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Qing Hu

Electrical and Computer Engineering · Massachusetts Institute of Technology  high

研究方向

  • 太赫兹量子级联激光器
    • THz量子级联激光
      • 直接声子提取增强工作温度
      • 频率梳
    • 超快光学
      • 双啁啾镜
      • 空气介质反射镜
太赫兹量子级联激光THz频率梳啁啾镜

该校申请信息 · Massachusetts Institute of Technology

ECE deadline(legacy)
申请费

近三年论文 · 2 篇 (点击展开摘要,时间倒序)

Ultrabroadband air-dielectric double-chirped mirrors for laser frequency combs
Light Science & Applications · 2025 · cited 3 · doi.org/10.1038/s41377-025-01961-4
Dispersion engineering is critical for the creation of integrated broadband laser frequency combs. In the long wavelength infrared range (LWIR, 8-13 µm), frequency combs based on quantum cascade lasers are attractive since they are monolithic, fundamental oscillators with high power levels and efficiencies. One effective approach for expanding quantum cascade laser gain bandwidth is by stacking multiple gain media with different center lasing frequencies, as this leads to flatter broadband gain spectra. However, as the gain bandwidth is increased, dispersion becomes the main limiting factor for comb bandwidth. Therefore, achieving broadband combs requires schemes that can flexibly engineer the dispersion over broad bandwidths. Here, we demonstrate the ultimate nanophotonic dispersion compensation scheme: an air-dielectric slab double-chirped mirror, which we fully integrate with the quantum cascade laser gain section. This scheme relies on the highest possible index contrast and therefore provides the maximum correction per unit length over a very broad bandwidth. With this approach, we report the successful demonstration of a broadband room-temperature LWIR laser frequency comb on a gain medium that normally does not form combs without deliberate dispersion compensations. Our air-dielectric mirrors are versatile and can be extended to other integrated laser frequency combs in different material platforms and frequency bands.
Enhanced operating temperature in terahertz quantum cascade lasers based on direct phonon depopulation
Applied Physics Letters · 2023 · cited 103 · doi.org/10.1063/5.0144705
Room temperature operation of terahertz quantum cascade lasers (THz QCLs) has been a long-pursued goal to realize compact semiconductor THz sources. In this paper, we report on improving the maximum operating temperature of THz QCLs to ∼ 261 K as a step toward the realization of this goal.