太赫兹辐射
材料科学
光电子学
光子学
声子
极化子
电介质
表面声子
太赫兹间隙
电场
太赫兹光谱与技术
光学
远红外激光器
物理
凝聚态物理
激光器
太赫兹超材料
量子力学
作者
Rui Xu,Tong Lin,Jiaming Luo,Xiaotong Chen,Elizabeth R. Blackert,Ahsa Moon,Khalil M. JeBailey,Hanyu Zhu
标识
DOI:10.1002/adma.202302974
摘要
Abstract Photonics in the frequency range of 5–15 terahertz (THz) potentially open a new realm of quantum materials manipulation and biosensing. This range, sometimes called “the new terahertz gap”, is traditionally difficult to access due to prevalent phonon absorption bands in solids. Low‐loss phonon–polariton materials may realize sub‐wavelength, on‐chip photonic devices, but typically operate in mid‐infrared frequencies with narrow bandwidths and are difficult to manufacture on a large scale. Here, for the first time, quantum paraelectric SrTiO 3 enables broadband surface phonon–polaritonic devices in 7–13 THz. As a proof of concept, polarization‐independent field concentrators are designed and fabricated to locally enhance intense, multicycle THz pulses by a factor of 6 and increase the spectral intensity by over 90 times. The time‐resolved electric field inside the concentrators is experimentally measured by THz‐field‐induced second harmonic generation. Illuminated by a table‐top light source, the average field reaches 0.5 GV m −1 over a large volume resolvable by far‐field optics. These results potentially enable scalable THz photonics with high breakdown fields made of various commercially available phonon–polariton crystals for studying driven phases in quantum materials and nonlinear molecular spectroscopy.
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