对氧化锌中浅供体结合激子转变光线宽的贡献

Vasileios Niaouris, Samuel H. D'Ambrosia, C. Zimmermann, Xingyi Wang, Ethan Hansen, Michael Titze, E. Bielejec, Kai Fu
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摘要

我们研究了单晶氧化锌(ZnO)中 Al、Ga 和 In 供体组合的供体结合激子光学线宽特性。氧化锌中的中性浅供体(D$^0$)是自旋量子比特,可通过供体结合激子(D$^0$X)进行光学访问。这种自旋光子界面可应用于量子网络、存储器和传导。影响自旋光子界面的基本光学参数包括辐射寿命、光学不均匀和均匀线宽以及光学深度。集合光致发光线宽范围为 4-11 GHz,比预期的寿命限制线宽大不到两个数量级。在对厚度为 300 美元/平方米的样品进行吸收测量时,集合线宽仍然很窄,而该样品的光学深度估计可达几百米。声子导致的集合线均匀加宽与 D$^0$X 态之间的热种群弛豫是一致的。我们发现,天然氧化锌中无序的同位素环境导致的不均匀展宽非常明显,范围在 1.9 GHz - 2.2 GHz 之间。双激光光谱反空穴燃烧测量可用于测量集合中的同质线宽,但其显示的光谱反空穴线宽与单激光集合线宽相似。尽管存在这种拓宽,但高均匀性、大光学深度和同位素纯化的潜力表明,氧化锌供体结合激子的光学特性有望用于多种量子技术,并激发了提高氧化锌同位素和化学纯度以用于量子技术的需求。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Contributions to the optical linewidth of shallow donor-bound excitonic transition in ZnO
We study the donor-bound exciton optical linewidth properties of Al, Ga and In donor ensembles in single-crystal zinc oxide (ZnO). Neutral shallow donors (D$^0$) in ZnO are spin qubits with optical access via the donor-bound exciton (D$^0$X). This spin-photon interface enables applications in quantum networking, memories and transduction. Essential optical parameters which impact the spin-photon interface include radiative lifetime, optical inhomogeneous and homogeneous linewidth and optical depth. The ensemble photoluminescence linewidth ranges from 4-11 GHz, less than two orders of magnitude larger than the expected lifetime-limited linewidth. The ensemble linewidth remains narrow in absorption measurements through the 300 $\mu$m-thick sample, which has an estimated optical depth up to several hundred. Homogeneous broadening of the ensemble line due to phonons is consistent with thermal population relaxation between D$^0$X states. This thermal relaxation mechanism has negligible contribution to the total linewidth at 2 K. We find that inhomogeneous broadening due to the disordered isotopic environment in natural ZnO is significant, ranging from 1.9 GHz - 2.2 GHz. Two-laser spectral anti-hole burning measurements, which can be used to measure the homogeneous linewidth in an ensemble, however, reveal spectral anti-hole linewidths similar to the single laser ensemble linewidth. Despite this broadening, the high homogeneity, large optical depth and potential for isotope purification indicate that the optical properties of the ZnO donor-bound exciton are promising for a wide range of quantum technologies and motivate a need to improve the isotope and chemical purity of ZnO for quantum technologies.
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