4.7 Article

Advances in upconversion enhanced solar cell performance

Journal

SOLAR ENERGY MATERIALS AND SOLAR CELLS
Volume 230, Issue -, Pages -

Publisher

ELSEVIER
DOI: 10.1016/j.solmat.2021.111234

Keywords

Solar cells; Upconversion; Luminescence; Lanthanides; Atomic layer deposition; Photonics

Funding

  1. Academy of Finland (Profi 3)
  2. Flagship Programme, Photonics Research and Innovation (PREIN)
  3. Jenny & Antti Wihuri Foundation

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The article discusses the current status and challenges of photovoltaic technology and proposes a potential solution to enhance solar cell performance by integrating an upconverting component. It summarizes the design principles, fabrication routes of UC materials, discusses different approaches to integrate UC layers into actual PV device configurations, highlights significant results achieved in the field, presents future prospects, and outlines remaining challenges in this important and intriguing scientific field.
Photovoltaics (PV) is the leading renewable energy harvesting technology. Thus, there is a remarkable strive to enhance the light harvesting capability of the state-of-the-art solar cells. The major issue common to all solar cell types is that they utilize only a limited portion of the solar spectrum, mostly in the visible range, as the active semiconductor materials suffer from intrinsic light absorption thresholds. As a result, photons below and above these threshold values do not contribute to the electricity generation. A plausible solution to enhance the performance is to integrate the PV cell with an upconverting (UC) component capable of harvesting lower energy photons in the infrared (IR) range and emitting visible light. The concept was first introduced in 1990s, but major progress in the field has been made in particular in the recent few years. In this overview our intention is to provide the readers with a comprehensive account of the progress in the research on the UC-enhanced solar cells. Lanthanide ions embedded in different host lattices constitute the most important UC material family relevant to the PV technology; we first summarize the design principles and fabrication routes of these materials. Then discussed are the different approaches taken to integrate the UC layers in actual PV device configurations. Finally, we will highlight the most prominent results obtained, give some future perspectives and outline the remaining challenges in this scientifically intriguing and application-wise important field.

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