4.8 Article

Hybrid Dry and Wet Etching of LiNbO3 Domain-Wall Memory Devices with 90° Etching Angles and Excellent Electrical Properties

Journal

ACS APPLIED MATERIALS & INTERFACES
Volume 15, Issue 44, Pages 51935-51943

Publisher

AMER CHEMICAL SOC
DOI: 10.1021/acsami.3c11445

Keywords

LiNbO3; etching; nanodevice; domain wall; oxygen vacancy; ferroelectric memory

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Ferroelectric domain walls, as agile nanoscale interfaces of polar order, can be selectively controlled by electric fields for their position, conformation, and function, which is ultimately crucial for realizing novel low-energy memory and computing structures. This study employed a hybrid etching technique to achieve smooth sidewalls in LiNbO3 domain wall memories, resulting in improved electrical performance and providing a new strategy for the development of LiNbO3 photonic devices.
Ferroelectric domain walls, agile nanoscale interfaces of polar order, can be selectively controlled by electric fields for their position, conformation, and function, which is ultimately the key to realizing novel low-energy memory and computing structures. LiNbO3 single-crystal domain wall memory has the advantages of high operational speed, high integration density, and virtually unlimited endurance cycles, appearing as a good solution for the next generation of highly miniaturized low-energy memories. However, the etching process poses significant challenges in the nanofabrication and high-density integration of LiNbO3 domain-wall memories. Here, we employed a hybrid etching technique to achieve smooth sidewalls with a 90 degrees inclined angle, leading to a 24% reduction in the coercive field and a 2.5-fold increase in the linear domain wall current density with a retention time of more than 10(6) seconds and endurance of over 10(5) writing cycles. Combined with the results of X-ray diffraction patterns and X-ray photoelectric spectra, it is concluded that the excellent electrical performance is related to the formation of an oxygen-deficient LiNbO3-x layer on the sidewall surface during the wet chemical etching process, which is a conductive layer that reduces the thickness of the dead layer between the side electrodes and the LiNbO3 cell and rectifies the diode-like wall currents with an onset voltage reduced from 1.23 to 0.28 V. These results prove the high-density integration of ferroelectric domain-wall memories at the nanoscale and provide a new strategy applicable to the development of LiNbO3 photonic devices.

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