Bulgakova Vladislava, Chizhov Pavel, Ushakov Alexander, Ratnikov Pavel, Goncharov Yuri, Martyanov Artem, Kononenko Vitali, Savin Sergey, Golovnin Ilya, Konov Vitaly, Garnov Sergey
Prokhorov General Physics Institute of the Russian Academy of Sciences, 119991 Moscow, Russia.
Moscow Institute of Physics and Technology, 141701 Dolgoprudny, Russia.
Materials (Basel). 2023 Dec 26;17(1):119. doi: 10.3390/ma17010119.
Diamond is a promising material for terahertz applications. In this work, we use a non-invasive optical pump-terahertz probe method to experimentally study the photoinduced carrier dynamics in doped diamond monocrystals and a new diamond-silicon composite. The chemical vapor deposited diamond substrate with embedded silicon microparticles showed two photoinduced carrier lifetimes (short lifetime on the order of 4 ps and long lifetime on the order of 200 ps). The short lifetime is several times less than in boron-doped diamonds and nitrogen-doped diamonds which were grown using a high temperature-high pressure technique. The observed phenomenon is explained by the transport of photoexcited carriers across the silicon-diamond interface, resulting in dual relaxation dynamics. The observed phenomenon could be used for ultrafast flexible terahertz modulation.
金刚石是一种很有前途的太赫兹应用材料。在这项工作中,我们使用非侵入式光泵浦 - 太赫兹探测方法,对掺杂金刚石单晶和一种新型金刚石 - 硅复合材料中的光致载流子动力学进行了实验研究。嵌入硅微粒的化学气相沉积金刚石衬底表现出两种光致载流子寿命(短寿命约为4皮秒,长寿命约为200皮秒)。该短寿命比使用高温高压技术生长的硼掺杂金刚石和氮掺杂金刚石中的短寿命小几倍。观察到的现象可通过光激发载流子在硅 - 金刚石界面的传输来解释,从而导致双重弛豫动力学。观察到的现象可用于超快柔性太赫兹调制。