Density functional theory investigation on formation of nanoscale PbS materials and its fabrication in silica optical fiber via atomic layer deposition

Dong Yanhua; Su Caiyun; Pan Xiangping; Zhao Yangyang; Wen Jianxiang; Pang Fufei; Huang Yi; Shang Yana; Wang Tingyun

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Density functional theory investigation on formation of nanoscale PbS materials and its fabrication in silica optical fiber via atomic layer deposition

机译：密度函数理论研究纳米级PBS材料形成及其在二氧化硅光纤中的制造通过原子层沉积

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摘要

The formation mechanisms for lead sulfide (PbS) semiconductor nanomaterials grown on silica substrate were investigated using density functional theory. There are two main reaction processes for the adsorption of Pb (tmhd)(2) on a silica substrate and the reaction with H2S to form PbS. The activation barriers of the two reaction processes were quite low at 10.1923 and 20.6778 kcal/mol, which is energetically favorable for PbS deposition by atomic layer deposition (ALD). In addition, PbS nanomaterials were introduced both on silica substrate and into the core of the silica fiber via ALD, with Pb(tmhd)(2) and H2S as precursors. The structural properties of the PbS nanomaterials and optical properties of the PbS-doped fiber were characterized. There were obvious absorption peaks at 480, 695, and 1043 nm. The fiber exhibited photoluminescence at 1060-1370 nm with 1064 nm pumping. A gain of 9.4 dB was obtained at 1310 nm, which can be attributed to the PbS nanomaterials in the fiber core. This is crucial for optical fiber communications.

机译：利用密度函数理论研究了在二氧化硅基板上生长的硫化铅（PBS）半导体纳米材料的形成机制。在二氧化硅基材上吸附Pb（TMHD）（2）的两种主要反应方法，以及与H2S形成PBS的反应。两种反应过程的活化屏障在10.1923和20.6778 kcal / mol处非常低，这对通过原子层沉积（ALD）的PBS沉积能量有利。此外，PBS纳米材料在二氧化硅基材上引入二氧化硅基材并通过ALD进入二氧化硅纤维的核心，PB（TMHD）（2）和H 2 S作为前体。表征PBS纳米材料的结构性能和PBS掺杂纤维的光学性质。 480,695和1043nm处存在明显的吸收峰。纤维在1060-1370nm下表现出光致发光，1064nm泵送。在1310nm处获得9.4dB的增益，其可归因于纤维芯中的PBS纳米材料。这对光纤通信至关重要。

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来源
《Optical fiber technology》 |2020年第9期|102257.1-102257.6|共6页
作者
Dong Yanhua; Su Caiyun; Pan Xiangping; Zhao Yangyang; Wen Jianxiang; Pang Fufei; Huang Yi; Shang Yana; Wang Tingyun;
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作者单位

Shanghai Univ Shanghai Inst Adv Commun & Data Sci Key Lab Specialty Fiber Opt & Opt Access Networks Joint Int Res Lab Specialty Fiber Opt & Adv Commu 99 Shangda Rd Shanghai 200444 Peoples R China;

Shanghai Univ Shanghai Inst Adv Commun & Data Sci Key Lab Specialty Fiber Opt & Opt Access Networks Joint Int Res Lab Specialty Fiber Opt & Adv Commu 99 Shangda Rd Shanghai 200444 Peoples R China;

Shanghai Univ Shanghai Inst Adv Commun & Data Sci Key Lab Specialty Fiber Opt & Opt Access Networks Joint Int Res Lab Specialty Fiber Opt & Adv Commu 99 Shangda Rd Shanghai 200444 Peoples R China;

Shanghai Univ Shanghai Inst Adv Commun & Data Sci Key Lab Specialty Fiber Opt & Opt Access Networks Joint Int Res Lab Specialty Fiber Opt & Adv Commu 99 Shangda Rd Shanghai 200444 Peoples R China;

Shanghai Univ Shanghai Inst Adv Commun & Data Sci Key Lab Specialty Fiber Opt & Opt Access Networks Joint Int Res Lab Specialty Fiber Opt & Adv Commu 99 Shangda Rd Shanghai 200444 Peoples R China;

Shanghai Univ Shanghai Inst Adv Commun & Data Sci Key Lab Specialty Fiber Opt & Opt Access Networks Joint Int Res Lab Specialty Fiber Opt & Adv Commu 99 Shangda Rd Shanghai 200444 Peoples R China;

Shanghai Univ Shanghai Inst Adv Commun & Data Sci Key Lab Specialty Fiber Opt & Opt Access Networks Joint Int Res Lab Specialty Fiber Opt & Adv Commu 99 Shangda Rd Shanghai 200444 Peoples R China;

Shanghai Univ Shanghai Inst Adv Commun & Data Sci Key Lab Specialty Fiber Opt & Opt Access Networks Joint Int Res Lab Specialty Fiber Opt & Adv Commu 99 Shangda Rd Shanghai 200444 Peoples R China;

Shanghai Univ Shanghai Inst Adv Commun & Data Sci Key Lab Specialty Fiber Opt & Opt Access Networks Joint Int Res Lab Specialty Fiber Opt & Adv Commu 99 Shangda Rd Shanghai 200444 Peoples R China;

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收录信息美国《科学引文索引》(SCI);美国《工程索引》(EI);
原文格式 PDF
正文语种 eng
中图分类
关键词
Density functional theory (DFT); Nanoscale PbS materials; Atomic layer deposition (ALD); PbS-doped silica optical fiber; Optical properties;

机译：密度函数理论（DFT）;纳米级PBS材料;原子层沉积（ALD）;PBS掺杂的二氧化硅光纤;光学性质;

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Density functional theory investigation on formation of nanoscale PbS materials and its fabrication in silica optical fiber via atomic layer deposition

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