Characterization of Orientation-Dependent Etching Properties and Surface Morphology of Sapphire Crystal in Wet Etching

“…This validated the fact that sapphire etching involves many slow-etch-rate planes. The above analyses presented the complex evolution of sapphire facets, which have been well documented with different etching mask layouts such as cavity and pyramids, , attributed to its trigonal crystal and strong etching selectivity between the sapphire crystal planes …”

“…These values are about 20 times smaller compared to the triangular window design [5715 ± 83.9% μm 2 (σ = 6813 μm 2 ) for 6°≤ α ≤ 18°; 5940 ± 81.7% μm 2 (σ = 7275 μm 2 ) for 42°≤ α ≤ 58°], indicating a uniquely wide-range layout design tolerance in crystal alignment where the membrane area remained almost constant. Besides, sapphire etching involves many slow-etch-rate crystal planes, which is very different from conventional silicon alkaline micromachining, where the final etched profile is mainly determined by a single slow-etch-rate (111) plane . This makes the etched profile in sapphire pretty complex and not only associated with the sapphire crystal plane but also significantly affected by the mask alignment .…”

“…Accordingly, Miller–Bravais indices { hkil } of the exposed sapphire facets in the cavity were calculated by building a hexagonal coordinate system (Figure S9, Table S2). As expected, the calculated indices cannot be directly linked to any of the typical crystallographic planes of sapphire . This validated the fact that sapphire etching involves many slow-etch-rate planes.…”

“…The above analyses presented the complex evolution of sapphire facets, which have been well documented with different etching mask layouts such as cavity 23 and pyramids, 20,24 attributed to its trigonal crystal and strong etching selectivity between the sapphire crystal planes. 21 2.3. Membrane Size Design and Fabrication Reproducibility.…”

Wafer-Scale Fabrication of Uniform, Micrometer-Sized, Triangular Membranes on Sapphire for High-Speed Protein Sensing in a Nanopore

“…This validated the fact that sapphire etching involves many slow-etch-rate planes. The above analyses presented the complex evolution of sapphire facets, which have been well documented with different etching mask layouts such as cavity and pyramids, , attributed to its trigonal crystal and strong etching selectivity between the sapphire crystal planes …”

“…These values are about 20 times smaller compared to the triangular window design [5715 ± 83.9% μm 2 (σ = 6813 μm 2 ) for 6°≤ α ≤ 18°; 5940 ± 81.7% μm 2 (σ = 7275 μm 2 ) for 42°≤ α ≤ 58°], indicating a uniquely wide-range layout design tolerance in crystal alignment where the membrane area remained almost constant. Besides, sapphire etching involves many slow-etch-rate crystal planes, which is very different from conventional silicon alkaline micromachining, where the final etched profile is mainly determined by a single slow-etch-rate (111) plane . This makes the etched profile in sapphire pretty complex and not only associated with the sapphire crystal plane but also significantly affected by the mask alignment .…”

“…Accordingly, Miller–Bravais indices { hkil } of the exposed sapphire facets in the cavity were calculated by building a hexagonal coordinate system (Figure S9, Table S2). As expected, the calculated indices cannot be directly linked to any of the typical crystallographic planes of sapphire . This validated the fact that sapphire etching involves many slow-etch-rate planes.…”

“…The above analyses presented the complex evolution of sapphire facets, which have been well documented with different etching mask layouts such as cavity 23 and pyramids, 20,24 attributed to its trigonal crystal and strong etching selectivity between the sapphire crystal planes. 21 2.3. Membrane Size Design and Fabrication Reproducibility.…”

Wafer-Scale Fabrication of Uniform, Micrometer-Sized, Triangular Membranes on Sapphire for High-Speed Protein Sensing in a Nanopore

Evolutionary Kinetic Monte Carlo Simulation of Anisotropic Wet Etching of Sapphire at Different Concentrations and Temperatures

An adaptive octree level set simulation method of the wet etching process for the fabrication of micro structure on sapphire crystal