Pt/PbSe optoelectronic receivers designed for 6G and terahertz communication technologies
Yükleniyor...
Tarih
2023
Dergi Başlığı
Dergi ISSN
Cilt Başlığı
Yayıncı
SPRINGER
Erişim Hakkı
info:eu-repo/semantics/closedAccess
Özet
Herein PbSe thin films are coated onto glass and semitransparent platinum substrates. The films which are treated as optoelectronic signal receivers are deposited by the thermal evaporation technique under a vacuum pressure of 10?5 mbar. The structural investigations have shown that (glass, Pt)/PbSe films are of polycrystalline nature. Optically, Pt substrates increased the transparency and reflectivity of PbSe films. The energy band gap of PbSe is also increased by 0.12 eV when films are coated onto Pt substrates. In addition the dielectric constant also increased as a result of strong interaction between Pt plasmonic particles and lead selenide. On the other hand, fitting of the imaginary part of the dielectric constant using Drude–Lorentz model has shown that coating of PbSe onto semitransparent Pt substrates increased the drift mobility of lead selenide by four times. Pt substrates resulted in a decrease in the density of free charge carriers and increases the scattering time constant at femtosecond levels. (Glass, Pt)/PbSe optoelectronic receivers displayed plasmon frequencies up to?~?13 GHz and showed terahertz cutoff frequency of?~?1.0 THz. In addition, allowing the propagation of an ac signal of low amplitude in the Pt/PbSe/Pt receivers has shown that the devices exhibit wide range of resistance tunability. The microwave cutoff frequency also reached 14 GHz. Both of the optical and electrical measurements proved the suitability of the Pt/PbSe devices for 6G and terahertz communication technologies.
Açıklama
Anahtar Kelimeler
PbSe, Thermal Evaporation, Negative Capacitance, Microwave, 6G Technology
Kaynak
Optical and Quantum Electronics
WoS Q Değeri
Q2
Scopus Q Değeri
N/A
Cilt
55
Sayı
156
Künye
Alkhamisi, M.M., Qasrawi, A.F., Khanfar, H.K. et al. Pt/PbSe optoelectronic receivers designed for 6G and terahertz communication technologies. Opt Quant Electron 55, 156 (2023). https://doi.org/10.1007/s11082-022-04434-9
