Organic photovoltaics: A journey through time, advancements, and future opportunities

Gennadiy Bulavko

doi:10.32703/2415-7422-2024-14-1-10-32

Gennadiy Bulavko Taras Shevchenko National University of Kyiv

DOI: https://doi.org/10.32703/2415-7422-2024-14-1-10-32

Keywords: renewable energy, solar cell efficiency, material science, sustainable technology, energy conversion, environmental impact

Abstract

This comprehensive study explores the realm of organic photovoltaics, a pivotal green energy technology, tracing its journey from early theoretical concepts to its current status as a promising avenue for sustainable energy production. The research meticulously examines the series of developmental milestones in the conversion of solar energy into electrical power, with a specialized focus on the evolution, technological advancements, and the inherent challenges faced by organic solar cells. Delving into the foundational aspects of organic photovoltaics, this paper reviews the initial discovery and subsequent enhancements in material science that have significantly influenced the efficiency and practicality of organic solar cells. It provides a detailed analysis of the various organic materials used over the years, including small molecules and polymers, discussing their light-absorbing capabilities, charge transport properties, and the innovative engineering behind the architectures of organic photovoltaic devices. A substantial portion of the study is dedicated to highlighting the unique advantages of organic photovoltaics, such as their lightweight nature, flexibility, and potential for low-cost production through roll-to-roll processes. These benefits are juxtaposed with the current limitations of organic photovoltaic technology, including comparatively lower efficiency and lifespan issues, to present a balanced perspective on the current state of organic photovoltaic development. Furthermore, the paper explores the environmental impact of organic solar cells, emphasizing their role in reducing carbon footprint and dependency on fossil fuels. It assesses the lifecycle analyses of organic photovoltaics, from manufacturing to disposal, to underscore their potential as an eco-friendly alternative to traditional photovoltaic technologies. In addressing the future prospects of organic photovoltaics, the research outlines the ongoing efforts in material innovation, device engineering, and scalability challenges. It discusses the role of interdisciplinary collaboration in overcoming the technical hurdles and enhancing the commercial viability of organic photovoltaics. The potential for integration of organic photovoltaics s into the urban landscape, wearable technology, and portable power sources is also explored, highlighting the versatile applications of organic solar cells in meeting the diverse energy needs of the modern world. In conclusion, this paper not only provides a thorough historical overview and current state analysis of organic photovoltaics but also forecasts the exciting advancements on the horizon. By identifying the critical factors for the success of organic photovoltaics and proposing strategic directions for future research, this study contributes valuable insights into the ongoing quest for renewable energy solutions. It calls for increased investment and research focus on organic photovoltaics as a key player in the global transition towards a sustainable and energy-efficient future.

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