Random coincidences of events could be one of the main sources of background in the search for neutrino-less double-beta decay of $$^{100}$$
100
Mo with macro-bolometers, due to their modest time resolution. Scintillating bolometers as those based on Li$$_2$$
2
MoO$$_4$$
4
crystals and employed in the CROSS and CUPID experiments can eventually exploit the coincident fast signal detected in a light detector to reduce this background. However, the scintillation provides a modest signal-to-noise ratio, making difficult a pile-up pulse-shape recognition and rejection at timescales shorter than a few ms. Neganov–Trofimov–Luke assisted light detectors (NTL-LDs) offer the possibility to effectively increase the signal-to-noise ratio, preserving a fast time-response, and enhance the capability of pile-up rejection via pulse shape analysis. In this article we present: (a) an experimental work performed with a Li$$_2$$
2
MoO$$_4$$
4
scintillating bolometer, studied in the framework of the CROSS experiment, and utilizing a NTL-LD; (b) a simulation method to reproduce, synthetically, randomly coincident two-neutrino double-beta decay events; (c) a new analysis method based on a pulse-shape discrimination algorithm capable of providing high pile-up rejection efficiencies. We finally show how the NTL-LDs offer a balanced solution between performance and complexity to reach background index $$\sim $$
∼
$$10^{-4}$$
10
-
4
counts/keV/kg/year with 280 g Li$$_2$$
2
MoO$$_4$$
4
($$^{100}$$
100
Mo enriched) bolometers at 3034 keV, the Q$$_{\beta \beta }$$
β
β
of the double-beta decay, and target the goal of a next generation experiment like CUPID.