Hao Wenjie, Gu Minghui, Tian Zhenyun, Fu Shaohua, Meng Meng, Zhang Hong, Guo Jiandong, Zhao Jimin
College of Physics, Sichuan University, Chengdu, 610065, China.
Beijing National Laboratory for Condensed Matter Physics, Institute of Physics, Chinese Academy of Sciences, Beijing, 100190, China.
Adv Sci (Weinh). 2024 Jan;11(2):e2305900. doi: 10.1002/advs.202305900. Epub 2023 Nov 20.
Electron-phonon coupling (EPC) and phonon-phonon scattering (PPS) are at the core of the microscopic physics mechanisms of vast quantum materials. However, to date, there are rarely reports that these two processes can be spatially separated, although they are usually temporally detached with different characteristic lifetimes. Here, by employing ultrafast spectroscopy to investigate the photo-carrier ultrafast dynamics in a LaCoO thin film on a (100) SrTiO substrate, intriguing evidence is found that the two interactions are indeed spatially separated. The EPC mainly occurs in the thin film, whereas PPS is largely in the substrate, especially at the several atomic layers near the interface. Across-interface penetration and decay of optical phonons into acoustic phonons thus naturally occur. An EPC strength λ = 0.30 is also obtained and an acoustic phonon mode at 45.3 GHz is observed. The finding lays out a cornerstone for future quantum nano device designs.
电子-声子耦合(EPC)和声子-声子散射(PPS)是大量量子材料微观物理机制的核心。然而,迄今为止,很少有报道表明这两个过程能够在空间上分离,尽管它们通常在时间上因具有不同的特征寿命而相互分离。在这里,通过利用超快光谱研究(100)SrTiO衬底上LaCoO薄膜中的光载流子超快动力学,发现了有趣的证据,表明这两种相互作用确实在空间上分离。EPC主要发生在薄膜中,而PPS主要发生在衬底中,特别是在界面附近的几个原子层中。因此,光学声子自然会发生跨界面渗透并衰变为声学声子。还获得了EPC强度λ = 0.30,并观察到45.3 GHz的声学声子模式。这一发现为未来量子纳米器件的设计奠定了基石。
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