用太赫兹级联激光器测定硅芯内激光器有源介质的光损耗

2010 2nd IEEE International Workshop Thz Radiation: Basic Research and Applications Pub Date : 2010-11-04 DOI:10.1109/TERA.2010.5619931

S. Pavlov, R. Eichholz, N. Abrosimov, H. Riemann, M. Wienold, L. Schrottke, M. Giehler, R. Hey, H. Grahn, A. Tredicucci, H. Beere, D. Ritchie, H. Hubers

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引用次数: 2

摘要

在过去的十年中，太赫兹范围内硅激光器在扩大频率工作范围、操纵硅矩阵以及降低光泵浦阈值方面取得了重大进展。虽然在硅激光器中实现的太赫兹增益已经被定义，但在有源介质中的光学损耗还没有实验测量。我们应用连续波太赫兹量子级联激光器，工作在2.5 THz和3.1 THz，直接测量光泵浦强度超过相应介质激光阈值条件下的光损失。这些测量允许估计太赫兹损失以及确定主要对光激发硅中总太赫兹吸收有贡献的物理机制。发现在光激发硅中动态诱导的所谓D¯-中心的吸收导致了太赫兹辐射的主要损失。然而，这些损失可以通过适当的晶体生长和掺杂程序显着降低。

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Using terahertz cascade lasers for determination of optical losses in active medium of silicon intracenter lasers

Terahertz-range intracenter silicon lasers have demonstrated significant progress over past decade in expanding the frequency operation range, in manipulation of a silicon matrix as well as in lowering of optical pump threshold. While terahertz gain realized in silicon lasers has been already defined, optical losses in the active media have not been yet measured experimentally. We applied continuous wave terahertz quantum cascade lasers, operating at 2.5 THz and 3.1 THz for direct measurements of the light losses at conditions of optical pumping with pump intensities exceeding laser thresholds for corresponding media. These measurements allow estimates of THz losses as well as determination of physical mechanisms mainly contributing for total THz absorption in optically excited silicon. It was found that absorption by so called D¯-centers, dynamically induced in optically excited silicon, cause major loss of THz emission. These losses, however, can be significantly reduced by a proper procedure of crystal growth and doping.

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2010 2nd IEEE International Workshop Thz Radiation: Basic Research and Applications

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