On-sky speckle nulling through a single-mode fiber with the Keck Planet Imager and Characterizer

TL;DR

This paper demonstrates the first on-sky speckle nulling through an optical fiber using the KPIC instrument at Keck, reducing stellar leakage and improving exoplanet observation sensitivity.

Contribution

It presents the first on-sky demonstration of speckle nulling through a fiber with KPIC, showing significant reduction in stellar leakage and potential for enhanced exoplanet spectroscopy.

Findings

Achieved a 2.6 to 2.8 times reduction in stellar leakage.

Reduced required exposure time by a factor of 2.6 to 2.8.

Performance limited by speckle phase instability.

Abstract

The Keck Planet Imager and Characterizer (KPIC) is an instrument at the Keck II telescope that enables high-resolution spectroscopy of directly imaged exoplanets and substellar companions. KPIC uses single-mode fibers to couple the adaptive optics system to Keck's near-infrared spectrometer (NIRSPEC). However, KPIC's sensitivity at small separations is limited by the leakage of stellar light into the fiber. Speckle nulling uses a deformable mirror to destructively interfere starlight with itself, a technique typically used to reduce stellar signal on a focal-plane imaging detector. We present the first on-sky demonstration of speckle nulling through an optical fiber with KPIC, using NIRSPEC to collect exposures that measure speckle phase for quasi-real-time wavefront control while also serving as science data. We repeat iterations of measurement and correction, each using at least 5 exposures. We show a decrease in the on-sky leaked starlight by a factor of 2.6 to 2.8 in the targeted spectral order, at a spatial separation of 2.0 {\lambda}/D in K-band. This corresponds to an estimated factor of 2.6 to 2.8 decrease in the required exposure time to reach a given SNR, relative to conventional KPIC observations. The performance of speckle nulling is limited by instability in the speckle phase: when the loop is opened, the null-depth degrades by a factor of 2 on the timescale of a single phase measurement, which would limit the suppression that can be achieved. Future work includes exploring gradient-descent methods, which may be faster and thereby able to achieve deeper nulls. In the meantime, the speckle nulling algorithm demonstrated in this work can be used to decrease stellar leakage and improve the signal-to-noise of science observations.