Low-Temperature and High-Speed Fabrication of Nanocrystalline Ge Films on Cu Substrates Using Sub-Torr-Pressure Plasma Sputtering

IF 1.8 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY IEEE Open Journal of Nanotechnology Pub Date : 2022-11-11 DOI:10.1109/OJNANO.2022.3221462

Giichiro Uchida;Kenta Nagai;Ayaka Wakana;Yumiko Ikebe

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Abstract

We fabricated nanocrystalline Ge films using radio-frequency (RF) magnetron plasma sputtering deposition under a high Ar-gas pressure. The Ge nanograins changed from amorphous to crystalline when the distance between the Ge sputtering target and the substrate was decreased to 5 mm and the RF input power was 11.8 W/cm ² (60 W), where the deposition rate was as high as 660 nm/min. In addition, the size of the nanocrystalline grains increased from 100 to 307 nm when the RF input power for plasma production was increased from 11.8 W/cm ² (60 W) to 17.7 W/cm ² (90 W). In the developed narrow-gap plasma process at sub-Torr pressures, nanocrystalline Ge films were successfully fabricated on Cu substrates at low temperatures, without the substrate being heated. However, when annealing was conducted under an N ₂ atmosphere, which is the conventional method to induce solid-phase crystallization, the amorphous Ge layer on a Cu substrate changed to a Cu ₃ Ge crystal layer through interdiffusion of Ge and Cu atoms at 400–500 °C.

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亚托压等离子溅射在Cu衬底上低温高速制备纳米晶锗薄膜

在高氩气压力下，采用射频磁控等离子溅射沉积法制备了纳米晶锗薄膜。当溅射靶与衬底之间的距离减小到5 mm，射频输入功率为11.8 W/cm2 (60 W)，沉积速率高达660 nm/min时，Ge纳米颗粒由无定形变为结晶。此外，当用于等离子体生产的射频输入功率从11.8 W/cm2 (60 W)增加到17.7 W/cm2 (90 W)时，纳米晶颗粒的尺寸从100 nm增加到307 nm。在亚托尔压力下开发的窄间隙等离子体工艺中，在低温下成功地在Cu衬底上制备了纳米晶锗薄膜，而无需加热衬底。然而，当采用诱导固相结晶的常规方法在N2气氛下进行退火时，在400-500℃时，Cu衬底上的非晶态Ge层通过Ge和Cu原子的相互扩散转变为Cu3Ge晶体层。

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