Abstract
Chlorine processes are widely used for the formation of waveguide structures in InP-based optoelectronics. Traditionally, ICP etching of InP in a Cl2-based plasma requires substrate temperatures in the range of 150–200 °C. This condition is mandatory, since during the etching process low-volatility InClx components are formed and at insufficient temperatures are deposited onto substrate, leading to the formation of defects and further impossibility of the formation of waveguide structures. The need to preheat the substrate limits the application of chlorine processes. This paper presents a method of ICP etching an InP/InGaAsP heterostructure in a Cl2/Ar/N2 gas mixture. A feature of the developed method is the cyclic etching of the heterostructure without preliminary heating. The etching process starts at room temperature. In the optimal etching mode, the angle of inclination of the sidewalls of the waveguides reached 88.8° at an etching depth of more than 4.5 μm. At the same time, the surface roughness did not exceed 30 nm. The selectivity of the etching process with respect to the SiNx mask was equal to 9. Using the developed etching method, test integrated waveguide elements were fabricated. The fabricated active integrated waveguide (p-InP epitaxial layers were not removed) with a width of 2 μm demonstrated an optical loss around 11 ± 1.5 dB/cm at 1550 nm. The insertion loss of the developed Y- and MMI-splitters did not exceed 0.8 dB.
Highlights
Published: 10 December 2021At present, integrated optoelectronics continues to be a dynamically evolved area
This is primarily facilitated by the fact that photonic integrated circuits (PICs) are widely used in the construction of telecommunication networks
The aim of this research was to develop a method for inductively coupled plasma (ICP) etching of a p-i-n InP/
Summary
At present, integrated optoelectronics continues to be a dynamically evolved area. This is primarily facilitated by the fact that photonic integrated circuits (PICs) are widely used in the construction of telecommunication networks. Growing volumes of data traffic require an infrastructure that is built on a corresponding component base. Traditional electric communication lines have long ceased to satisfy the demand for bandwidth, and the backbone data transmission lines; today they are actively being replaced to connect the end users. The application of PICs is not limited to the telecommunication market. They find application in recognition and sensing tools, optical signal processing, biophotonics, high-speed computing, sources of coherent and incoherent light, etc. Indium phosphide is one of the basic materials that make it possible to create both active and passive elements [1,2,3,4]
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