ABSTRACT Yb 3+ ‐doped CsPbCl 3 nanocrystals exhibit an exceptionally efficient quantum‐cutting, converting single UV photons into a pair of near‐infrared photons with a photoluminescence quantum yield approaching 200%, offering broad opportunities for optoelectronic and photonic applications. Recent studies highlighted the importance of Yb 3+ ‐induced defect states in mediating energy transfer from the host to Yb 3+ multiplets. However, the persistent observation of thermally activated Yb 3+ emission even when the defect‐state energy lies well above the threshold for quantum‐cutting remains intriguing and unresolved. Based on temperature‐dependent emission measurements, we establish that the thermal activation of Yb 3+ emission is universal and introduce temperature‐dependent rate equations that quantitatively reproduce all experimental observations. The detailed analyses demonstrate that the observed thermal activation is the combined effect of the thermally activated defect state population and the presence of 15 phonon‐assisted multiphonon processes, presenting a phonon bottleneck at low temperatures, and thereby suppressing the dissipation of excess energy to lattice phonons. Furthermore, photon‐correlation analyses, performed here for the first time to probe the quantum nature of the Yb 3+ emission in CsPbCl 3 nanocrystals, unambiguously establish the decoherence of the emitted photons due to the large time separations between the cooperative excitation of Yb 3+ ions (∼ns) and their long‐lived emission (∼2.7 ms).
Mukherjee et al. (Tue,) studied this question.