Transmission and Absorption of Bilateral Porous Silicon with Macropores or Nanowires
| Authors | V.F. Onyshchenko |
| Affiliations |
V.Ye. Lashkaryov Institute of Semiconductor Physics of National Academy of Sciences of Ukraine, 41, Nauky Ave., 03028 Kyiv, Ukraine |
| Е-mail | onyshchenkovf@isp.kiev.ua |
| Issue | Volume 16, Year 2024, Number 2 |
| Dates | Received 04 January 2024; revised manuscript received 20 April 2024; published online 29 April 2024 |
| Citation | V.F. Onyshchenko, J. Nano- Electron. Phys. 16 No 2, 02008 (2024) |
| DOI | https://doi.org/10.21272/jnep.16(2).02008 |
| PACS Number(s) | 78.20. – e |
| Keywords | Transmission (16) , Absorption (17) , Nanowires (9) , Bilateral macroporous silicon. |
| Annotation |
The transmission and absorption spectra of bilateral macroporous silicon and nanowires were calculated. The transmission and reflection of the interfaces between the monocrystalline substrate and the layers of macroporous silicon is taken into account. The absorption of bilateral macroporous silicon when one or the other layer of macroporous silicon is illuminated is considered. The transmission of the lateral interfaces between bilateral macroporous silicon and air is calculated. The transmission of the lateral interfaces of bilateral macroporous silicon depends on the reflection coefficients of the interfaces between the monocrystalline substrate and the layers of macroporous silicon and the volume fraction of pores. The incidence of light on the lateral interface between bilateral macroporous silicon and air at different angles and the effect of total internal reflection are taken into account. The dependence of the transmission and absorption spectra of bilateral macroporous silicon and nanowires on the reflection and transmission of the interface between the frontal layer of macroporous silicon and the monocrystalline substrate and the volume fraction of pores is considered. The increase in absorption and transmittance of bilateral macroporous silicon with an increase in the volume fraction of pores to a certain value and a decrease in absorption and transmittance due to an increase in the reflection of the interface between the frontal layer of macroporous silicon and the monocrystalline substrate are shown. |
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List of References |
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