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Published February 8, 2017 | Supplemental Material
Journal Article Open

Optical Line Width Broadening Mechanisms at the 10 kHz Level in Eu^(3+):Y_2O_3 Nanoparticles

Abstract

We identify the physical mechanisms responsible for the optical homogeneous broadening in Eu^(3+):Y_2O_3 nanoparticles to determine whether rare-earth crystals can be miniaturized to volumes less than λ^3 while preserving their appeal for quantum technology hardware. By studying how the homogeneous line width depends on temperature, applied magnetic field, and measurement time scale, the dominant broadening interactions for various temperature ranges above 3 K were characterized. Below 3 K the homogeneous line width is dominated by an interaction not observed in bulk crystal studies. These measurements demonstrate that broadening due to size-dependent phonon interactions is not a significant contributor to the homogeneous line width, which contrasts previous studies in rare-earth ion nanocrystals. Importantly, the results provide strong evidence that for the 400 nm diameter nanoparticles under study the minimum line width achieved (45 ± 1 kHz at 1.3 K) is not fundamentally limited. In addition, we highlight that the expected broadening caused by electric field fluctuations arising from surface charges is comparable to the observed broadening. Under the assumption that such Stark broadening is a significant contribution to the homogeneous line width, several strategies for reducing this line width to below 10 kHz are discussed. Furthermore, it is demonstrated that the Eu^(3+) hyperfine state lifetime is sufficiently long to preserve spectral features for time scales up to 1 s. These results allow integrated rare-earth ion quantum optics to be pursued at a submicron scale and, hence, open up directions for greater scaling of rare-earth quantum technology.

Additional Information

© 2017 American Chemical Society. Received: September 21, 2016; Revised: January 5, 2017; Published: January 18, 2017. This project has received funding from the European Union's Seventh Framework Programme FP7/2007-2013/under REA grant agreement no. 287252 (CIPRIS, People Programme-Marie Curie Actions), European Union's Horizon 2020 research and innovation programme under grant agreement no. 712721 (NanOQTech), and ANR under grant agreements no. 145-CE26-0037-01 (DISCRYS) and 12-BS08-0015-01 (RAMACO). The authors declare no competing financial interest.

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