# Nanoimprint Lithography Enabling High-Performance Organic Optoelectronics: Advances and Perspectives

**Authors:** Ningning Song, Xinghao Guo, Hongqiao Zhao, Bohang Li, Ningning Liang, Tianrui Zhai

PMC · DOI: 10.1007/s40820-026-02093-z · Nano-Micro Letters · 2026-02-04

## TL;DR

Nanoimprint lithography improves the performance of organic optoelectronic devices by enabling precise patterning and efficient manufacturing.

## Contribution

This review systematically summarizes recent advances in nanoimprint lithography for organic optoelectronics and highlights its potential for industrial applications.

## Key findings

- Nanoimprint lithography enhances light management in organic light-emitting diodes and solar cells.
- The technique improves charge transport in organic field-effect transistors through controlled molecular ordering.
- NIL supports scalable, low-cost fabrication on flexible substrates, enabling next-generation wearable electronics.

## Abstract

Nanoimprint lithography (NIL) enables high-performance light management in organic light-emitting diodes and organic solar cells, and enhances charge transport in organic field-effect transistors via controlled molecular ordering, pushing organic optoelectronics beyond conventional efficiency limits.The technology provides a scalable, low-cost platform for large-area fabrication on flexible substrates, effectively bridging the gap between laboratory innovation and industrial mass production.NIL uniquely empowers the creation of multifunctional integrated devices and novel architectures, opening pathways for next-generation wearable electronics and bio-integrated systems.

Nanoimprint lithography (NIL) enables high-performance light management in organic light-emitting diodes and organic solar cells, and enhances charge transport in organic field-effect transistors via controlled molecular ordering, pushing organic optoelectronics beyond conventional efficiency limits.

The technology provides a scalable, low-cost platform for large-area fabrication on flexible substrates, effectively bridging the gap between laboratory innovation and industrial mass production.

NIL uniquely empowers the creation of multifunctional integrated devices and novel architectures, opening pathways for next-generation wearable electronics and bio-integrated systems.

Organic optoelectronic devices demonstrate immense potential in flexible displays, wearable electronics, and artificial skin, needing precise light-field and morphology management strategies to further improve their opto-electric performance. Nanoimprint lithography (NIL) has emerged as a high-resolution, high-efficiency, and low-cost patterning technique that mechanically transferring micro/nanoscale patterns from a template to a substrate to significantly enhance the optoelectronic performance through the precise creation of advanced light-management structures, combined with additional solid-state stacking morphology. This review systematically summarizes recent advances in NIL technology for organic optoelectronics. It begins with an introduction to the fundamental principles, main process variants (thermal, ultraviolet, and electrochemical NIL), as well as key technical issues. Subsequently, through specific applications in organic light-emitting diodes, organic solar cells, and organic field-effect transistors, it highlights the exceptional capabilities of NIL to enhance device performance by controlling crystallization and creating functional micro/nanostructuring. Specific advantages include enabling high-efficiency light management to overcome efficiency bottlenecks, facilitating low-cost, high-throughput manufacturing for industrialization, full compatibility with flexible substrates for emerging applications, enabling multifunctional integration and novel device architectures, and tailoring material microstructures and properties advance fundamental research. Finally, we discuss the remaining challenges and future prospects of NIL in integrated organic optoelectronic systems.

## Full-text entities

- **Diseases:** OFETs (MESH:D019965), OLEDs (MESH:D020795)
- **Chemicals:** P3HT (MESH:C507295), silanes (MESH:D012821), polyester (MESH:D011091), water (MESH:D014867), acrylate (MESH:C036658), polyurethanes (MESH:D011140), PMMA (MESH:D019904), epoxy (MESH:D004853), Ag (MESH:D012834), MoO3 (MESH:C082290), Al (MESH:D000535), graphene (MESH:D006108), oxygen (MESH:D010100), LiF (MESH:C027651), sucrose (MESH:D013395), volatile organic compound (MESH:D055549), perovskite (MESH:C059910), PDMS (MESH:C013830), silicon (MESH:D012825), carbon (MESH:D002244), polymer (MESH:D011108), Li (MESH:D008094), metal (MESH:D008670), nickel (MESH:D009532), OLED (-), silica (MESH:D012822), naphthoquinone (MESH:D009285), diamond (MESH:D018130), ZnO (MESH:D015034), PEDOT: PSS (MESH:C533756), TiO2 (MESH:C009495), Au (MESH:D006046), quartz (MESH:D011791)
- **Mutations:** T2T

## Full text

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## Figures

10 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12868367/full.md

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Source: https://tomesphere.com/paper/PMC12868367