Identifying type II quasars at intermediate redshift with few-shot learning photometric classification

TL;DR

This paper introduces a few-shot learning method using the AMELIA pipeline to identify rare type II quasars at intermediate redshift with limited data, validated through spectroscopic and multi-wavelength analysis.

Contribution

It develops a transfer-learning based few-shot classification approach for rare astronomical objects, addressing challenges of small training datasets in quasar identification.

Findings

Achieved F1-score above 0.8 in identifying QSO2s at z=1-2.

Discovered a sub-population of [NeV] emitters likely to be obscured AGNs.

Validated candidates with X-ray, radio, and spectral analysis confirming dusty AGN nature.

Abstract

We aim to identify QSO2 candidates in the redshift desert using optical and infrared photometry. At this intermediate redshift range, most of the prominent optical emission lines in QSO2 sources (e.g. CIV1549; [OIII]4959,5008) fall either outside the wavelength range of the SDSS optical spectra or in particularly noisy wavelength ranges, making QSO2 identification challenging. Therefore, we adopted a semi-supervised machine learning approach to select candidates in the SDSS galaxy sample. Recent applications of machine learning in astronomy focus on problems involving large data sets, with small data sets often being overlooked. We developed a few-shot learning approach for the identification and classification of rare-object classes using limited training data (200 sources). The new AMELIA pipeline uses a transfer-learning based approach with decision trees, distance-based, and deep learning methods to build a classifier capable of identifying rare objects on the basis of an observational training data set. We validated the performance of AMELIA by addressing the problem of identifying QSO2s at 1 $\leq$ z $\leq$ 2 using SDSS and WISE photometry, obtaining an F1-score above 0.8 in a supervised approach. We then used AMELIA to select new QSO2 candidates in the redshift desert and examined the nature of the candidates using SDSS spectra, when available. In particular, we identified a sub-population of [NeV]3426 emitters at z $\sim$ 1.1, which are highly likely to contain obscured AGNs. We used X-ray and radio cross-matching to validate our classification and investigated the performance of photometric criteria from the literature showing that our candidates have an inherent dusty nature. Finally, we derived physical properties for our QSO2 sample using photoionisation models and verified the AGN classification using an SED fitting.