Self‐Expansion Based Multi‐Patterning for 2D Materials Fabrication beyond the Lithographical Limit

Borhade, Poonam Subhash; Chen, Tawat; Chen, Ding‐Rui; Chen, Yu‐Xiang; Yao, Yu‐Chi; Yen, Zhi‐Long; Tsai, Chun Hsiung; Hsieh, Ya‐Ping; Hofmann, Mario

doi:10.1002/smll.202311209

Small

2023

DOI: 10.1002/smll.202311209

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Self‐Expansion Based Multi‐Patterning for 2D Materials Fabrication beyond the Lithographical Limit

Poonam Subhash Borhade,

Tawat Chen,

Ding‐Rui Chen

et al.

Abstract: Two‐dimensional (2D) materials are promising successors for silicon transistor channels in ultimately scaled devices, necessitating significant research efforts to study their behavior at nanoscopic length scales. Unfortunately, current research has limited itself to direct patterning approaches, which limit the achievable resolution to the diffraction limit and introduce unwanted defects into the 2D material. The potential of multi‐patterning to fabricate 2D materials features with unprecedented precision and… Show more

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2024

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Transferrable Alumina Membranes as High‐Performance Dielectric for Flexible 2D Materials Devices

Borhade,

Raman,

Yen

et al. 2024

Adv Elect Materials

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Abstract2D materials have shown great promise for novel electronic functionality. A common challenge for 2D materials‐based transistors is forming a high‐performance gate terminal due to the challenges of depositing a dielectric of sufficient quality and controllable thickness. Herein the van‐der‐Waals integration of a free‐standing Al2O3 dielectric membrane is demonstrated as a facile, scalable, and powerful gate dielectric. A process is developed that permits the wet transfer of an amorphous alumina layer with a finely adjustable equivalent oxide thickness (EOT) in the single nanometer range. Electrical characterization demonstrates the high breakdown field and low leakage of the dielectric and integration into 2D materials transistors reveals a high performance. The wafer‐scale uniformity of the dielectric membrane permits the formation of large‐scale flexible devices that exhibit good robustness and long‐term stability.

show abstract

Transferrable Alumina Membranes as High‐Performance Dielectric for Flexible 2D Materials Devices

Borhade,

Raman,

Yen

et al. 2024

Adv Elect Materials

Self Cite

View full text Add to dashboard Cite

show abstract

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Self‐Expansion Based Multi‐Patterning for 2D Materials Fabrication beyond the Lithographical Limit

Cited by 1 publication

References 46 publications

Transferrable Alumina Membranes as High‐Performance Dielectric for Flexible 2D Materials Devices

Transferrable Alumina Membranes as High‐Performance Dielectric for Flexible 2D Materials Devices

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