Xiaorui Wang, Tomáš Vaněk, František Hájek, Vítězslav Jarý, Tomáš Hubáček, Alice Hospodková, Francis Chi-Chung Ling and Shijie Xu
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引用次数: 0
Abstract
With the sub-bandgap optical excitation, thermal dynamics of holes among multiple levels in n-type GaN epilayers with different dopants of Si, Ge and C are investigated via measuring and modeling variable-temperature yellow luminescence (YL) band of the samples. In sharp contrast to the case of above-bandgap optical excitation, the variable-temperature YL band of all the studied GaN samples including unintentionally-doped sample exhibit unusual negative thermal quenching (NTQ) behavior, suggesting a possible physical mechanism, namely thermally induced migration of holes from shallower levels to the luminescent deep level. By considering the possible presence of multiple hole levels in the doped GaN samples, a phenomenological model is developed for the thermal transfer of holes among the multi-levels and the interpretation of the observed NTQ phenomenon of the YL band. Different activation energies of 347.9, 520.8 and 348.5 meV are obtained for the Ge-doped, high C-containing, and Si-doped GaN samples, respectively. The results reveal the existence of multiple hole defect levels in the n-type GaN. Possible microstructural origins causing these different hole levels are further argued. The study may shed some light on the nature of various defect complexes in the technologically important GaN epilayers. Combined microstructural and optical investigations need to be further done for elucidating various optically- and electrically-active defect complexes in GaN.
在亚带隙光激发下,通过测量和模拟样品的变温黄色发光(YL)带,研究了含有硅、锗和碳等不同掺杂剂的 n 型氮化镓外延层中多级空穴的热动力学。与高带隙光激发的情况形成鲜明对比的是,所有研究的 GaN 样品(包括无意掺杂的样品)的变温 YL 带都表现出不寻常的负热淬灭(NTQ)行为,这表明了一种可能的物理机制,即热诱导空穴从较浅的层次迁移到发光的较深层次。考虑到掺杂氮化镓样品中可能存在多个空穴水平,我们建立了一个多水平之间空穴热转移的现象学模型,并解释了所观察到的 YL 波段的 NTQ 现象。掺杂 Ge、高含 C 和掺杂 Si 的 GaN 样品分别获得了 347.9、520.8 和 348.5 meV 的不同活化能。这些结果揭示了 n 型氮化镓中存在多个空穴缺陷水平。研究还进一步论证了造成这些不同空穴水平的可能微结构根源。这项研究可以揭示具有重要技术意义的氮化镓外延层中各种缺陷复合物的性质。要阐明氮化镓中各种光学和电学活性缺陷复合物,还需要进一步开展微结构和光学联合研究。
期刊介绍:
Devoted to semiconductor research, Semiconductor Science and Technology''s multidisciplinary approach reflects the far-reaching nature of this topic.
The scope of the journal covers fundamental and applied experimental and theoretical studies of the properties of non-organic, organic and oxide semiconductors, their interfaces and devices, including:
fundamental properties
materials and nanostructures
devices and applications
fabrication and processing
new analytical techniques
simulation
emerging fields:
materials and devices for quantum technologies
hybrid structures and devices
2D and topological materials
metamaterials
semiconductors for energy
flexible electronics.