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Main Authors: Bruton, Sean, Cheshire IV, James R., Doré, Olivier, Gebhardt, Henry S. Grasshorn, Wen, Robin Y.
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2605.10935
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author Bruton, Sean
Cheshire IV, James R.
Doré, Olivier
Gebhardt, Henry S. Grasshorn
Wen, Robin Y.
author_facet Bruton, Sean
Cheshire IV, James R.
Doré, Olivier
Gebhardt, Henry S. Grasshorn
Wen, Robin Y.
contents The Spherical Fourier-Bessel (SFB) basis, in separating the angular and radial modes of the power spectrum, permits a targeted identification and mitigation of systematics in clustering surveys while retaining more cosmological signal than traditional bases. We demonstrate this principle on the eBOSS DR16 LRG and QSO samples, identifying modes which may be contaminated by systematics. Our initial inference on the LRG sample yields an fNL value consistent with zero, while the QSO value is in slight tension with zero. Using the SFB basis, we vary the selection of angular and radial modes to search for inconsistencies in the inferred value of fNL, an indicator of underlying systematics. In the QSO sample, we find evidence (p < 0.005 compared to the same cuts on EZMocks) of a systematic afflicting large physical scales, which is consistent with residual stellar contamination; we also find evidence (p < 0.05) for an unknown systematic in the QSO and LRG samples at the approximate angular plate and imaging scale of eBOSS.
format Preprint
id arxiv_https___arxiv_org_abs_2605_10935
institution arXiv
publishDate 2026
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spellingShingle Demonstrating the Use of the Spherical Fourier Bessel Basis for Large Scale Clustering Systematics Discovery and Mitigation with eBOSS
Bruton, Sean
Cheshire IV, James R.
Doré, Olivier
Gebhardt, Henry S. Grasshorn
Wen, Robin Y.
Cosmology and Nongalactic Astrophysics
The Spherical Fourier-Bessel (SFB) basis, in separating the angular and radial modes of the power spectrum, permits a targeted identification and mitigation of systematics in clustering surveys while retaining more cosmological signal than traditional bases. We demonstrate this principle on the eBOSS DR16 LRG and QSO samples, identifying modes which may be contaminated by systematics. Our initial inference on the LRG sample yields an fNL value consistent with zero, while the QSO value is in slight tension with zero. Using the SFB basis, we vary the selection of angular and radial modes to search for inconsistencies in the inferred value of fNL, an indicator of underlying systematics. In the QSO sample, we find evidence (p < 0.005 compared to the same cuts on EZMocks) of a systematic afflicting large physical scales, which is consistent with residual stellar contamination; we also find evidence (p < 0.05) for an unknown systematic in the QSO and LRG samples at the approximate angular plate and imaging scale of eBOSS.
title Demonstrating the Use of the Spherical Fourier Bessel Basis for Large Scale Clustering Systematics Discovery and Mitigation with eBOSS
topic Cosmology and Nongalactic Astrophysics
url https://arxiv.org/abs/2605.10935