Hopping of the center-of-mass of single G centers in silicon-on-insulator

TL;DR

This study investigates the atomic reconfiguration of G centers in silicon-on-insulator, revealing how their center-of-mass hopping affects photoluminescence and polarization properties, with implications for quantum photonics.

Contribution

It demonstrates that SOI structures restrict G center reconfiguration, enabling polarized emission and highlighting strain's role in defect dynamics, advancing understanding of defect behavior in silicon photonics.

Findings

G centers in SOI show multipolar emission and fine spectral structures.

Reconfiguration dynamics differ significantly between SOI and bulk silicon.

Strain fluctuations in SOI influence G center geometry and photoluminescence.

Abstract

Among the wealth of single fluorescent defects recently detected in silicon, the G center catches interest for its telecom single-photon emission that could be coupled to a metastable electron spin triplet. The G center is a unique defect where the standard Born-Oppenheimer approximation breaks down as one of its atoms can move between 6 lattice sites under optical excitation. The impact of this atomic reconfiguration on the photoluminescence properties of G centers is still largely unknown, especially in silicon-on-insulator (SOI) samples. Here, we investigate the displacement of the center-of-mass of the G center in silicon. We show that single G defects in SOI exhibit a multipolar emission and zero-phonon line fine structures with splittings up to $\sim1$ meV, both indicating a motion of the defect central atom over time. Combining polarization and spectral analysis at the single-photon level, we evidence that the reconfiguration dynamics are drastically different from the one of the unperturbed G center in bulk silicon. The SOI structure freezes the delocalization of the G defect center-of-mass and as a result, enables to isolate linearly polarized optical lines. Under above-bandgap optical excitation, the central atom of G centers in SOI behaves as if it were in a 6-slot roulette wheel, randomly alternating between localized crystal sites at each optical cycle. Comparative measurements in a bulk silicon sample and ab initio calculations highlight that strain is likely the dominant perturbation impacting the G center geometry. These results shed light on the importance of the atomic reconfiguration dynamics to understand and control the photoluminescence properties of the G center in silicon. More generally, these findings emphasize the impact of strain fluctuations inherent to SOI wafers for future quantum integrated photonics applications based on color centers in silicon.