Euclid: Improving redshift distribution reconstruction using a deep-to-wide transfer function

May 2026 • 2026A&A...709A..55K

Authors • Kang, Y. • Paltani, S. • Hartley, W. G. • Bolzonella, M. • Wright, A. H. • Dubath, F. • Castander, F. J. • Masters, D. C. • d'Assignies, W. • Hildebrandt, H. • Ilbert, O. • Manera, M. • Roster, W. • Stanford, S. A. • Aghanim, N. • Altieri, B. • Andreon, S. • Auricchio, N. • Aussel, H. • Baccigalupi, C. • Baldi, M. • Bardelli, S. • Battaglia, P. • Biviano, A. • Branchini, E. • Brescia, M. • Brinchmann, J. • Camera, S. • Cañas-Herrera, G. • Capobianco, V. • Carbone, C. • Cardone, V. F. • Carretero, J. • Casas, S. • Castellano, M. • Castignani, G. • Cavuoti, S. • Chambers, K. C. • Cimatti, A. • Colodro-Conde, C. • Congedo, G. • Conversi, L. • Copin, Y. • Costille, A. • Courbin, F. • Courtois, H. M. • Cropper, M. • Degaudenzi, H. • De Lucia, G. • Dole, H. • Duncan, C. A. J. • Dupac, X. • Dusini, S. • Ealet, A. • Escoffier, S. • Farina, M. • Farinelli, R. • Farrens, S. • Faustini, F. • Ferriol, S. • Finelli, F. • Fourmanoit, N. • Frailis, M. • Franceschi, E. • Fumana, M. • Galeotta, S. • George, K. • Gillis, B. • Giocoli, C. • Gracia-Carpio, J. • Grazian, A. • Grupp, F. • Haugan, S. V. H. • Hoekstra, H. • Holmes, W. • Hormuth, F. • Hornstrup, A. • Hudelot, P. • Jahnke, K. • Jhabvala, M. • Joachimi, B. • Keihänen, E. • Kermiche, S. • Kiessling, A. • Kubik, B. • Kümmel, M. • Kunz, M. • Kurki-Suonio, H. • Laureijs, R. • Le Brun, A. M. C. • Ligori, S. • Lilje, P. B. • Lindholm, V. • Lloro, I. • Mainetti, G. • Maino, D. • Maiorano, E. • Mansutti, O. • Marcin, S. • Marggraf, O. • Martinelli, M. • Martinet, N. • Marulli, F. • Massey, R. J. • Medinaceli, E. • Mei, S. • Mellier, Y. • Meneghetti, M. • Merlin, E. • Meylan, G. • Mora, A. • Moresco, M. • Moscardini, L. • Nakajima, R. • Neissner, C. • Niemi, S.-M. • Padilla, C. • Pasian, F. • Pedersen, K. • Pettorino, V. • Pires, S. • Polenta, G. • Poncet, M. • Popa, L. A. • Pozzetti, L. • Raison, F. • Renzi, A. • Rhodes, J. • Riccio, G. • Romelli, E. • Roncarelli, M. • Saglia, R. • Sakr, Z. • Sánchez, A. G. • Sapone, D. • Sartoris, B. • Schneider, P. • Schrabback, T. • Secroun, A. • Seidel, G. • Serrano, S. • Simon, P. • Sirignano, C. • Sirri, G. • Stanco, L. • Steinwagner, J. • Tallada-Crespí, P. • Taylor, A. N. • Tereno, I. • Tessore, N. • Toft, S. • Toledo-Moreo, R. • Torradeflot, F. • Tutusaus, I. • Valiviita, J. • Vassallo, T. • Veropalumbo, A. • Wang, Y. • Weller, J. • Zamorani, G. • Zerbi, F. M. • Zinchenko, I. A. • Zucca, E. • García-Bellido, J. • Martín-Fleitas, J. • Scottez, V. • Viel, M. • Teyssier, R.

Abstract • The Euclid mission of the European Space Agency seeks to understand the Universe's expansion history and the nature of dark energy, through measurements of cosmic shear. This requires a very accurate estimate of the true redshift distribution of the galaxies, with the systematic error in the mean redshift satisfying σ_⟨z⟩ < 0.002(1 + z) per tomographic bin. Achieving this accuracy relies on reference samples with spectroscopic redshifts, together with a procedure to match them to survey sources for which only photometric redshifts are available. One important source of systematic uncertainty is the mismatch in photometric properties between galaxies in the Euclid survey and the reference objects. We develop a method to degrade the photometry of objects with deep photometry to match the properties of any shallower survey in the multi-band photometric space, preserving all the correlations between the fluxes and their uncertainties. We compare our transfer method with more demanding image-based methods, such as Balrog from the Dark Energy Survey Collaboration. According to our metrics, our method outperforms Balrog. We implement our method in the redshift distribution reconstruction, based on the self-organising map approach, and test it using a realistic sample from the Euclid Flagship Mock Galaxy Simulation. We find that the key ingredient is to ensure that the reference objects are distributed in the colour space the same way as the wide-survey objects, which can be efficiently achieved with our transfer method. In our best implementation, the mean redshift biases are consistently reduced across the tomographic bins, bringing a significant fraction of them within the Euclid accuracy requirements in all tomographic bins. Equally importantly, the tests allow us to pinpoint which step in the calibration pipeline has the strongest impact on achieving the required accuracy. Our approach also reproduces the overall redshift distributions, which are crucial for applications such as angular clustering. The agreement between the reconstructed and true distributions demonstrates both the feasibility and robustness of the approach. This implementation is sufficient for Euclid Data Release 1 and provides a solid foundation for subsequent data releases. ★ This paper is published on behalf of the Euclid Consortium.

Links

• POSTSCRIPT https://www.aanda.org/10.1051/0004-6361/202658861/postscript
• PREPRINT http://arxiv.org/abs/2601.02005