Litcius/Paper detail

Enhanced power-point tracking for high-hysteresis perovskite solar cells with a galvanostatic approach

Emilio J. Juárez‐Pérez, Cristina Momblona, Roberto Casas, Marta Haro

2024Cell Reports Physical Science12 citationsDOIOpen Access PDF

Abstract

Harnessing the untapped potential of solar energy sources is crucial for achieving a sustainable future, and accurate maximum-power-point tracking of solar cells is vital to maximizing their power generation. This article introduces a power-tracking algorithm and cost-effective hardware for long-term operational stability measurements in perovskite solar cells. Existing algorithms for photovoltaic technology lead to suboptimal performance when applied to the most stable perovskite devices (for example, triple-mesoscopic hole-transport-material-free metal halide perovskite solar cells). To address this challenge, we developed a low-cost hardware solution for research purposes that enables concurrent long-term stability measurements in parallel with a galvanostatic-type power-tracking algorithm, ensuring superior operational performance for high-hysteresis perovskite solar cells. The suggested enhancements bear significant implications for the extensive integration of perovskite solar-cell technologies, particularly those dependent on power-optimizer devices.

Topics & Concepts

Perovskite (structure)Photovoltaic systemMaximum power point trackingComputer scienceHysteresisSolar cellPerovskite solar cellMaterials sciencePower (physics)Solar powerMaximum power principleEnergy conversion efficiencyStability (learning theory)Electronic engineeringElectrical engineeringOptoelectronicsEngineeringVoltagePhysicsChemical engineeringInverterMachine learningQuantum mechanicsPerovskite Materials and Applicationssolar cell performance optimizationOrganic Electronics and Photovoltaics