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A review of optimization strategies for hybrid renewable energy systems toward sustainable clean energy

Muhibbuddin Muhibbuddin, Erdiwansyah Erdiwansyah, Ahmad Syahir, Rizalman Mamat, Ratnaningsih Eko Sardjono

2025Results in Engineering7 citationsDOIOpen Access PDF

Abstract

• Metaheuristic algorithms reduce LCOE to $0.06192/kWh in off-grid HRES. • NSGA-II cuts system cost by up to 56.7 % in grid-connected hybrid setups. • PV-Hydro-storage combos reduce curtailment by 60 % with LCOE below $0.10/kWh. • AI and GIS tools enhance forecasting, planning, and energy dispatch accuracy. • HRES faces high CAPEX, regulatory gaps, and needs circular economy models. The global transition toward decarbonization has accelerated the development of HRES as resilient, cost-effective, and sustainable energy solutions. This review synthesises findings from >30 recent high-impact studies (2024–2025) on optimisation strategies integrating solar, wind, hydro, and storage technologies. Metaheuristic algorithms, including DE, PSO, and NSGA-II, have demonstrated significant effectiveness in minimising system costs and improving reliability. In off-grid rural electrification applications, DE achieved the lowest Levelized Cost of Energy (LCOE) of $0.062/kWh (USD2024) with an LPSP of 0.05, highlighting its superior cost-efficiency and stability. In grid-connected systems, NSGA-II enabled multi-objective optimisation, reducing total system costs by up to 56.7 % through coordinated use of hybrid battery and pumped-hydro storage. In Turkey, optimised PV–hydro–battery systems maintained a continuous power balance while reducing curtailed energy by 60 %, achieving an LCOE below $0.10/kWh. Moreover, incorporating frequency-constrained UC models with virtual inertia improved grid stability, though at the cost of approximately 12 % lower renewable penetration and 35 % higher operating costs. Emerging research trends emphasise AI-based forecasting, GIS-assisted spatial optimisation, blockchain-enabled peer-to-peer energy trading, and lifecycle sustainability assessments. Persistent challenges include high capital expenditure, technical complexity, and inadequate regulatory and sectoral integration. The review concludes with recommendations for AI-integrated real-time control, modular and scalable HRES design, policy-algorithm co-development, and circular economy frameworks to support the global deployment of intelligent, adaptive, and sustainable hybrid energy systems.

Topics & Concepts

Cost of electricity by sourceRenewable energyEnvironmental economicsSustainabilityCapital costElectricity generationElectrificationCogenerationFlexibility (engineering)Efficient energy useVariable renewable energyMarket penetrationComputer scienceSustainable developmentElectricityHybrid systemRisk analysis (engineering)Energy systemEngineeringEnergy storageElectric power systemEnergy mixProduction (economics)Net present valueGridEnvironmental scienceProcess engineeringElectricity systemMulti-objective optimizationEnergy consumptionEnergy engineeringEnergy sourceCost effectivenessPenetration rateEnergy managementOperating costEnergy policyEnergy (signal processing)Hybrid Renewable Energy SystemsIntegrated Energy Systems OptimizationSmart Grid Energy Management
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