Euclid preparation: XXIX. Water ice in spacecraft Part I: The physics of ice formation and contamination

M. Schirmer; K. Thürmer; B. Bras; M. Cropper; J. Martin-Fleitas; Y. Goueffon; R. Kohley; A. Mora; M. Portaluppi; G. D. Racca; A. D. Short; S. Szmolka; L. M.Gaspar Venancio; M. Altmann; Z. Balog; U. Bastian; M. Biermann; D. Busonero; C. Fabricius; F. Grupp; C. Jordi; W. Löffler; A. Sagrista Sellés; N. Aghanim; A. Amara; L. Amendola; M. Baldi; C. Bodendorf; D. Bonino; E. Branchini; M. Brescia; J. Brinchmann; S. Camera; G. P. Candini; V. Capobianco; C. Carbone; J. Carretero; M. Castellano; S. Cavuoti; A. Cimatti; R. Cledassou; G. Congedo; C. J. Conselice; L. Conversi; Y. Copin; L. Corcione; F. Courbin; A. Da Silva; H. Degaudenzi; A. M. Di Giorgio; J. Dinis; F. Dubath; X. Dupac; S. Dusini; S. Farrens; S. Ferriol; M. Frailis; E. Franceschi; M. Fumana; S. Galeotta; B. Garilli; W. Gillard; B. Gillis; C. Giocoli; S. V.H. Haugan; H. Hoekstra; W. Holmes; F. Hormuth; A. Hornstrup; K. Jahnke; S. Kermiche; A. Kiessling; M. Kilbinger; T. Kitching; M. Kunz; H. Kurki-Suonio; S. Ligori; P. B. Lilje; I. Lloro; E. Maiorano; O. Mansutti; O. Marggraf; K. Markovic; F. Marulli; R. Massey; E. Medinaceli; S. Mei; Y. Mellier; M. Meneghetti; E. Merlin; G. Meylan; M. Moresco; L. Moscardini; E. Munari; R. Nakajima; S. M. Niemi; J. W. Nightingale; T. Nutma; C. Padilla; S. Paltani; F. Pasian; V. Pettorino; S. Pires; G. Polenta; M. Poncet; L. A. Popa; F. Raison; A. Renzi; J. Rhodes; G. Riccio; E. Romelli; M. Roncarelli; E. Rossetti; R. Saglia; D. Sapone; B. Sartoris; P. Schneider; A. Secroun; G. Seidel; S. Serrano; C. Sirignano; G. Sirri; J. Skottfelt; L. Stanco; P. Tallada-Crespí; A. N. Taylor; I. Tereno; R. Toledo-Moreo; I. Tutusaus; E. A. Valentijn; L. Valenziano; T. Vassallo; Y. Wang; J. Weller; A. Zacchei; J. Zoubian; S. Andreon; S. Bardelli; P. Battaglia; E. Bozzo; C. Colodro-Conde; M. Farina; J. Graciá-Carpio; E. Keihänen; V. Lindholm; D. Maino; N. Mauri; N. Morisset; V. Scottez; M. Tenti; E. Zucca; Y. Akrami; C. Baccigalupi; M. Ballardini; A. Biviano; A. Blanchard; A. S. Borlaff; C. Burigana; R. Cabanac; A. Cappi; C. S. Carvalho; S. Casas; G. Castignani; T. Castro; K. C. Chambers; A. R. Cooray; J. Coupon; H. M. Courtois; J. G. Cuby; S. Davini; G. De Lucia; G. Desprez; S. Di Domizio; H. Dole; J. A. Escartin; S. Escoffier; I. Ferrero; L. Gabarra; K. Ganga; J. Garcia-Bellido; K. George; F. Giacomini; G. Gozaliasl; H. Hildebrandt; J. J.E. Kajava; V. Kansal; C. C. Kirkpatrick; L. Legrand; P. Liebing; A. Loureiro; G. Maggio; M. Magliocchetti; G. Mainetti; R. Maoli; S. Marcin; M. Martinelli; N. Martinet; C. J.A.P. Martins; S. Matthew; M. Maturi; L. Maurin; R. B. Metcalf; P. Monaco; G. Morgante; S. Nadathur; A. A. Nucita; L. Patrizii; J. E. Pollack; V. Popa; D. Potter; M. Pöntinen; A. G. Sánchez; Z. Sakr; A. Schneider; M. Sereno; A. Shulevski; P. Simon; J. Steinwagner; R. Teyssier; J. Valiviita

doi:10.1051/0004-6361/202346635

Euclid preparation: XXIX. Water ice in spacecraft Part I: The physics of ice formation and contamination

M. Schirmer
, K. Thürmer
, B. Bras
, M. Cropper
, J. Martin-Fleitas
, Y. Goueffon
, R. Kohley
, A. Mora
, M. Portaluppi
, G. D. Racca
, A. D. Short
, S. Szmolka
, L. M.Gaspar Venancio
, M. Altmann
, Z. Balog
, U. Bastian
, M. Biermann
, D. Busonero
, C. Fabricius
, F. Grupp

C. Jordi, W. Löffler, A. Sagrista Sellés, N. Aghanim, A. Amara, L. Amendola, M. Baldi, C. Bodendorf, D. Bonino, E. Branchini, M. Brescia, J. Brinchmann, S. Camera, G. P. Candini, V. Capobianco, C. Carbone, J. Carretero, M. Castellano, S. Cavuoti, A. Cimatti, R. Cledassou, G. Congedo, C. J. Conselice, L. Conversi, Y. Copin, L. Corcione, F. Courbin, A. Da Silva, H. Degaudenzi, A. M. Di Giorgio, J. Dinis, F. Dubath, X. Dupac, S. Dusini, S. Farrens, S. Ferriol, M. Frailis, E. Franceschi, M. Fumana, S. Galeotta, B. Garilli, W. Gillard, B. Gillis, C. Giocoli, S. V.H. Haugan, H. Hoekstra, W. Holmes, F. Hormuth, A. Hornstrup, K. Jahnke, S. Kermiche, A. Kiessling, M. Kilbinger, T. Kitching, M. Kunz, H. Kurki-Suonio, S. Ligori, P. B. Lilje, I. Lloro, E. Maiorano, O. Mansutti, O. Marggraf, K. Markovic, F. Marulli, R. Massey, E. Medinaceli, S. Mei, Y. Mellier, M. Meneghetti, E. Merlin, G. Meylan, M. Moresco, L. Moscardini, E. Munari, R. Nakajima, S. M. Niemi, J. W. Nightingale, T. Nutma, C. Padilla, S. Paltani, F. Pasian, V. Pettorino, S. Pires, G. Polenta, M. Poncet, L. A. Popa, F. Raison, A. Renzi, J. Rhodes, G. Riccio, E. Romelli, M. Roncarelli, E. Rossetti, R. Saglia, D. Sapone, B. Sartoris, P. Schneider, A. Secroun, G. Seidel, S. Serrano, C. Sirignano, G. Sirri, J. Skottfelt, L. Stanco, P. Tallada-Crespí, A. N. Taylor, I. Tereno, R. Toledo-Moreo, I. Tutusaus, E. A. Valentijn, L. Valenziano, T. Vassallo, Y. Wang, J. Weller, A. Zacchei, J. Zoubian, S. Andreon, S. Bardelli, P. Battaglia, E. Bozzo, C. Colodro-Conde, M. Farina, J. Graciá-Carpio, E. Keihänen, V. Lindholm, D. Maino, N. Mauri, N. Morisset, V. Scottez, M. Tenti, E. Zucca, Y. Akrami, C. Baccigalupi, M. Ballardini, A. Biviano, A. Blanchard, A. S. Borlaff, C. Burigana, R. Cabanac, A. Cappi, C. S. Carvalho, S. Casas, G. Castignani, T. Castro, K. C. Chambers, A. R. Cooray, J. Coupon, H. M. Courtois, J. G. Cuby, S. Davini, G. De Lucia, G. Desprez, S. Di Domizio, H. Dole, J. A. Escartin, S. Escoffier, I. Ferrero, L. Gabarra, K. Ganga, J. Garcia-Bellido, K. George, F. Giacomini, G. Gozaliasl, H. Hildebrandt, J. J.E. Kajava, V. Kansal, C. C. Kirkpatrick, L. Legrand, P. Liebing, A. Loureiro, G. Maggio, M. Magliocchetti, G. Mainetti, R. Maoli, S. Marcin, M. Martinelli, N. Martinet, C. J.A.P. Martins, S. Matthew, M. Maturi, L. Maurin, R. B. Metcalf, P. Monaco, G. Morgante, S. Nadathur, A. A. Nucita, L. Patrizii, J. E. Pollack, V. Popa, D. Potter, M. Pöntinen, A. G. Sánchez, Z. Sakr, A. Schneider, M. Sereno, A. Shulevski, P. Simon, J. Steinwagner, R. Teyssier, J. Valiviita

Max Planck Institute for Astronomy
Sandia National Laboratories
ESTEC
University College London
Airbus Group
European Space Agency - ESA
Heidelberg University
Ludwig Maximilian University of Munich
Université Paris-Saclay
University of Portsmouth
University of Genoa
University of Naples Federico II
University of Porto
Institute for High Energy Physics
Centre national d'études spatiales
University of Manchester
ESRIN - ESA Centre for Earth Observation
Universite Claude Bernard Lyon 1
Swiss Federal Institute of Technology Lausanne
University of Lisbon
University of Geneva
CNRS
University of Oslo
Leiden University
California Institute of Technology
von Hoerner & Sulger GmbH
University of Helsinki
Netherlands Institute for Radio Astronomy
University of Bonn
Durham University
Université Paris 7
Institut de recherche sur les lois fondamentales de l'Univers
Italian Space Agency
Universidad de Chile
Open University Milton Keynes
CIEMAT
Technical University of Cartagena
Instituto de Astrofísica de Canarias
University of Milan
Sorbonne Université
University of Ferrara
NASA Ames Research Center
RWTH Aachen University
University of Hawai'i at Mānoa
University of California at Irvine
Ruhr University Bochum
University of Turku
University of Rome La Sapienza
University of Applied Sciences Northwestern Switzerland
University of Salento
University of Zurich
Princeton University
Aurora Technology B.V.
Institute of Space Science
Institut d’Astrophysique de Paris
European Space Astronomy Centre
National Institute for Astrophysics
University of Barcelona
Institute of Space Studies of Catalonia
University of Bologna
Max Planck Institute for Extraterrestrial Physics
Istituto di Astrofisica Spaziale e Fisica Cosmica di Bologna
Osservatorio Astronomico di Capodimonte
University of Padua
University of Groningen
University of Trieste
CSIC-UAM - Institute of Theoretical Physics
Imperial College London
Institut national de physique nucléaire et de physique des particules
Saint Mary's University Halifax
National Institute for Nuclear Physics
Osservatorio Astronomico Roma
University of Edinburgh
Osservatorio Astronomico di Trieste
Université Paul Sabatier Toulouse III

Research output: Contribution to journal › Journal article › Research › peer-review

115 Downloads (Orbit)

Abstract

Material outgassing in a vacuum leads to molecular contamination, a well-known problem in spaceflight. Water is the most common contaminant in cryogenic spacecraft, altering numerous properties of optical systems. Too much ice means that Euclida's calibration requirements cannot be met anymore. Euclid must then be thermally decontaminated, which is a month-long risky operation. We need to understand how ice affects our data to build adequate calibration and survey plans. A comprehensive analysis in the context of an astrophysical space survey has not been done before. In this paper we look at other spacecraft with well-documented outgassing records. We then review the formation of thin ice films, and find that for Euclid a mix of amorphous and crystalline ices is expected. Their surface topography-and thus optical properties-depend on the competing energetic needs of the substrate-water and the water-water interfaces, and they are hard to predict with current theories. We illustrate that with scanning-tunnelling and atomic-force microscope images of thin ice films. Sophisticated tools exist to compute contamination rates, and we must understand their underlying physical principles and uncertainties. We find considerable knowledge errors on the diffusion and sublimation coefficients, limiting the accuracy of outgassing estimates. We developed a water transport model to compute contamination rates in Euclid, and find agreement with industry estimates within the uncertainties. Tests of the Euclid flight hardware in space simulators did not pick up significant contamination signals, but they were also not geared towards this purpose; our in-flight calibration observations will be much more sensitive. To derive a calibration and decontamination strategy, we need to understand the link between the amount of ice in the optics and its effect on the data. There is little research about this, possibly because other spacecraft can decontaminate more easily, quenching the need for a deeper understanding. In our second paper, we quantify the impact of iced optics on Euclida's data.

Original language	English
Article number	A142
Journal	Astronomy and Astrophysics
Volume	675
Number of pages	34
ISSN	0004-6361
DOIs	https://doi.org/10.1051/0004-6361/202346635
Publication status	Published - 2023

Keywords

Molecular processes
Solid state: volatile
Space vehicles
Space vehicles: instruments
Telescopes

Access to Document

10.1051/0004-6361/202346635Licence: CC BY

FulltextFinal published version, 6.11 MBLicence: CC BY

OpenUrl availability

Check availability in DTU Findit

Cite this

Schirmer, M., Thürmer, K., Bras, B., Cropper, M., Martin-Fleitas, J., Goueffon, Y., Kohley, R., Mora, A., Portaluppi, M., Racca, G. D., Short, A. D., Szmolka, S., Venancio, L. M. G., Altmann, M., Balog, Z., Bastian, U., Biermann, M., Busonero, D., Fabricius, C., ... Valiviita, J. (2023). Euclid preparation: XXIX. Water ice in spacecraft Part I: The physics of ice formation and contamination. Astronomy and Astrophysics, 675, Article A142. https://doi.org/10.1051/0004-6361/202346635

@article{6146f070da4549b6a9a65eae2577f00f,

title = "Euclid preparation: XXIX. Water ice in spacecraft Part I: The physics of ice formation and contamination",

abstract = "Material outgassing in a vacuum leads to molecular contamination, a well-known problem in spaceflight. Water is the most common contaminant in cryogenic spacecraft, altering numerous properties of optical systems. Too much ice means that Euclida's calibration requirements cannot be met anymore. Euclid must then be thermally decontaminated, which is a month-long risky operation. We need to understand how ice affects our data to build adequate calibration and survey plans. A comprehensive analysis in the context of an astrophysical space survey has not been done before. In this paper we look at other spacecraft with well-documented outgassing records. We then review the formation of thin ice films, and find that for Euclid a mix of amorphous and crystalline ices is expected. Their surface topography-and thus optical properties-depend on the competing energetic needs of the substrate-water and the water-water interfaces, and they are hard to predict with current theories. We illustrate that with scanning-tunnelling and atomic-force microscope images of thin ice films. Sophisticated tools exist to compute contamination rates, and we must understand their underlying physical principles and uncertainties. We find considerable knowledge errors on the diffusion and sublimation coefficients, limiting the accuracy of outgassing estimates. We developed a water transport model to compute contamination rates in Euclid, and find agreement with industry estimates within the uncertainties. Tests of the Euclid flight hardware in space simulators did not pick up significant contamination signals, but they were also not geared towards this purpose; our in-flight calibration observations will be much more sensitive. To derive a calibration and decontamination strategy, we need to understand the link between the amount of ice in the optics and its effect on the data. There is little research about this, possibly because other spacecraft can decontaminate more easily, quenching the need for a deeper understanding. In our second paper, we quantify the impact of iced optics on Euclida's data.",

keywords = "Molecular processes, Solid state: volatile, Space vehicles, Space vehicles: instruments, Telescopes",

author = "M. Schirmer and K. Th{\"u}rmer and B. Bras and M. Cropper and J. Martin-Fleitas and Y. Goueffon and R. Kohley and A. Mora and M. Portaluppi and Racca, \{G. D.\} and Short, \{A. D.\} and S. Szmolka and Venancio, \{L. M.Gaspar\} and M. Altmann and Z. Balog and U. Bastian and M. Biermann and D. Busonero and C. Fabricius and F. Grupp and C. Jordi and W. L{\"o}ffler and Sell{\'e}s, \{A. Sagrista\} and N. Aghanim and A. Amara and L. Amendola and M. Baldi and C. Bodendorf and D. Bonino and E. Branchini and M. Brescia and J. Brinchmann and S. Camera and Candini, \{G. P.\} and V. Capobianco and C. Carbone and J. Carretero and M. Castellano and S. Cavuoti and A. Cimatti and R. Cledassou and G. Congedo and Conselice, \{C. J.\} and L. Conversi and Y. Copin and L. Corcione and F. Courbin and \{Da Silva\}, A. and H. Degaudenzi and \{Di Giorgio\}, \{A. M.\} and J. Dinis and F. Dubath and X. Dupac and S. Dusini and S. Farrens and S. Ferriol and M. Frailis and E. Franceschi and M. Fumana and S. Galeotta and B. Garilli and W. Gillard and B. Gillis and C. Giocoli and Haugan, \{S. V.H.\} and H. Hoekstra and W. Holmes and F. Hormuth and A. Hornstrup and K. Jahnke and S. Kermiche and A. Kiessling and M. Kilbinger and T. Kitching and M. Kunz and H. Kurki-Suonio and S. Ligori and Lilje, \{P. B.\} and I. Lloro and E. Maiorano and O. Mansutti and O. Marggraf and K. Markovic and F. Marulli and R. Massey and E. Medinaceli and S. Mei and Y. Mellier and M. Meneghetti and E. Merlin and G. Meylan and M. Moresco and L. Moscardini and E. Munari and R. Nakajima and Niemi, \{S. M.\} and Nightingale, \{J. W.\} and T. Nutma and C. Padilla and S. Paltani and F. Pasian and V. Pettorino and S. Pires and G. Polenta and M. Poncet and Popa, \{L. A.\} and F. Raison and A. Renzi and J. Rhodes and G. Riccio and E. Romelli and M. Roncarelli and E. Rossetti and R. Saglia and D. Sapone and B. Sartoris and P. Schneider and A. Secroun and G. Seidel and S. Serrano and C. Sirignano and G. Sirri and J. Skottfelt and L. Stanco and P. Tallada-Cresp{\'i} and Taylor, \{A. N.\} and I. Tereno and R. Toledo-Moreo and I. Tutusaus and Valentijn, \{E. A.\} and L. Valenziano and T. Vassallo and Y. Wang and J. Weller and A. Zacchei and J. Zoubian and S. Andreon and S. Bardelli and P. Battaglia and E. Bozzo and C. Colodro-Conde and M. Farina and J. Graci{\'a}-Carpio and E. Keih{\"a}nen and V. Lindholm and D. Maino and N. Mauri and N. Morisset and V. Scottez and M. Tenti and E. Zucca and Y. Akrami and C. Baccigalupi and M. Ballardini and A. Biviano and A. Blanchard and Borlaff, \{A. S.\} and C. Burigana and R. Cabanac and A. Cappi and Carvalho, \{C. S.\} and S. Casas and G. Castignani and T. Castro and Chambers, \{K. C.\} and Cooray, \{A. R.\} and J. Coupon and Courtois, \{H. M.\} and Cuby, \{J. G.\} and S. Davini and \{De Lucia\}, G. and G. Desprez and \{Di Domizio\}, S. and H. Dole and Escartin, \{J. A.\} and S. Escoffier and I. Ferrero and L. Gabarra and K. Ganga and J. Garcia-Bellido and K. George and F. Giacomini and G. Gozaliasl and H. Hildebrandt and Kajava, \{J. J.E.\} and V. Kansal and Kirkpatrick, \{C. C.\} and L. Legrand and P. Liebing and A. Loureiro and G. Maggio and M. Magliocchetti and G. Mainetti and R. Maoli and S. Marcin and M. Martinelli and N. Martinet and Martins, \{C. J.A.P.\} and S. Matthew and M. Maturi and L. Maurin and Metcalf, \{R. B.\} and P. Monaco and G. Morgante and S. Nadathur and Nucita, \{A. A.\} and L. Patrizii and Pollack, \{J. E.\} and V. Popa and D. Potter and M. P{\"o}ntinen and S{\'a}nchez, \{A. G.\} and Z. Sakr and A. Schneider and M. Sereno and A. Shulevski and P. Simon and J. Steinwagner and R. Teyssier and J. Valiviita",

note = "Publisher Copyright: {\textcopyright} 2023 Authors",

year = "2023",

doi = "10.1051/0004-6361/202346635",

language = "English",

volume = "675",

journal = "Astronomy and Astrophysics",

issn = "0004-6361",

publisher = "EDP Sciences",

}

Schirmer, M, Thürmer, K, Bras, B, Cropper, M, Martin-Fleitas, J, Goueffon, Y, Kohley, R, Mora, A, Portaluppi, M, Racca, GD, Short, AD, Szmolka, S, Venancio, LMG, Altmann, M, Balog, Z, Bastian, U, Biermann, M, Busonero, D, Fabricius, C, Grupp, F, Jordi, C, Löffler, W, Sellés, AS, Aghanim, N, Amara, A, Amendola, L, Baldi, M, Bodendorf, C, Bonino, D, Branchini, E, Brescia, M, Brinchmann, J, Camera, S, Candini, GP, Capobianco, V, Carbone, C, Carretero, J, Castellano, M, Cavuoti, S, Cimatti, A, Cledassou, R, Congedo, G, Conselice, CJ, Conversi, L, Copin, Y, Corcione, L, Courbin, F, Da Silva, A, Degaudenzi, H, Di Giorgio, AM, Dinis, J, Dubath, F, Dupac, X, Dusini, S, Farrens, S, Ferriol, S, Frailis, M, Franceschi, E, Fumana, M, Galeotta, S, Garilli, B, Gillard, W, Gillis, B, Giocoli, C, Haugan, SVH, Hoekstra, H, Holmes, W, Hormuth, F, Hornstrup, A, Jahnke, K, Kermiche, S, Kiessling, A, Kilbinger, M, Kitching, T, Kunz, M, Kurki-Suonio, H, Ligori, S, Lilje, PB, Lloro, I, Maiorano, E, Mansutti, O, Marggraf, O, Markovic, K, Marulli, F, Massey, R, Medinaceli, E, Mei, S, Mellier, Y, Meneghetti, M, Merlin, E, Meylan, G, Moresco, M, Moscardini, L, Munari, E, Nakajima, R, Niemi, SM, Nightingale, JW, Nutma, T, Padilla, C, Paltani, S, Pasian, F, Pettorino, V, Pires, S, Polenta, G, Poncet, M, Popa, LA, Raison, F, Renzi, A, Rhodes, J, Riccio, G, Romelli, E, Roncarelli, M, Rossetti, E, Saglia, R, Sapone, D, Sartoris, B, Schneider, P, Secroun, A, Seidel, G, Serrano, S, Sirignano, C, Sirri, G, Skottfelt, J, Stanco, L, Tallada-Crespí, P, Taylor, AN, Tereno, I, Toledo-Moreo, R, Tutusaus, I, Valentijn, EA, Valenziano, L, Vassallo, T, Wang, Y, Weller, J, Zacchei, A, Zoubian, J, Andreon, S, Bardelli, S, Battaglia, P, Bozzo, E, Colodro-Conde, C, Farina, M, Graciá-Carpio, J, Keihänen, E, Lindholm, V, Maino, D, Mauri, N, Morisset, N, Scottez, V, Tenti, M, Zucca, E, Akrami, Y, Baccigalupi, C, Ballardini, M, Biviano, A, Blanchard, A, Borlaff, AS, Burigana, C, Cabanac, R, Cappi, A, Carvalho, CS, Casas, S, Castignani, G, Castro, T, Chambers, KC, Cooray, AR, Coupon, J, Courtois, HM, Cuby, JG, Davini, S, De Lucia, G, Desprez, G, Di Domizio, S, Dole, H, Escartin, JA, Escoffier, S, Ferrero, I, Gabarra, L, Ganga, K, Garcia-Bellido, J, George, K, Giacomini, F, Gozaliasl, G, Hildebrandt, H, Kajava, JJE, Kansal, V, Kirkpatrick, CC, Legrand, L, Liebing, P, Loureiro, A, Maggio, G, Magliocchetti, M, Mainetti, G, Maoli, R, Marcin, S, Martinelli, M, Martinet, N, Martins, CJAP, Matthew, S, Maturi, M, Maurin, L, Metcalf, RB, Monaco, P, Morgante, G, Nadathur, S, Nucita, AA, Patrizii, L, Pollack, JE, Popa, V, Potter, D, Pöntinen, M, Sánchez, AG, Sakr, Z, Schneider, A, Sereno, M, Shulevski, A, Simon, P, Steinwagner, J, Teyssier, R & Valiviita, J 2023, 'Euclid preparation: XXIX. Water ice in spacecraft Part I: The physics of ice formation and contamination', Astronomy and Astrophysics, vol. 675, A142. https://doi.org/10.1051/0004-6361/202346635

TY - JOUR

T1 - Euclid preparation

T2 - XXIX. Water ice in spacecraft Part I: The physics of ice formation and contamination

AU - Schirmer, M.

AU - Thürmer, K.

AU - Bras, B.

AU - Cropper, M.

AU - Martin-Fleitas, J.

AU - Goueffon, Y.

AU - Kohley, R.

AU - Mora, A.

AU - Portaluppi, M.

AU - Racca, G. D.

AU - Short, A. D.

AU - Szmolka, S.

AU - Venancio, L. M.Gaspar

AU - Altmann, M.

AU - Balog, Z.

AU - Bastian, U.

AU - Biermann, M.

AU - Busonero, D.

AU - Fabricius, C.

AU - Grupp, F.

AU - Jordi, C.

AU - Löffler, W.

AU - Sellés, A. Sagrista

AU - Aghanim, N.

AU - Amara, A.

AU - Amendola, L.

AU - Baldi, M.

AU - Bodendorf, C.

AU - Bonino, D.

AU - Branchini, E.

AU - Brescia, M.

AU - Brinchmann, J.

AU - Camera, S.

AU - Candini, G. P.

AU - Capobianco, V.

AU - Carbone, C.

AU - Carretero, J.

AU - Castellano, M.

AU - Cavuoti, S.

AU - Cimatti, A.

AU - Cledassou, R.

AU - Congedo, G.

AU - Conselice, C. J.

AU - Conversi, L.

AU - Copin, Y.

AU - Corcione, L.

AU - Courbin, F.

AU - Da Silva, A.

AU - Degaudenzi, H.

AU - Di Giorgio, A. M.

AU - Dinis, J.

AU - Dubath, F.

AU - Dupac, X.

AU - Dusini, S.

AU - Farrens, S.

AU - Ferriol, S.

AU - Frailis, M.

AU - Franceschi, E.

AU - Fumana, M.

AU - Galeotta, S.

AU - Garilli, B.

AU - Gillard, W.

AU - Gillis, B.

AU - Giocoli, C.

AU - Haugan, S. V.H.

AU - Hoekstra, H.

AU - Holmes, W.

AU - Hormuth, F.

AU - Hornstrup, A.

AU - Jahnke, K.

AU - Kermiche, S.

AU - Kiessling, A.

AU - Kilbinger, M.

AU - Kitching, T.

AU - Kunz, M.

AU - Kurki-Suonio, H.

AU - Ligori, S.

AU - Lilje, P. B.

AU - Lloro, I.

AU - Maiorano, E.

AU - Mansutti, O.

AU - Marggraf, O.

AU - Markovic, K.

AU - Marulli, F.

AU - Massey, R.

AU - Medinaceli, E.

AU - Mei, S.

AU - Mellier, Y.

AU - Meneghetti, M.

AU - Merlin, E.

AU - Meylan, G.

AU - Moresco, M.

AU - Moscardini, L.

AU - Munari, E.

AU - Nakajima, R.

AU - Niemi, S. M.

AU - Nightingale, J. W.

AU - Nutma, T.

AU - Padilla, C.

AU - Paltani, S.

AU - Pasian, F.

AU - Pettorino, V.

AU - Pires, S.

AU - Polenta, G.

AU - Poncet, M.

AU - Popa, L. A.

AU - Raison, F.

AU - Renzi, A.

AU - Rhodes, J.

AU - Riccio, G.

AU - Romelli, E.

AU - Roncarelli, M.

AU - Rossetti, E.

AU - Saglia, R.

AU - Sapone, D.

AU - Sartoris, B.

AU - Schneider, P.

AU - Secroun, A.

AU - Seidel, G.

AU - Serrano, S.

AU - Sirignano, C.

AU - Sirri, G.

AU - Skottfelt, J.

AU - Stanco, L.

AU - Tallada-Crespí, P.

AU - Taylor, A. N.

AU - Tereno, I.

AU - Toledo-Moreo, R.

AU - Tutusaus, I.

AU - Valentijn, E. A.

AU - Valenziano, L.

AU - Vassallo, T.

AU - Wang, Y.

AU - Weller, J.

AU - Zacchei, A.

AU - Zoubian, J.

AU - Andreon, S.

AU - Bardelli, S.

AU - Battaglia, P.

AU - Bozzo, E.

AU - Colodro-Conde, C.

AU - Farina, M.

AU - Graciá-Carpio, J.

AU - Keihänen, E.

AU - Lindholm, V.

AU - Maino, D.

AU - Mauri, N.

AU - Morisset, N.

AU - Scottez, V.

AU - Tenti, M.

AU - Zucca, E.

AU - Akrami, Y.

AU - Baccigalupi, C.

AU - Ballardini, M.

AU - Biviano, A.

AU - Blanchard, A.

AU - Borlaff, A. S.

AU - Burigana, C.

AU - Cabanac, R.

AU - Cappi, A.

AU - Carvalho, C. S.

AU - Casas, S.

AU - Castignani, G.

AU - Castro, T.

AU - Chambers, K. C.

AU - Cooray, A. R.

AU - Coupon, J.

AU - Courtois, H. M.

AU - Cuby, J. G.

AU - Davini, S.

AU - De Lucia, G.

AU - Desprez, G.

AU - Di Domizio, S.

AU - Dole, H.

AU - Escartin, J. A.

AU - Escoffier, S.

AU - Ferrero, I.

AU - Gabarra, L.

AU - Ganga, K.

AU - Garcia-Bellido, J.

AU - George, K.

AU - Giacomini, F.

AU - Gozaliasl, G.

AU - Hildebrandt, H.

AU - Kajava, J. J.E.

AU - Kansal, V.

AU - Kirkpatrick, C. C.

AU - Legrand, L.

AU - Liebing, P.

AU - Loureiro, A.

AU - Maggio, G.

AU - Magliocchetti, M.

AU - Mainetti, G.

AU - Maoli, R.

AU - Marcin, S.

AU - Martinelli, M.

AU - Martinet, N.

AU - Martins, C. J.A.P.

AU - Matthew, S.

AU - Maturi, M.

AU - Maurin, L.

AU - Metcalf, R. B.

AU - Monaco, P.

AU - Morgante, G.

AU - Nadathur, S.

AU - Nucita, A. A.

AU - Patrizii, L.

AU - Pollack, J. E.

AU - Popa, V.

AU - Potter, D.

AU - Pöntinen, M.

AU - Sánchez, A. G.

AU - Sakr, Z.

AU - Schneider, A.

AU - Sereno, M.

AU - Shulevski, A.

AU - Simon, P.

AU - Steinwagner, J.

AU - Teyssier, R.

AU - Valiviita, J.

PY - 2023

Y1 - 2023

N2 - Material outgassing in a vacuum leads to molecular contamination, a well-known problem in spaceflight. Water is the most common contaminant in cryogenic spacecraft, altering numerous properties of optical systems. Too much ice means that Euclida's calibration requirements cannot be met anymore. Euclid must then be thermally decontaminated, which is a month-long risky operation. We need to understand how ice affects our data to build adequate calibration and survey plans. A comprehensive analysis in the context of an astrophysical space survey has not been done before. In this paper we look at other spacecraft with well-documented outgassing records. We then review the formation of thin ice films, and find that for Euclid a mix of amorphous and crystalline ices is expected. Their surface topography-and thus optical properties-depend on the competing energetic needs of the substrate-water and the water-water interfaces, and they are hard to predict with current theories. We illustrate that with scanning-tunnelling and atomic-force microscope images of thin ice films. Sophisticated tools exist to compute contamination rates, and we must understand their underlying physical principles and uncertainties. We find considerable knowledge errors on the diffusion and sublimation coefficients, limiting the accuracy of outgassing estimates. We developed a water transport model to compute contamination rates in Euclid, and find agreement with industry estimates within the uncertainties. Tests of the Euclid flight hardware in space simulators did not pick up significant contamination signals, but they were also not geared towards this purpose; our in-flight calibration observations will be much more sensitive. To derive a calibration and decontamination strategy, we need to understand the link between the amount of ice in the optics and its effect on the data. There is little research about this, possibly because other spacecraft can decontaminate more easily, quenching the need for a deeper understanding. In our second paper, we quantify the impact of iced optics on Euclida's data.

AB - Material outgassing in a vacuum leads to molecular contamination, a well-known problem in spaceflight. Water is the most common contaminant in cryogenic spacecraft, altering numerous properties of optical systems. Too much ice means that Euclida's calibration requirements cannot be met anymore. Euclid must then be thermally decontaminated, which is a month-long risky operation. We need to understand how ice affects our data to build adequate calibration and survey plans. A comprehensive analysis in the context of an astrophysical space survey has not been done before. In this paper we look at other spacecraft with well-documented outgassing records. We then review the formation of thin ice films, and find that for Euclid a mix of amorphous and crystalline ices is expected. Their surface topography-and thus optical properties-depend on the competing energetic needs of the substrate-water and the water-water interfaces, and they are hard to predict with current theories. We illustrate that with scanning-tunnelling and atomic-force microscope images of thin ice films. Sophisticated tools exist to compute contamination rates, and we must understand their underlying physical principles and uncertainties. We find considerable knowledge errors on the diffusion and sublimation coefficients, limiting the accuracy of outgassing estimates. We developed a water transport model to compute contamination rates in Euclid, and find agreement with industry estimates within the uncertainties. Tests of the Euclid flight hardware in space simulators did not pick up significant contamination signals, but they were also not geared towards this purpose; our in-flight calibration observations will be much more sensitive. To derive a calibration and decontamination strategy, we need to understand the link between the amount of ice in the optics and its effect on the data. There is little research about this, possibly because other spacecraft can decontaminate more easily, quenching the need for a deeper understanding. In our second paper, we quantify the impact of iced optics on Euclida's data.

KW - Molecular processes

KW - Solid state: volatile

KW - Space vehicles

KW - Space vehicles: instruments

KW - Telescopes

U2 - 10.1051/0004-6361/202346635

DO - 10.1051/0004-6361/202346635

M3 - Journal article

AN - SCOPUS:85166908375

SN - 0004-6361

VL - 675

JO - Astronomy and Astrophysics

JF - Astronomy and Astrophysics

M1 - A142

ER -

Euclid preparation: XXIX. Water ice in spacecraft Part I: The physics of ice formation and contamination

Abstract

Keywords

Access to Document

OpenUrl availability

Fingerprint

Cite this