Thin copper selenide films were synthesized on polyamide sheets using the successive ionic layer adsorption and reaction (SILAR) method at three different temperatures. It was found that elevating the temperature of the solution led to the creation of copper selenide films with different features. X-ray diffraction characterization revealed that all films crystallized into a cubic Cu2−xSe, but with different crystallinity parameters. With elevating the temperature, grain size increased (6.61–14.33 and 15.81 for 40, 60 and 80 °C, respectively), while dislocation density and the strain decreased. Surface topology was investigated with Scanning Electron Microscopy and Atomic Force Microscopy, which revealed that the grains combined into agglomerates of up to 100 nm (80 °C) to 1 μm (40 °C). The value of the direct band gap of the copper selenide thin films, obtained with UV/VIS spectroscopy, varied in the range of 2.28–1.98 eV. The formation of Cu2−xSe was confirmed by Raman analysis; the ...most prominent Raman peak is located at 260 cm−1, which is attributed to binary copper selenides. The thin Cu2−xSe films deposited on polyamide showed p-type conductivity, and the electrical resistivity varied in the range of 20–50 Ω. Our results suggest that elevated temperatures prevent large agglomeration, leading to higher resistance behavior.
TY - JOUR
AU - Jakubauskas, Gediminas
AU - Gilic, Martina
AU - Paluckiene, Edita
AU - Mitric, Jelena
AU - Ćirković, Jovana
AU - Ralevic, Uros
AU - Usoviene, Egle
AU - Griskonis, Egidijus
AU - Petrasauskiene, Neringa
PY - 2022
UR - http://rimsi.imsi.bg.ac.rs/handle/123456789/1571
AB - Thin copper selenide films were synthesized on polyamide sheets using the successive ionic layer adsorption and reaction (SILAR) method at three different temperatures. It was found that elevating the temperature of the solution led to the creation of copper selenide films with different features. X-ray diffraction characterization revealed that all films crystallized into a cubic Cu2−xSe, but with different crystallinity parameters. With elevating the temperature, grain size increased (6.61–14.33 and 15.81 for 40, 60 and 80 °C, respectively), while dislocation density and the strain decreased. Surface topology was investigated with Scanning Electron Microscopy and Atomic Force Microscopy, which revealed that the grains combined into agglomerates of up to 100 nm (80 °C) to 1 μm (40 °C). The value of the direct band gap of the copper selenide thin films, obtained with UV/VIS spectroscopy, varied in the range of 2.28–1.98 eV. The formation of Cu2−xSe was confirmed by Raman analysis; the most prominent Raman peak is located at 260 cm−1, which is attributed to binary copper selenides. The thin Cu2−xSe films deposited on polyamide showed p-type conductivity, and the electrical resistivity varied in the range of 20–50 Ω. Our results suggest that elevated temperatures prevent large agglomeration, leading to higher resistance behavior.
PB - MDPI
T2 - Chemosensors
T1 - Characterization of Flexible Copper Selenide Films on Polyamide Substrate Obtained by SILAR Method—Towards Application in Electronic Devices
IS - 8
SP - 313
VL - 10
DO - 10.3390/chemosensors10080313
ER -
@article{
author = "Jakubauskas, Gediminas and Gilic, Martina and Paluckiene, Edita and Mitric, Jelena and Ćirković, Jovana and Ralevic, Uros and Usoviene, Egle and Griskonis, Egidijus and Petrasauskiene, Neringa",
year = "2022",
abstract = "Thin copper selenide films were synthesized on polyamide sheets using the successive ionic layer adsorption and reaction (SILAR) method at three different temperatures. It was found that elevating the temperature of the solution led to the creation of copper selenide films with different features. X-ray diffraction characterization revealed that all films crystallized into a cubic Cu2−xSe, but with different crystallinity parameters. With elevating the temperature, grain size increased (6.61–14.33 and 15.81 for 40, 60 and 80 °C, respectively), while dislocation density and the strain decreased. Surface topology was investigated with Scanning Electron Microscopy and Atomic Force Microscopy, which revealed that the grains combined into agglomerates of up to 100 nm (80 °C) to 1 μm (40 °C). The value of the direct band gap of the copper selenide thin films, obtained with UV/VIS spectroscopy, varied in the range of 2.28–1.98 eV. The formation of Cu2−xSe was confirmed by Raman analysis; the most prominent Raman peak is located at 260 cm−1, which is attributed to binary copper selenides. The thin Cu2−xSe films deposited on polyamide showed p-type conductivity, and the electrical resistivity varied in the range of 20–50 Ω. Our results suggest that elevated temperatures prevent large agglomeration, leading to higher resistance behavior.",
publisher = "MDPI",
journal = "Chemosensors",
title = "Characterization of Flexible Copper Selenide Films on Polyamide Substrate Obtained by SILAR Method—Towards Application in Electronic Devices",
number = "8",
pages = "313",
volume = "10",
doi = "10.3390/chemosensors10080313"
}
Jakubauskas, G., Gilic, M., Paluckiene, E., Mitric, J., Ćirković, J., Ralevic, U., Usoviene, E., Griskonis, E.,& Petrasauskiene, N.. (2022). Characterization of Flexible Copper Selenide Films on Polyamide Substrate Obtained by SILAR Method—Towards Application in Electronic Devices. in Chemosensors
MDPI., 10(8), 313.
https://doi.org/10.3390/chemosensors10080313
Jakubauskas G, Gilic M, Paluckiene E, Mitric J, Ćirković J, Ralevic U, Usoviene E, Griskonis E, Petrasauskiene N. Characterization of Flexible Copper Selenide Films on Polyamide Substrate Obtained by SILAR Method—Towards Application in Electronic Devices. in Chemosensors. 2022;10(8):313.
doi:10.3390/chemosensors10080313 .
Jakubauskas, Gediminas, Gilic, Martina, Paluckiene, Edita, Mitric, Jelena, Ćirković, Jovana, Ralevic, Uros, Usoviene, Egle, Griskonis, Egidijus, Petrasauskiene, Neringa, "Characterization of Flexible Copper Selenide Films on Polyamide Substrate Obtained by SILAR Method—Towards Application in Electronic Devices" in Chemosensors, 10, no. 8 (2022):313,
https://doi.org/10.3390/chemosensors10080313 . .
