Abstract
As one of the important technologies in the field of heterogeneous integration, transfer technology has broad application prospects and unique technical advantages. This transfer technology includes the wet chemical etching of a sacrificial layer, such that silicon nano-film devices are released from the donor substrate and can be transferred. However, in the process of wet etching the SiO2 sacrificial layer present underneath the single-crystal silicon nano-film by using the transfer technology, the etching is often incomplete, which seriously affects the efficiency and quality of the transfer and makes the device preparation impossible. This article analyzes the principle of incomplete etching, and compares the four factors that affect the etching process, including the size of Si nano-film on top of the sacrificial layer, the location of the anchor point, the shape of Si nano-film on top of the sacrificial layer, and the thickness of the sacrificial layer. Finally, the etching conditions are obtained to avoid the phenomenon of incomplete etching of the sacrificial layer, so that the transfer technology can be better applied in the field of heterogeneous integration. Additionally, Si MOSFETs (Metal-Oxide-Semiconductor Field Effect Transistors) on sapphire substrate were fabricated by using the optimized transfer technology.
Highlights
Published: 16 November 2021In the past few decades, under the guidance of Moore’s Law, the minimum size of silicon-based electronic devices has gradually decreased, and the performance and computing speed of circuits have continuously increased
Single-crystal silicon nano-films have unique optical and thermal properties that are different from silicon bulk materials
The sacrificial layer should be designed as a rectangle ness should be chosen
Summary
In the past few decades, under the guidance of Moore’s Law, the minimum size of silicon-based electronic devices has gradually decreased, and the performance and computing speed of circuits have continuously increased. Due to the physical limitations, in the foreseeable future, the size of silicon-based devices can no longer continue to shrink and meet the Moore’s Law [1]. At this time, single-crystal silicon nano-films and compound semiconductor materials have attracted widespread attention due to their unique advantages. Nanomaterials 2021, 11, 3085 other heterogeneous integration technologies, transfer technology has many advantages. The transfer object can be simple nanowires, two-dimensional structures, or even complex three-dimensional structures [10,11,12,13,14] This makes the transfer technology compatible with many other processing technologies.
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