scenarios, stable operation can be ensured with approximately a 25% GFM capacity penetration. In contrast, the open-loop and VAC configurations require around 50% and 75% capacities, respectively, to maintain stability. These findings indicate that the DLC-based inner-loop design offers superior stability margins while substantially reducing the required GFM capacity, thereby improving economic efficiency. This study establishes a quantitative impedance-based criterion for inner-loop control selection and provides practical design guidelines for deploying dVOC-based GFM inverters in future converter-dominated power systems. Full article

(This article belongs to the Special Issue Challenges and Innovations in Stability and Control of Power Systems)

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34 pages, 2842 KB

Open AccessArticle

A Multi-Criteria Decision-Support Tool Based on the MMCP for Sustainable Smart Grid Planning: Application to the Provence-Alpes-Côte d’Azur Region

by Walid Ouled Amor, Youssef Dhieb, Farhan Hameed Malik, Walid Ayadi, Ghulam Amjad Hussain and Moez Ghariani

Energies 2026, 19(5), 1215; https://doi.org/10.3390/en19051215 (registering DOI) - 28 Feb 2026

Abstract

This study presents the Multi-Method Convergence Protocol (MMCP), a decision-making framework designed to overcome the mono-objective limitations of HOMER Pro (Hybrid Optimization Model for Electric Renewables) and the instability commonly observed among traditional MCDM approaches. Applied to a hybrid PV–wind–grid Smart Grid (Intelligent [...] Read more.

This study presents the Multi-Method Convergence Protocol (MMCP), a decision-making framework designed to overcome the mono-objective limitations of HOMER Pro (Hybrid Optimization Model for Electric Renewables) and the instability commonly observed among traditional MCDM approaches. Applied to a hybrid PV–wind–grid Smart Grid (Intelligent Electrical Power Grid) in the Provence-Alpes-Côte d’Azur region (France), the protocol transforms techno-economic simulation outputs into robust and explainable multi-criteria decisions. MMCP integrates five sequential stages—normalization, AHP-based (Analytic Hierarchy Process) weighting, multi-method ranking (TOPSIS, PROMETHEE II, ELECTRE II (Elimination and Choice Expressing Reality II), and VIKOR), Borda–Copeland (Borda Count Ranking Method–Copeland Pairwise Aggregation Method) co-aggregation, and statistical validation—using Kendall’s τb (Kendall’s Rank Correlation Coefficient) and Spearman’s ρ (Spearman’s Rank Correlation Coefficient). Results reveal strong convergence between compensatory and non-compensatory models (τb ≥ 0.75; ρ ≥ 0.90), confirming the internal coherence and structural stability of the rankings. Scenario 17 emerges as the optimal configuration, combining low LCOE (Levelized Cost of Energy) with reduced emissions and balanced renewable penetration. The near-linear alignment between aggregation methods validates the protocol’s reliability and methodological transparency. Overall, MMCP provides a scalable and traceable foundation for sustainable Smart Grid planning and evidence-based energy governance. Full article

(This article belongs to the Section A1: Smart Grids and Microgrids)

17 pages, 1664 KB

Open AccessArticle

STGCformer: Spatio-Temporal Graph Convolutional Transformer for Short-Term Wind Power Forecasting

by Chenyu Tian, Min Xia, Shi Yuan, Liwen Wang and Wei Zhuang

Energies 2026, 19(5), 1214; https://doi.org/10.3390/en19051214 (registering DOI) - 28 Feb 2026

Abstract

The accuracy of short-term wind power forecasting (STWPF) is crucial for the stable operation of power systems. To address the issue of insufficient capture of spatio-temporal dependencies in existing models, which leads to low prediction accuracy, this paper proposes a novel Transformer-based spatio-temporal [...] Read more.

The accuracy of short-term wind power forecasting (STWPF) is crucial for the stable operation of power systems. To address the issue of insufficient capture of spatio-temporal dependencies in existing models, which leads to low prediction accuracy, this paper proposes a novel Transformer-based spatio-temporal graph convolutional (STGCformer) model. The time series decomposition module (TSDM) captures periodic fluctuations and long-term variations within the data by performing seasonal trend decomposition. The spatio-temporal graph convolutional (STGC) architecture combines a Graph Attention Network (GAT) with convolutional layers (Convs) to capture both spatial and temporal dependencies, jointly processing the spatio-temporal characteristics inherent in wind power data. The Transformer’s attention mechanism simultaneously handles both short-term and long-term fluctuations. Extensive experimental results show that STGCformer achieves the best prediction accuracy across multiple time steps (24, 48, 72, 96 h), with the average absolute error (MAE) and mean absolute percentage error (MAPE) at 48 h being 41.383 and 3.862, respectively. This model provides a new methodological framework for STWPF. Full article

(This article belongs to the Special Issue Development of Artificial Intelligence in Green Buildings and Renewable Energy)

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