As the planet confronts the escalating challenges of climate change and a mounting global energy crisis, the search for sustainable, efficient energy solutions has never been more urgent. Traditional silicon-based photovoltaic technologies, while foundational to the current solar energy landscape, face inherent limitations in efficiency, operational stability, and mechanical flexibility. In response, an international team of researchers led by Professor Ghulam Dastgeer of Sejong University and Professor Zhiming Wang from the University of Electronic Science and Technology of China has compiled a profound review illuminating the transformative potential of two-dimensional (2D) materials in next-generation solar energy devices. Their comprehensive analysis not only highlights the remarkable properties of atomically thin 2D materials but also navigates their integration into diverse photovoltaic architectures poised to transcend current technological barriers.
Two-dimensional materials, typified by their atomic-scale thickness and exceptional electronic characteristics, have captivated scientific interest due to their tunable bandgaps and superior charge carrier mobilities. This multidimensional tunability enables bespoke electronic and optical properties unattainable in conventional bulk materials. Graphene, molybdenum disulfide (MoS₂), and MXenes exemplify this class of materials, each offering distinct advantages that address the critical loss mechanisms in conventional solar cells. Their ability to facilitate rapid charge transport and minimize recombination events constitutes a fundamental shift in photovoltaic device engineering, targeting performance enhancements beyond conventional limitations.
A central aspect of this research lies in exploiting 2D materials for interface engineering within solar cells. These materials serve as electron and hole transport layers (ETLs and HTLs), as well as surface passivation agents that strategically align energy levels between active layers and electrodes. This alignment is crucial in perovskite, organic, and dye-sensitized solar cells, where interfacial imperfections often precipitate charge recombination and performance degradation. Through the introduction of 2D layers, the undesirable trap states and energetic mismatches are substantially suppressed, resulting in improved charge extraction efficiency and prolonged device lifetimes.
Beyond electronic advantages, the inherent chemical stability and mechanical flexibility of 2D materials open pathways toward the fabrication of lightweight, bendable photovoltaic devices. Such characteristics are particularly promising for emerging applications in wearable electronics and portable power generators, where traditional rigid silicon panels are impractical. The fusion of mechanical resilience and electronic optimization encapsulates a new era of photovoltaics geared towards ubiquitous, integrated energy harvesting solutions.
This review meticulously categorizes the diverse family of 2D materials, encompassing graphene, transition metal dichalcogenides (TMDCs) like MoS₂ and WS₂, black phosphorus, MXenes, and elemental 2D sheets such as silicene and stanene. Each material’s unique electronic structure and surface chemistry afford tailored functionalities within photovoltaic cells, from serving as transparent conductive electrodes to acting as catalytic counter electrodes in dye-sensitized solar cells. Such versatility underscores the pivotal role of material selection in optimizing photovoltaic performance for specific device configurations.
Architectural innovation in solar cells benefits significantly from the integration of 2D materials. The study outlines their impact across planar heterojunctions, bulk heterojunctions, and nanocomposite solar cell designs. These architectures harness the 2D materials’ ability to enhance light absorption, facilitate efficient exciton dissociation, and streamline charge collection. By engineering nanoscale interfaces and heterostructures, researchers can finely tune device properties, resulting in marked improvements in power conversion efficiencies and operational stability.
Scaling laboratory breakthroughs to industrial relevance remains a critical challenge. The review highlights advances in scalable synthesis techniques such as chemical vapor deposition (CVD), liquid-phase exfoliation, and roll-to-roll transfer printing. These methods are pivotal for producing high-quality 2D materials over large areas with reproducible properties, enabling their integration into commercially viable solar modules. Addressing synthesis scalability is essential to fulfill the promise of 2D materials in terawatt-scale photovoltaic deployment.
In the realm of perovskite solar cells, 2D materials have been shown to passivate defects through mechanisms like lead-sulfur (Pb–S) bonding, promoting epitaxial growth and creating effective barriers against moisture and ion migration. Such modifications have propelled perovskite devices to achieve power conversion efficiencies exceeding 26%, alongside substantially enhanced operational stability surpassing 1,000 hours. These advancements hold transformative potential for establishing perovskite photovoltaics as a cornerstone technology.
Organic solar cells benefit similarly from employing 2D transition metal dichalcogenides such as WS₂ and layered compounds like ZrSe₂ as electron and hole transport layers. The work-function tuning ability of these materials reduces charge recombination losses and contributes to mechanical durability, enabling efficiencies above 17% and sustaining performance over 1,000 bending cycles. This intersection of efficiency and flexibility aligns perfectly with demands for wearable and deformable solar devices.
Dye-sensitized solar cells (DSSCs), traditionally reliant on platinum counter electrodes, are witnessing a paradigm shift facilitated by 2D material-based alternatives. Pt-free counter electrodes using compounds such as WSe₂ combined with zinc or MoP/MXene composites exhibit superior electrocatalytic activity toward triiodide (I₃⁻) reduction, reaching efficiencies surpassing 10%. These innovations reduce reliance on precious metals and offer cost-effective, sustainable pathways for DSSC commercialization.
Despite these promising strides, significant challenges must be addressed to fully harness the capabilities of 2D materials in photovoltaics. The atomic thickness of these materials inherently limits light absorption, necessitating innovative strategies to augment photon harvesting. Moreover, their susceptibility to structural defects and environmental degradation remains an obstacle to long-term device reliability. The roadmap forward includes leveraging machine learning for accelerated material discovery, designing multifunctional heterostructures that synergize complementary properties, and subjecting devices to rigorous operational lifetimes exceeding 10,000 hours to validate stability.
The comprehensive review envisions a future where 2D materials are seamlessly integrated into photovoltaic technologies, driving efficiencies beyond 28% and fostering commercial viability at scale by the year 2030. Achieving this vision mandates interdisciplinary collaboration among materials scientists, chemists, physicists, and engineers, catalyzing innovation that transcends current photovoltaic paradigms. By charting this course, the research not only illuminates the transformative role of 2D materials but also galvanizes the global scientific community towards a sustainable, solar-powered future.
Subject of Research:
Article Title: Emerging Role of 2D Materials in Photovoltaics: Efficiency Enhancement and Future Perspectives
News Publication Date:
Web References: http://dx.doi.org/10.1007/s40820-025-01869-z
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Image Credits: Ghulam Dastgeer, Muhammad Wajid Zulfiqar, Sobia Nisar, Rimsha Zulfiqar, Muhammad Imran, Swagata Panchanan, Subhajit Dutta, Kamran Akbar, Alberto Vomiero, Zhiming Wang
Keywords: Photovoltaics, 2D Materials, Graphene, MoS₂, MXenes, Perovskite Solar Cells, Organic Solar Cells, Dye-Sensitized Solar Cells, Electron Transport Layers, Hole Transport Layers, Flexible Solar Cells
