Vector-apodizing phase plate coronagraph: design, current performance, and future development [Invited]

D. S. Doelman; F. Snik; E. H. Por; E. H. Por; S. P. Bos; G. P. P. L. Otten; G. P. P. L. Otten; M. Kenworthy; S. Y. Haffert; S. Y. Haffert; M. Wilby; A. J. Bohn; B. J. Sutlieff; B. J. Sutlieff; K. Miller; M. Ouellet; M. Ouellet; J. de Boer; C. U. Keller; M. J. Escuti; S. Shi; N. Z. Warriner; K. Hornburg; J. L. Birkby; J. L. Birkby; J. L. Birkby; J. Males; K. M. Morzinski; L. M. Close; J. Codona; J. Long; L. Schatz; J. Lumbres; J. Lumbres; A. Rodack; K. Van Gorkom; A. Hedglen; O. Guyon; O. Guyon; O. Guyon; O. Guyon; J. Lozi; T. Groff; J. Chilcote; N. Jovanovic; S. Thibault; C. de Jonge; G. Allain; C. Vallée; D. Patel; O. Côté; C. Marois; C. Marois; P. Hinz; P. Hinz; J. Stone; J. Stone; A. Skemer; Z. Briesemeister; A. Boehle; A. M. Glauser; W. Taylor; P. Baudoz; E. Huby; O. Absil; B. Carlomagno; C. Delacroix

doi:10.1364/AO.422155

Applied Optics
Vol. 60,
Issue 19,
pp. D52-D72
(2021)
•https://doi.org/10.1364/AO.422155

Vector-apodizing phase plate coronagraph: design, current performance, and future development [Invited]

D. S. Doelman, F. Snik, E. H. Por, S. P. Bos, G. P. P. L. Otten, M. Kenworthy, S. Y. Haffert, M. Wilby, A. J. Bohn, B. J. Sutlieff, K. Miller, M. Ouellet, J. de Boer, C. U. Keller, M. J. Escuti, S. Shi, N. Z. Warriner, K. Hornburg, J. L. Birkby, J. Males, K. M. Morzinski, L. M. Close, J. Codona, J. Long, L. Schatz, J. Lumbres, A. Rodack, K. Van Gorkom, A. Hedglen, O. Guyon, et al.

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D. S. Doelman, F. Snik, E. H. Por, S. P. Bos, G. P. P. L. Otten, M. Kenworthy, S. Y. Haffert, M. Wilby, A. J. Bohn, B. J. Sutlieff, K. Miller, M. Ouellet, J. de Boer, C. U. Keller, M. J. Escuti, S. Shi, N. Z. Warriner, K. Hornburg, J. L. Birkby, J. Males, K. M. Morzinski, L. M. Close, J. Codona, J. Long, L. Schatz, J. Lumbres, A. Rodack, K. Van Gorkom, A. Hedglen, O. Guyon, J. Lozi, T. Groff, J. Chilcote, N. Jovanovic, S. Thibault, C. de Jonge, G. Allain, C. Vallée, D. Patel, O. Côté, C. Marois, P. Hinz, J. Stone, A. Skemer, Z. Briesemeister, A. Boehle, A. M. Glauser, W. Taylor, P. Baudoz, E. Huby, O. Absil, B. Carlomagno, and C. Delacroix, "Vector-apodizing phase plate coronagraph: design, current performance, and future development [Invited]," Appl. Opt. 60, D52-D72 (2021)

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About this Article
History
- Original Manuscript: February 11, 2021
- Revised Manuscript: April 16, 2021
- Manuscript Accepted: April 19, 2021
- Published: May 13, 2021
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Applied Optics Joint Feature Issue with Applied Optics and Journal of the Optical Society of America B: Astrophotonics (2021)

JOSA B Joint Feature Issue with Applied Optics and Journal of the Optical Society of America B: Astrophotonics (2021)

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Abstract

Over the last decade, the vector-apodizing phase plate (vAPP) coronagraph has been developed from concept to on-sky application in many high-contrast imaging systems on 8 m class telescopes. The vAPP is a geometric-phase patterned coronagraph that is inherently broadband, and its manufacturing is enabled only by direct-write technology for liquid-crystal patterns. The vAPP generates two coronagraphic point spread functions (PSFs) that cancel starlight on opposite sides of the PSF and have opposite circular polarization states. The efficiency, that is, the amount of light in these PSFs, depends on the retardance offset from a half-wave of the liquid-crystal retarder. Using different liquid-crystal recipes to tune the retardance, different vAPPs operate with high efficiencies (${\gt}96\%$) in the visible and thermal infrared (0.55 µm to 5 µm). Since 2015, seven vAPPs have been installed in a total of six different instruments, including Magellan/MagAO, Magellan/MagAO-X, Subaru/SCExAO, and LBT/LMIRcam. Using two integral field spectrographs installed on the latter two instruments, these vAPPs can provide low-resolution spectra (${\rm{R}} \sim 30$) between 1 µm and 5 µm. We review the design process, development, commissioning, on-sky performance, and first scientific results of all commissioned vAPPs. We report on the lessons learned and conclude with perspectives for future developments and applications.

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Telescope	Instrument	Type	Inst.	$λ$ [µm]	MTR	Contrast	IWA [ $λ / D$ ]	OWA [ $λ / D$ ]	Strehl [%]	FPWFS
Magellan	MagAO/Clio	gvAPP $2 \times 180$	2015	2–5	3	$10^{- 5}$	2.0	7	39.8	–
WHT	LEXI	vAPP 360	2017	0.6–0.8	1	$10^{- 4}$	2.5	6	57.2	2
Subaru	SCExAO/CHARIS	gvAPP $2 \times 180$	2018	1–2.5	3	$10^{- 5}$	2.1	11	49.2	1 + 3
FC	HiCIBaS	gvAPP $2 \times 180$	2018	0.83–0.88	1	$10^{- 6}$	2.1	8.5	28.8	2 + 3
Magellan	MagAO-X	gvAPP $2 \times 180$	2018	0.55–0.9	3	$10^{- 5}$	2.1	15	40.7	1 + 2 + 3
LBT	LMIRcam	gvAPP $2 \times 180$	2018	2–5	3	$10^{- 5}$	1.8	15	52.6	3
LBT	LMIRcam/ALES	dgvAPP 360	2018	2–5	3	$10^{- 5}$	2.7	15	42.0	–
VLT	ERIS	gvAPP $2 \times 180$	2022	2–5	3	$10^{- 5}$	2.2	15	50.9	1
ELT	METIS	gvAPP $2 \times 180$	2028	2.9–5.3	3	$10^{- 5}$	2.5	20	63.8	1
ELT	MICADO	gvAPP $2 \times 180$	2026	1–2.5	3	$10^{- 5}$	2.6	20	68.8	–

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