Date21st, Jun 2019

Summary:

The history and progress of ice lithography (IL), and its applications in 3D nanofabrication are reviewed. The evolution of IL instruments is discussed and major instrumentation advances are highlighted. Finally, the perspectives of nanoscale 3D printing of functional materials using organic ices are presented.

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Figure 1

image: IL process flow. Water ice acts as a positive-tone lithography resist, and alkane ice demonstrates a negative-resist-like capability. view more 

Credit: ©Science China Press

Nanotechnology and nanoscience are enabled by nanofabrication. Electron-beam lithography (EBL), which makes patterns down to a few nanometers, is one of the fundamental pillars of nanofabrication. In the past decade, significant progress has been made in electron-beam-based nanofabrication, such as the emerging ice lithography (IL) technology, in which ice thin-films are used as resists and patterned by a focused electron-beam. The entire process of IL nanofabrication is sustainable and streamlined because spin coating and chemical developing steps commonly required for EBL resists are made needless.

A fresh review "Ice lithography for 3D nanofabrication" by Prof. Min Qiu at Westlake University is published in Science Bulletin. In this review, the authors present current status and future perspectives of ice lithography (IL). Different ice resists and IL instrument design are also introduced. Special emphasis is placed on advantages of IL for 3D nanofabrication.

The IL technology was first proposed by the Nanopore group at Harvard University in 2005. Water ice is the first identified ice resist for IL, and it is still the only one positive-tone lithography resist so far. As shown in Fig.1, water ice is easily removed within the electron-beam exposure area. Organic ice condensed from simple organic molecules, such as alkanes, demonstrates a negative-resist-like capability, which means only exposed patterns remain on the substrate after heating the sample to room temperature.

IL research is still in its infancy, and this method has already exhibited great advantages in efficient 3D nanofabrication. Different from spin coating of EBL resists, ice resists are able to coat all accessible freezing surfaces of the sample during ice deposition. Therefore, IL can process samples with non-flat and irregular surfaces, such as patterning on AFM probes, and pattern on a tiny and fragile nanostructure, such as suspended single-walled carbon nanotubes. Benefiting from the very low sensitivity of water ice, IL allows in situ observing nanostructures under the ice resist through SEM imaging. This feature not only improves the alignment accuracy but also simplifies the processing steps in fabricating 3D layered nanostructures.

As cutting-edge instrument research and development is essential for advancing the IL technology, this review finally discusses the evolution of IL instruments and provides a clear guidance on the construction of a dedicated IL instrument. With the discovery of new functional ice resists in future, more cutting-edge and interdisciplinary researches are expected to exploit the potentials of IL.

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This work was supported by the National Natural Science Foundation of China (Grant No. 61425023), National Key Research and Development Program of China (Grant No. 2017YFA0205700), European Union's Horizon 2020 research and innovation program under the Marie Skodowska-Curie grant agreement (Grant No. 713683).

See the article:

Ding Zhao, Anpan Han, and Min Qiu, Ice lithography for 3D nanofabrication, Science Bulletin, 2019, vol. 64, No.12, 865-871

https://www.sciencedirect.com/science/article/pii/S209592731930324X?via%3Dihub

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