From Lab Testing to Science: Applying SAPHIRA HgCdTe L-APD Detectors to Adaptive Optics

TL;DR

This paper demonstrates the application of SAPHIRA HgCdTe L-APD detectors in adaptive optics for astronomy, highlighting their high sensitivity, fast frame rates, and photon-counting capabilities, enabling advanced high-contrast observations.

Contribution

The study introduces the first science-grade SAPHIRA detectors used in adaptive optics, showcasing their wavefront sensing capabilities and impact on high-contrast astronomical imaging.

Findings

SAPHIRA detectors achieved high frame rates (~400 Hz full frame)

Demonstrated wavefront sensing behind pyramid optics

Enabled detailed debris disk morphology studies

Abstract

Due to their high frame rates, high sensitivity, low noise, and low dark current, SAPHIRA detectors provide new capabilities for astronomical observations. The SAPHIRA detector is a 320x256@24 $\mu$m pixel HgCdTe linear avalanche photodiode array manufactured by Leonardo. It is sensitive to 0.8-2.5 $\mu$m light. Unlike other near-infrared arrays, SAPHIRA features a user-adjustable avalanche gain, which multiplies the photon signal but has minimal impact on the read noise. This enables the equivalent of sub-electron read noise and therefore photon-counting performance, which has not previously been achieved with astronomical near-infrared arrays. SAPHIRA is intended for high clocking speeds, and we developed a new readout controller to utilize this capability and thereby enable the high frame rates ($\sim$400 Hz for the full frame or $\sim$1.7 kHz for a 128x128 pixel subarray). Beginning with the first science-grade SAPHIRA detectors and continuing with later improved devices, we deployed SAPHIRAs to the SCExAO instrument at Subaru Telescope. SCExAO is an extreme adaptive optics instrument intended for observations of high-contrast objects such as debris disks and extrasolar planets. While at SCExAO, we demonstrated the ability of SAPHIRA to function as a focal-plane wavefront sensor, and we performed extensive studies of speckle evolution. Our demonstration of SAPHIRA's ability to wavefront sense behind pyramid optics contributed to the decision to select a SAPHIRA detector and pyramid optics for the facility-class Keck Planet Imager. Additionally, we utilized the high Strehl provided by SCExAO to characterize the morphology of the HIP 79977 debris disk. Due largely to our characterization of the performance of SAPHIRA detectors and our demonstration of their capabilities, numerous facilities throughout the world have recently proposed to use them in instruments currently in development.