Abstract
Integrated photonic spectrographs offer an avenue to extreme miniaturization of astronomical instruments, which would greatly benefit extremely large telescopes and future space missions. These devices first require optimization for astronomical applications, which includes design, fabrication, and field testing. Given the high costs of photonic fabrication, multi-project wafer (MPW) silicon nitride (SiN) offerings, where a user purchases a portion of a wafer, provide a convenient and affordable avenue to develop this technology. In this work, we study the potential of two commonly used SiN waveguide geometries by MPW foundries, i.e., square and rectangular profiles, to determine how they affect the performance of mid/high-resolution arrayed waveguide grating (AWG) spectrometers around 1.5 µm. Specifically, we present results from detailed simulations on the mode sizes, shapes, and polarization properties, and on the impact of phase errors on the throughput and cross talk as well as some laboratory results of coupling and propagation losses. From the MPW run tolerances and our phase-error study, we estimate that an AWG with R ∼10,000 can be developed with the MPW runs, and even greater resolving power is achievable with more reliable, dedicated fabrication runs. Depending on the fabrication and design optimizations, it is possible to achieve throughputs ∼60% using the SiN platform. Thus, we show that SiN MPW offerings are highly promising and will play a key role in integrated photonic spectrograph developments for astronomy.
Highlights
The ability to spectroscopically characterize objects is one of the most powerful diagnostic tools in an astronomer’s arsenal
There are two main classes of waveguide geometries offered by silicon nitride (SiN) Multi-Project Wafer (MPW) foundries, namely square and rectangular core shapes and both show great promise for enabling astronomers to rapidly prototype devices. In this body of work, we demonstrate through simulation, the potential of developing midto-high resolving power (R = 5k to 10k) arrayed waveguide gratings (AWGs) based on SiN waveguides using the square and rectangular geometries of commercial MPWs
We explored the key structural and spectral properties of AWG spectrographs using commercial MPW geometries from an astronomical perspective
Summary
The ability to spectroscopically characterize objects is one of the most powerful diagnostic tools in an astronomer’s arsenal. It can be used to determine the chemical composition and abundances of constituents, as well as the relative velocity of the object with respect to the observer, which can constrain its distance. By combining this data with imaging, it is possible to get a global understanding of a wide variety of astrophysical targets spanning from planets all the way up to the structure of the Universe. The diameter of a seeing-limited spectrograph collimator increases as a function of the telescope diameter, which has the knock on effect of increasing the size of subsequent optics and the volume, mass and cost of the spectrograph [1]. Instrument size and cost are critical issues for the next-generation extremely large telescopes (ELTs), which have primary mirror diameters of > 24 m
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