Seongyu Lee scite author profile

The fabrication of organic photovoltaic modules via printing techniques has been the greatest challenge for their commercial manufacture. Current module architecture, which is based on a monolithic geometry consisting of serially interconnecting stripe-patterned subcells with finite widths, requires highly sophisticated patterning processes that significantly increase the complexity of printing production lines and cause serious reductions in module efficiency due to so-called aperture loss in series connection regions. Herein we demonstrate an innovative module structure that can simultaneously reduce both patterning processes and aperture loss. By using a charge recombination feature that occurs at contacts between electron- and hole-transport layers, we devise a series connection method that facilitates module fabrication without patterning the charge transport layers. With the successive deposition of component layers using slot-die and doctor-blade printing techniques, we achieve a high module efficiency reaching 7.5% with area of 4.15 cm2.

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Self-assembly of interfacial and photoactive layers via one-step solution processing for efficient inverted organic solar cells

Kang

Lee

Jung

et al. 2013

Nanoscale

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Vertically self-assembled bilayers with an interfacial bottom layer and a photoactive top layer are demonstrated via a single coating step of a blend composed of an amine-containing nonconjugated polyelectrolyte (NPE) and an organic electron donor-acceptor bulk heterojunction composite. The self-assembled NPE layer reduces the work function of an indium tin oxide (ITO) cathode, which leads to efficient inverted organic solar cells without any additional interface engineering of the ITO.

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Air‐Stable Organic Solar Cells Using an Iodine‐Free Solvent Additive

Lee

Kong

Lee

2016

Advanced Energy Materials

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A Versatile Self‐Organization Printing Method for Simplified Tandem Organic Photovoltaics

Kim

Kang

Hong

et al. 2016

Adv Funct Materials

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Despite recent dramatic enhancements in power conversion efficiencies (PCEs) resulting in values over 10%, the manufacturing of tandem organic solar cells (OSCs) via current printing technologies is subject to tremendous challenges. Existing complicated tandem structures consisting of six or more component layers have been a major obstacle that significantly increases the complexity of printing processes and substantially sacrifices the PCE for printed devices. Here, an innovative printing method is reported that simplifies the fabrication process of the tandem OSCs. By developing a new printing technique using a nanocomposites containing interfacial and photoactive materials, a simultaneously printed bilayer of consisting of interfacial and photoactive layers, achieved through vertical self‐organization, is successfully demonstrated, resulting in tandem OSCs with only four printed layers. Moreover, by rigorously controlling the molecular weight of the interfacial materials, the self‐assembly characteristics are improved and an efficient tandem OSC is yielded with a PCE of 9.1% achieved in printed layers.

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Efficient and photostable ternary organic solar cells with a narrow band gap non-fullerene acceptor and fullerene additive

Lee

Yao

et al. 2020

J. Mater. Chem. A

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Achieving Thickness‐Insensitive Morphology of the Photoactive Layer for Printable Organic Photovoltaic Cells via Side Chain Engineering in Nonfullerene Acceptors

Lee

Park

Lee

et al. 2019

Advanced Energy Materials

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Although high power conversion efficiency of over 14% has been achieved using nonfullerene acceptors (NFAs) in organic photovoltaics (OPVs), securing their insensitive device performance to the thickness of the photoactive layer remains an indispensable requirement for their successful commercialization via printing technologies. In this study, by synthesizing a new series of ITIC‐based NFAs having alkyl or alkoxy groups, it is found that the bulk heterojunction morphology dependence on the thickness of the photoactive layer becomes more severe as the difference in the surface energy of the donor and acceptor increases. It is believed that this observation is the origin that yields the device performance dependence on the thickness of the photoactive layer. Through sensitive control of the surface energy of these ITIC‐based NFAs, it is demonstrated that thickness‐insensitive OPVs can be achieved even using a doctor blade technique under air without using any additives. It is believed that present approach provides an important insight into the design of photoactive materials and morphology control for the printable OPVs using NFAs.

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Seongyu Lee

Achieving long-term stable perovskite solar cells via ion neutralization

A highly efficient self-power pack system integrating supercapacitors and photovoltaics with an area-saving monolithic architecture

A series connection architecture for large-area organic photovoltaic modules with a 7.5% module efficiency

Self-assembly of interfacial and photoactive layers via one-step solution processing for efficient inverted organic solar cells

Air‐Stable Organic Solar Cells Using an Iodine‐Free Solvent Additive

A Versatile Self‐Organization Printing Method for Simplified Tandem Organic Photovoltaics

Efficient and photostable ternary organic solar cells with a narrow band gap non-fullerene acceptor and fullerene additive

Achieving Thickness‐Insensitive Morphology of the Photoactive Layer for Printable Organic Photovoltaic Cells via Side Chain Engineering in Nonfullerene Acceptors

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