Highly efficient printed quantum dot light-emitting diodes through ultrahigh-definition double-layer transfer printing

Jisu Yoo; Kyunghoon Lee; U. Jeong Yang; Hyeon Hwa Song; Jae Hong Jang; Gwang Heon Lee; Megalamane S. Bootharaju; Jun Hee Kim; Kiwook Kim; Soo Ik Park; Jung Duk Seo; Shi Li; Won Seok Yu; Jong Ik Kwon; Myoung Hoon Song; Taeghwan Hyeon; Jiwoong Yang; Moon Kee Choi

doi:10.1038/s41566-024-01496-x

Highly efficient printed quantum dot light-emitting diodes through ultrahigh-definition double-layer transfer printing

Jisu Yoo
, Kyunghoon Lee
, U. Jeong Yang
, Hyeon Hwa Song
, Jae Hong Jang
, Gwang Heon Lee
, Megalamane S. Bootharaju
, Jun Hee Kim
, Kiwook Kim
, Soo Ik Park
, Jung Duk Seo
, Shi Li
, Won Seok Yu
, Jong Ik Kwon
, Myoung Hoon Song
, Taeghwan Hyeon
, Jiwoong Yang
, Moon Kee Choi

Department of Energy and Science and Engineering

Research output: Contribution to journal › Article › peer-review

57 Scopus citations

Abstract

Highly efficient and high-definition displays with deformable form factors are highly desirable for next-generation electronic devices. Despite the unique advantages of quantum dots (QDs), including high photoluminescence quantum yield, wide colour range and high colour purity, developing a QD patterning process for high-definition pixels and efficient QD light-emitting diodes (QLEDs) is in its early stages. Here we present highly efficient QLEDs through ultrahigh-definition double-layer transfer printing of a QD/ZnO film. Surface engineering of viscoelastic stamps enables double-layer transfer printing that can create RGB pixelated patterns with 2,565 pixels per inch and monochromic QD patterns with ~20,526 pixels per inch. The close packing of both QDs and ZnO nanoparticles by double-layer transfer printing substantially minimizes the leakage current, enhancing the external quantum efficiency of our devices to 23.3%. Furthermore, we demonstrate highly efficient wearable QLEDs fabricated by our technique. This study paves the way for the development of highly efficient, full-colour QD displays via the transfer printing technique, demonstrating great promise for next-generation display technologies.

Original language	English
Pages (from-to)	1105-1112
Number of pages	8
Journal	Nature Photonics
Volume	18
Issue number	10
DOIs	https://doi.org/10.1038/s41566-024-01496-x
State	Published - Oct 2024

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Publisher Copyright:
© The Author(s), under exclusive licence to Springer Nature Limited 2024.

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Yoo, J., Lee, K., Yang, U. J., Song, H. H., Jang, J. H., Lee, G. H., Bootharaju, M. S., Kim, J. H., Kim, K., Park, S. I., Seo, J. D., Li, S., Yu, W. S., Kwon, J. I., Song, M. H., Hyeon, T., Yang, J., & Choi, M. K. (2024). Highly efficient printed quantum dot light-emitting diodes through ultrahigh-definition double-layer transfer printing. Nature Photonics, 18(10), 1105-1112. https://doi.org/10.1038/s41566-024-01496-x

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title = "Highly efficient printed quantum dot light-emitting diodes through ultrahigh-definition double-layer transfer printing",

abstract = "Highly efficient and high-definition displays with deformable form factors are highly desirable for next-generation electronic devices. Despite the unique advantages of quantum dots (QDs), including high photoluminescence quantum yield, wide colour range and high colour purity, developing a QD patterning process for high-definition pixels and efficient QD light-emitting diodes (QLEDs) is in its early stages. Here we present highly efficient QLEDs through ultrahigh-definition double-layer transfer printing of a QD/ZnO film. Surface engineering of viscoelastic stamps enables double-layer transfer printing that can create RGB pixelated patterns with 2,565 pixels per inch and monochromic QD patterns with \textasciitilde{}20,526 pixels per inch. The close packing of both QDs and ZnO nanoparticles by double-layer transfer printing substantially minimizes the leakage current, enhancing the external quantum efficiency of our devices to 23.3\%. Furthermore, we demonstrate highly efficient wearable QLEDs fabricated by our technique. This study paves the way for the development of highly efficient, full-colour QD displays via the transfer printing technique, demonstrating great promise for next-generation display technologies.",

author = "Jisu Yoo and Kyunghoon Lee and Yang, \{U. Jeong\} and Song, \{Hyeon Hwa\} and Jang, \{Jae Hong\} and Lee, \{Gwang Heon\} and Bootharaju, \{Megalamane S.\} and Kim, \{Jun Hee\} and Kiwook Kim and Park, \{Soo Ik\} and Seo, \{Jung Duk\} and Shi Li and Yu, \{Won Seok\} and Kwon, \{Jong Ik\} and Song, \{Myoung Hoon\} and Taeghwan Hyeon and Jiwoong Yang and Choi, \{Moon Kee\}",

note = "Publisher Copyright: {\textcopyright} The Author(s), under exclusive licence to Springer Nature Limited 2024.",

year = "2024",

month = oct,

doi = "10.1038/s41566-024-01496-x",

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Yoo, J, Lee, K, Yang, UJ, Song, HH, Jang, JH, Lee, GH, Bootharaju, MS, Kim, JH, Kim, K, Park, SI, Seo, JD, Li, S, Yu, WS, Kwon, JI, Song, MH, Hyeon, T, Yang, J & Choi, MK 2024, 'Highly efficient printed quantum dot light-emitting diodes through ultrahigh-definition double-layer transfer printing', Nature Photonics, vol. 18, no. 10, pp. 1105-1112. https://doi.org/10.1038/s41566-024-01496-x

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AU - Park, Soo Ik

AU - Seo, Jung Duk

AU - Li, Shi

AU - Yu, Won Seok

AU - Kwon, Jong Ik

AU - Song, Myoung Hoon

AU - Hyeon, Taeghwan

AU - Yang, Jiwoong

AU - Choi, Moon Kee

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N2 - Highly efficient and high-definition displays with deformable form factors are highly desirable for next-generation electronic devices. Despite the unique advantages of quantum dots (QDs), including high photoluminescence quantum yield, wide colour range and high colour purity, developing a QD patterning process for high-definition pixels and efficient QD light-emitting diodes (QLEDs) is in its early stages. Here we present highly efficient QLEDs through ultrahigh-definition double-layer transfer printing of a QD/ZnO film. Surface engineering of viscoelastic stamps enables double-layer transfer printing that can create RGB pixelated patterns with 2,565 pixels per inch and monochromic QD patterns with ~20,526 pixels per inch. The close packing of both QDs and ZnO nanoparticles by double-layer transfer printing substantially minimizes the leakage current, enhancing the external quantum efficiency of our devices to 23.3%. Furthermore, we demonstrate highly efficient wearable QLEDs fabricated by our technique. This study paves the way for the development of highly efficient, full-colour QD displays via the transfer printing technique, demonstrating great promise for next-generation display technologies.

AB - Highly efficient and high-definition displays with deformable form factors are highly desirable for next-generation electronic devices. Despite the unique advantages of quantum dots (QDs), including high photoluminescence quantum yield, wide colour range and high colour purity, developing a QD patterning process for high-definition pixels and efficient QD light-emitting diodes (QLEDs) is in its early stages. Here we present highly efficient QLEDs through ultrahigh-definition double-layer transfer printing of a QD/ZnO film. Surface engineering of viscoelastic stamps enables double-layer transfer printing that can create RGB pixelated patterns with 2,565 pixels per inch and monochromic QD patterns with ~20,526 pixels per inch. The close packing of both QDs and ZnO nanoparticles by double-layer transfer printing substantially minimizes the leakage current, enhancing the external quantum efficiency of our devices to 23.3%. Furthermore, we demonstrate highly efficient wearable QLEDs fabricated by our technique. This study paves the way for the development of highly efficient, full-colour QD displays via the transfer printing technique, demonstrating great promise for next-generation display technologies.

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Highly efficient printed quantum dot light-emitting diodes through ultrahigh-definition double-layer transfer printing

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