ALMA Band 9 upgrade: aA feasibility study

S. Realini; R. Hesper; J. Barkhof; A. Baryshev

doi:10.1051/epjconf/202429300043

ALMA Band 9 upgrade: aA feasibility study

S. Realini^*, R. Hesper, J. Barkhof, A. Baryshev

^*Corresponding author for this work

Astronomy

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › Academic › peer-review

Abstract

We present the results of a study on the feasibility of upgrading the existing ALMA Band 9 receivers (602-720 GHz). In the current configuration, each receiver is a dual channel heterodyne system capable of detecting orthogonally polarized signals through the use of a wire grid and a compact arrangement of mirrors. The main goals of the study are the upgrade of the mixer architecture from Double-Sideband (DSB) to Sideband-separating (2SB), the extension of the IF and RF bandwidth, and the analysis of the possibilities of improving the polarimetric performance. We demonstrate the performance of 2SB mixers both in the lab and on-sky with the SEPIA660 receiver at APEX, which shows image rejection ratios exceeding 20 dB and can perform successful observations of several spectral lines close to the band edges. The same architecture in ALMA Band 9 would lead to an increase in the effective spectral sensitivity and a gain of a factor two in observation time. We set up also an electromagnetic model of the optics to simulate the polarization performance of the receivers, which is currently limited by the cross-polar level and the beam squint, i.e. pointing mismatch between the two polarizations. We present the results of the simulations compared to the measurements and we conclude that the use of a polarizing grid is the main responsible of the limitations.

Original language	English
Title of host publication	mm Universe 2023 - Observing the Universe at mm Wavelengths
Editors	F. Mayet, A. Catalano, J.F. Macias-Perez, L. Perotto
Publisher	EDP Sciences
Number of pages	6
ISBN (Electronic)	9782759891252
DOIs	https://doi.org/10.1051/epjconf/202429300043
Publication status	Published - 28-Mar-2024
Event	3rd Observing the Universe at mm Wavelengths, mm Universe 2023 - Grenoble, France Duration: 26-Jun-2023 → 30-Jun-2023

Publication series

Name	EPJ Web of Conferences
Volume	293
ISSN (Print)	2101-6275
ISSN (Electronic)	2100-014X

Conference

Conference	3rd Observing the Universe at mm Wavelengths, mm Universe 2023
Country/Territory	France
City	Grenoble
Period	26/06/2023 → 30/06/2023

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ALMA Band 9 upgrade: aA feasibility studyFinal publisher's version, 929 KBLicence: CC BY

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title = "ALMA Band 9 upgrade: aA feasibility study",

abstract = "We present the results of a study on the feasibility of upgrading the existing ALMA Band 9 receivers (602-720 GHz). In the current configuration, each receiver is a dual channel heterodyne system capable of detecting orthogonally polarized signals through the use of a wire grid and a compact arrangement of mirrors. The main goals of the study are the upgrade of the mixer architecture from Double-Sideband (DSB) to Sideband-separating (2SB), the extension of the IF and RF bandwidth, and the analysis of the possibilities of improving the polarimetric performance. We demonstrate the performance of 2SB mixers both in the lab and on-sky with the SEPIA660 receiver at APEX, which shows image rejection ratios exceeding 20 dB and can perform successful observations of several spectral lines close to the band edges. The same architecture in ALMA Band 9 would lead to an increase in the effective spectral sensitivity and a gain of a factor two in observation time. We set up also an electromagnetic model of the optics to simulate the polarization performance of the receivers, which is currently limited by the cross-polar level and the beam squint, i.e. pointing mismatch between the two polarizations. We present the results of the simulations compared to the measurements and we conclude that the use of a polarizing grid is the main responsible of the limitations.",

author = "S. Realini and R. Hesper and J. Barkhof and A. Baryshev",

note = "Publisher Copyright: {\textcopyright} The Authors, published by EDP Sciences.; 3rd Observing the Universe at mm Wavelengths, mm Universe 2023 ; Conference date: 26-06-2023 Through 30-06-2023",

year = "2024",

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Realini, S, Hesper, R , Barkhof, J & Baryshev, A 2024, ALMA Band 9 upgrade: aA feasibility study. in F Mayet, A Catalano, JF Macias-Perez & L Perotto (eds), mm Universe 2023 - Observing the Universe at mm Wavelengths., 00043, EPJ Web of Conferences, vol. 293, EDP Sciences, 3rd Observing the Universe at mm Wavelengths, mm Universe 2023, Grenoble, France, 26/06/2023. https://doi.org/10.1051/epjconf/202429300043

ALMA Band 9 upgrade: aA feasibility study. / Realini, S.; Hesper, R.; Barkhof, J. et al.
mm Universe 2023 - Observing the Universe at mm Wavelengths. ed. / F. Mayet; A. Catalano; J.F. Macias-Perez; L. Perotto. EDP Sciences, 2024. 00043 (EPJ Web of Conferences; Vol. 293).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › Academic › peer-review

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T1 - ALMA Band 9 upgrade

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N2 - We present the results of a study on the feasibility of upgrading the existing ALMA Band 9 receivers (602-720 GHz). In the current configuration, each receiver is a dual channel heterodyne system capable of detecting orthogonally polarized signals through the use of a wire grid and a compact arrangement of mirrors. The main goals of the study are the upgrade of the mixer architecture from Double-Sideband (DSB) to Sideband-separating (2SB), the extension of the IF and RF bandwidth, and the analysis of the possibilities of improving the polarimetric performance. We demonstrate the performance of 2SB mixers both in the lab and on-sky with the SEPIA660 receiver at APEX, which shows image rejection ratios exceeding 20 dB and can perform successful observations of several spectral lines close to the band edges. The same architecture in ALMA Band 9 would lead to an increase in the effective spectral sensitivity and a gain of a factor two in observation time. We set up also an electromagnetic model of the optics to simulate the polarization performance of the receivers, which is currently limited by the cross-polar level and the beam squint, i.e. pointing mismatch between the two polarizations. We present the results of the simulations compared to the measurements and we conclude that the use of a polarizing grid is the main responsible of the limitations.

AB - We present the results of a study on the feasibility of upgrading the existing ALMA Band 9 receivers (602-720 GHz). In the current configuration, each receiver is a dual channel heterodyne system capable of detecting orthogonally polarized signals through the use of a wire grid and a compact arrangement of mirrors. The main goals of the study are the upgrade of the mixer architecture from Double-Sideband (DSB) to Sideband-separating (2SB), the extension of the IF and RF bandwidth, and the analysis of the possibilities of improving the polarimetric performance. We demonstrate the performance of 2SB mixers both in the lab and on-sky with the SEPIA660 receiver at APEX, which shows image rejection ratios exceeding 20 dB and can perform successful observations of several spectral lines close to the band edges. The same architecture in ALMA Band 9 would lead to an increase in the effective spectral sensitivity and a gain of a factor two in observation time. We set up also an electromagnetic model of the optics to simulate the polarization performance of the receivers, which is currently limited by the cross-polar level and the beam squint, i.e. pointing mismatch between the two polarizations. We present the results of the simulations compared to the measurements and we conclude that the use of a polarizing grid is the main responsible of the limitations.

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M3 - Conference contribution

AN - SCOPUS:85212204785

T3 - EPJ Web of Conferences

BT - mm Universe 2023 - Observing the Universe at mm Wavelengths

A2 - Mayet, F.

A2 - Catalano, A.

A2 - Macias-Perez, J.F.

A2 - Perotto, L.

PB - EDP Sciences

Y2 - 26 June 2023 through 30 June 2023

ER -

ALMA Band 9 upgrade: aA feasibility study

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