Machine learning spectral clustering techniques: Application to Jovian clouds from Juno/JIRAM and JWST/NIRSpec

F. Biagiotti; L. N. Fletcher; D. Grassi; M. T. Roman; G. Piccioni; Alessandro Mura; I. De Pater; T. Fouchet; M. H. Wong; R. Hueso; O. King; H. Melin; J. Harkett; S. Toogood; P. G.J. Irwin; F. Tosi; A. Adriani; G. Sindoni; C. Plainaki; R. Sordini; R. Noschese; A. Cicchetti; G. Orton; P. Rodriguez-Ovalle; G. L. Bjoraker; S. Levin; C. Li; S. Bolton

doi:10.1051/0004-6361/202554552

Machine learning spectral clustering techniques: Application to Jovian clouds from Juno/JIRAM and JWST/NIRSpec

F. Biagiotti^*, L. N. Fletcher, D. Grassi, M. T. Roman, G. Piccioni, Alessandro Mura, I. De Pater, T. Fouchet, M. H. Wong, R. Hueso, O. King, H. Melin, J. Harkett, S. Toogood, P. G.J. Irwin, F. Tosi, A. Adriani, G. Sindoni, C. Plainaki, R. SordiniR. Noschese, A. Cicchetti, G. Orton, P. Rodriguez-Ovalle, G. L. Bjoraker, S. Levin, C. Li, S. Bolton

^*Corresponding author for this work

School of Engineering Physics and Mathematics

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Abstract

We present a new method, based on a joint application of a principal component analysis (PCA) and Gaussian mixture models (GMM), to automatically find similar groups of spectra in a collection. We applied the method (condensed in the public code chopper.py) to archival Jupiter spectral data in the 2–5 µm range collected by NASA Juno/JIRAM in its first perijove passage (August 2016) and to mosaics of the great red spot (GRS) acquired by JWST/NIRSpec (July 2022). Using JIRAM data analyzed in previous work, we show that using a PCA+GMM clustering can increase the efficiency of the retrieval stage without any loss of accuracy in terms of the retrieved parameters. We show that a PCA+GMM approach is able to automatically identify spectra of known regions of interest (e.g., belts, zones, GRS) belonging to different clusters. The application of the method to the NIRSpec data leads to detection of substructures inside the GRS, which appears to be composed of an outer halo characterized by low reflectivity and an inner brighter main oval. By applying these techniques to JIRAM data, we were able to identify the same substructure. We remark that these new structures have not been seen before at visible wavelengths. In both cases, the spectra belonging to the inner oval have solar and thermal signals comparable to those belonging to the halo, but they present broadened 2.73 µm solar-reflected peaks. Performing forward simulations with the NEMESIS radiative transfer suite, we propose that the broadening may be caused by differences in the vertical extension of the main cloud layer. This finding is consistent with recent 3D fluid dynamics simulations.

Original language	English
Article number	A247
Number of pages	21
Journal	Astronomy and Astrophysics
Volume	701
Early online date	19 Sept 2025
DOIs	https://doi.org/10.1051/0004-6361/202554552
Publication status	Published - Sept 2025

Keywords

methods: data analysis
planets and satellites: atmospheres
planets and satellites: individual: Jupiter
techniques: miscellaneous

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Biagiotti, F., Fletcher, L. N., Grassi, D., Roman, M. T., Piccioni, G., Mura, A., De Pater, I., Fouchet, T., Wong, M. H., Hueso, R., King, O., Melin, H., Harkett, J., Toogood, S., Irwin, P. G. J., Tosi, F., Adriani, A., Sindoni, G., Plainaki, C., ... Bolton, S. (2025). Machine learning spectral clustering techniques: Application to Jovian clouds from Juno/JIRAM and JWST/NIRSpec. Astronomy and Astrophysics, 701, Article A247. https://doi.org/10.1051/0004-6361/202554552

@article{3d10f6ad366840cf8647682513dc04d3,

title = "Machine learning spectral clustering techniques: Application to Jovian clouds from Juno/JIRAM and JWST/NIRSpec",

abstract = "We present a new method, based on a joint application of a principal component analysis (PCA) and Gaussian mixture models (GMM), to automatically find similar groups of spectra in a collection. We applied the method (condensed in the public code chopper.py) to archival Jupiter spectral data in the 2–5 µm range collected by NASA Juno/JIRAM in its first perijove passage (August 2016) and to mosaics of the great red spot (GRS) acquired by JWST/NIRSpec (July 2022). Using JIRAM data analyzed in previous work, we show that using a PCA+GMM clustering can increase the efficiency of the retrieval stage without any loss of accuracy in terms of the retrieved parameters. We show that a PCA+GMM approach is able to automatically identify spectra of known regions of interest (e.g., belts, zones, GRS) belonging to different clusters. The application of the method to the NIRSpec data leads to detection of substructures inside the GRS, which appears to be composed of an outer halo characterized by low reflectivity and an inner brighter main oval. By applying these techniques to JIRAM data, we were able to identify the same substructure. We remark that these new structures have not been seen before at visible wavelengths. In both cases, the spectra belonging to the inner oval have solar and thermal signals comparable to those belonging to the halo, but they present broadened 2.73 µm solar-reflected peaks. Performing forward simulations with the NEMESIS radiative transfer suite, we propose that the broadening may be caused by differences in the vertical extension of the main cloud layer. This finding is consistent with recent 3D fluid dynamics simulations.",

keywords = "methods: data analysis, planets and satellites: atmospheres, planets and satellites: individual: Jupiter, techniques: miscellaneous",

author = "F. Biagiotti and Fletcher, \{L. N.\} and D. Grassi and Roman, \{M. T.\} and G. Piccioni and Alessandro Mura and \{De Pater\}, I. and T. Fouchet and Wong, \{M. H.\} and R. Hueso and O. King and H. Melin and J. Harkett and S. Toogood and Irwin, \{P. G.J.\} and F. Tosi and A. Adriani and G. Sindoni and C. Plainaki and R. Sordini and R. Noschese and A. Cicchetti and G. Orton and P. Rodriguez-Ovalle and Bjoraker, \{G. L.\} and S. Levin and C. Li and S. Bolton",

year = "2025",

month = sep,

doi = "10.1051/0004-6361/202554552",

language = "English",

volume = "701",

journal = "Astronomy and Astrophysics",

issn = "0004-6361",

publisher = "EDP Sciences",

}

Biagiotti, F, Fletcher, LN, Grassi, D, Roman, MT, Piccioni, G, Mura, A, De Pater, I, Fouchet, T, Wong, MH, Hueso, R, King, O, Melin, H, Harkett, J, Toogood, S, Irwin, PGJ, Tosi, F, Adriani, A, Sindoni, G, Plainaki, C, Sordini, R, Noschese, R, Cicchetti, A, Orton, G, Rodriguez-Ovalle, P, Bjoraker, GL, Levin, S, Li, C & Bolton, S 2025, 'Machine learning spectral clustering techniques: Application to Jovian clouds from Juno/JIRAM and JWST/NIRSpec', Astronomy and Astrophysics, vol. 701, A247. https://doi.org/10.1051/0004-6361/202554552

TY - JOUR

T1 - Machine learning spectral clustering techniques: Application to Jovian clouds from Juno/JIRAM and JWST/NIRSpec

AU - Biagiotti, F.

AU - Fletcher, L. N.

AU - Grassi, D.

AU - Roman, M. T.

AU - Piccioni, G.

AU - Mura, Alessandro

AU - De Pater, I.

AU - Fouchet, T.

AU - Wong, M. H.

AU - Hueso, R.

AU - King, O.

AU - Melin, H.

AU - Harkett, J.

AU - Toogood, S.

AU - Irwin, P. G.J.

AU - Tosi, F.

AU - Adriani, A.

AU - Sindoni, G.

AU - Plainaki, C.

AU - Sordini, R.

AU - Noschese, R.

AU - Cicchetti, A.

AU - Orton, G.

AU - Rodriguez-Ovalle, P.

AU - Bjoraker, G. L.

AU - Levin, S.

AU - Li, C.

AU - Bolton, S.

PY - 2025/9

Y1 - 2025/9

N2 - We present a new method, based on a joint application of a principal component analysis (PCA) and Gaussian mixture models (GMM), to automatically find similar groups of spectra in a collection. We applied the method (condensed in the public code chopper.py) to archival Jupiter spectral data in the 2–5 µm range collected by NASA Juno/JIRAM in its first perijove passage (August 2016) and to mosaics of the great red spot (GRS) acquired by JWST/NIRSpec (July 2022). Using JIRAM data analyzed in previous work, we show that using a PCA+GMM clustering can increase the efficiency of the retrieval stage without any loss of accuracy in terms of the retrieved parameters. We show that a PCA+GMM approach is able to automatically identify spectra of known regions of interest (e.g., belts, zones, GRS) belonging to different clusters. The application of the method to the NIRSpec data leads to detection of substructures inside the GRS, which appears to be composed of an outer halo characterized by low reflectivity and an inner brighter main oval. By applying these techniques to JIRAM data, we were able to identify the same substructure. We remark that these new structures have not been seen before at visible wavelengths. In both cases, the spectra belonging to the inner oval have solar and thermal signals comparable to those belonging to the halo, but they present broadened 2.73 µm solar-reflected peaks. Performing forward simulations with the NEMESIS radiative transfer suite, we propose that the broadening may be caused by differences in the vertical extension of the main cloud layer. This finding is consistent with recent 3D fluid dynamics simulations.

AB - We present a new method, based on a joint application of a principal component analysis (PCA) and Gaussian mixture models (GMM), to automatically find similar groups of spectra in a collection. We applied the method (condensed in the public code chopper.py) to archival Jupiter spectral data in the 2–5 µm range collected by NASA Juno/JIRAM in its first perijove passage (August 2016) and to mosaics of the great red spot (GRS) acquired by JWST/NIRSpec (July 2022). Using JIRAM data analyzed in previous work, we show that using a PCA+GMM clustering can increase the efficiency of the retrieval stage without any loss of accuracy in terms of the retrieved parameters. We show that a PCA+GMM approach is able to automatically identify spectra of known regions of interest (e.g., belts, zones, GRS) belonging to different clusters. The application of the method to the NIRSpec data leads to detection of substructures inside the GRS, which appears to be composed of an outer halo characterized by low reflectivity and an inner brighter main oval. By applying these techniques to JIRAM data, we were able to identify the same substructure. We remark that these new structures have not been seen before at visible wavelengths. In both cases, the spectra belonging to the inner oval have solar and thermal signals comparable to those belonging to the halo, but they present broadened 2.73 µm solar-reflected peaks. Performing forward simulations with the NEMESIS radiative transfer suite, we propose that the broadening may be caused by differences in the vertical extension of the main cloud layer. This finding is consistent with recent 3D fluid dynamics simulations.

KW - methods: data analysis

KW - planets and satellites: atmospheres

KW - planets and satellites: individual: Jupiter

KW - techniques: miscellaneous

UR - https://www.scopus.com/pages/publications/105017009674

U2 - 10.1051/0004-6361/202554552

DO - 10.1051/0004-6361/202554552

M3 - Article

AN - SCOPUS:105017009674

SN - 0004-6361

VL - 701

JO - Astronomy and Astrophysics

JF - Astronomy and Astrophysics

M1 - A247

ER -

Machine learning spectral clustering techniques: Application to Jovian clouds from Juno/JIRAM and JWST/NIRSpec

Abstract

Keywords

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