dor_id: 41729

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650.#.4.x: Físico Matemáticas y Ciencias de la Tierra

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336.#.#.3: Artículo de Investigación

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856.4.0.u: https://rmf.smf.mx/ojs/rmf/article/view/3861/3828

100.1.#.a: Sastré Hernández, J.; Calixto, M. E.; Tufiño Velázquez, M.; Contreras Puente, G.; Morales Acevedo, A.; Casados Cruz, G.; Hernández Pérez, M. A.; Albor Aguilera, M. L.; Mendoza Pérez.

524.#.#.a: Sastré Hernández, J., et al. (2011). Cu(In,Ga)Se2 thin films processed by co-evaporation and their application into solar cells. Revista Mexicana de Física; Vol 57, No 5: 441-0. Recuperado de https://repositorio.unam.mx/contenidos/41729

245.1.0.a: Cu(In,Ga)Se2 thin films processed by co-evaporation and their application into solar cells

502.#.#.c: Universidad Nacional Autónoma de México

561.1.#.a: Facultad de Ciencias, UNAM

264.#.0.c: 2011

264.#.1.c: 2011-01-01

653.#.#.a: Cu(In; Ga)Se; Co-evaporation; thin films; solar cells

506.1.#.a: La titularidad de los derechos patrimoniales de esta obra pertenece a las instituciones editoras. Su uso se rige por una licencia Creative Commons BY-NC-ND 4.0 Internacional, https://creativecommons.org/licenses/by-nc-nd/4.0/legalcode.es, fecha de asignación de la licencia 2011-01-01, para un uso diferente consultar al responsable jurídico del repositorio por medio de rmf@ciencias.unam.mx

884.#.#.k: https://rmf.smf.mx/ojs/rmf/article/view/3861

001.#.#.#: oai:ojs.rmf.smf.mx:article/3861

041.#.7.h: eng

520.3.#.a: Polycrystalline Cu(In,Ga)Se 2(CIGS) solar cells are attractive because low cost techniques can be used to obtain high efficiency thin film photovoltaic devices. Several research groups around the world have developed CIGS/CdS solar cells with efficiencies larger than 15%sim[1] using evaporation, making it an attractive and reliable technique for thin film deposition. Our PVD system is provided with MBE-type Knudsen cells to deposit CIGS thin films on glass/Molibdenum (Mo) substrates. The deposition conditions for each metal source have been established by doing a deposition profile of temperature data vs. growth rate by co-evaporation to obtain CIGS thin film for solar cells. Characterization of the co-evaporated CIGS thin films was performed by X-ray diffraction (X-RD), scanning electron microscopy (SEM) and energy dispersive x-ray spectroscopy (EDS) techniques. Good quality polycrystalline films were obtained as shown by X-RD patterns. SEM micrographs show films having a very uniform appearance with large grain sizes (\sim 1 \μ m). Photoluminescence (PL) studies on CIGS samples with different Ga and Cu concentrations (Ga/Ga+In) = 0.25 and 0.34 and (Cu/In+Ga) = 0.83, 0.88 and 0.94) have been performed. The EDS results have shown that is possible to control very precisely the CIGS thin film composition using these Knudsen cells. Film thicknesses of\sim 3-4 \μ m, were measured with an Ambios profilemeter XP 100 stylus type. A conversion efficiency of 10.9 % has been achieved for solar cells made from the co-evaporated absorbers.

773.1.#.t: Revista Mexicana de Física; Vol 57, No 5 (2011): 441-0

773.1.#.o: https://rmf.smf.mx/ojs/rmf/index

046.#.#.j: 2020-11-25 00:00:00.000000

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last_modified: 2020-11-27 00:00:00

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Artículo

Cu(In,Ga)Se2 thin films processed by co-evaporation and their application into solar cells

Sastré Hernández, J.; Calixto, M. E.; Tufiño Velázquez, M.; Contreras Puente, G.; Morales Acevedo, A.; Casados Cruz, G.; Hernández Pérez, M. A.; Albor Aguilera, M. L.; Mendoza Pérez.

Facultad de Ciencias, UNAM, publicado en Revista Mexicana de Física, y cosechado de Revistas UNAM

Licencia de uso

Procedencia del contenido

Entidad o dependencia
Facultad de Ciencias, UNAM
Revista
Revista Mexicana de Física
Repositorio
Revistas UNAM
Contacto
Revistas UNAM. Dirección General de Publicaciones y Fomento Editorial, UNAM en revistas@unam.mx

Cita

Sastré Hernández, J., et al. (2011). Cu(In,Ga)Se2 thin films processed by co-evaporation and their application into solar cells. Revista Mexicana de Física; Vol 57, No 5: 441-0. Recuperado de https://repositorio.unam.mx/contenidos/41729

Descripción del recurso

Autor(es)
Sastré Hernández, J.; Calixto, M. E.; Tufiño Velázquez, M.; Contreras Puente, G.; Morales Acevedo, A.; Casados Cruz, G.; Hernández Pérez, M. A.; Albor Aguilera, M. L.; Mendoza Pérez.
Tipo
Artículo de Investigación
Área del conocimiento
Físico Matemáticas y Ciencias de la Tierra
Título
Cu(In,Ga)Se2 thin films processed by co-evaporation and their application into solar cells
Fecha
2011-01-01
Resumen
Polycrystalline Cu(In,Ga)Se 2(CIGS) solar cells are attractive because low cost techniques can be used to obtain high efficiency thin film photovoltaic devices. Several research groups around the world have developed CIGS/CdS solar cells with efficiencies larger than 15%sim[1] using evaporation, making it an attractive and reliable technique for thin film deposition. Our PVD system is provided with MBE-type Knudsen cells to deposit CIGS thin films on glass/Molibdenum (Mo) substrates. The deposition conditions for each metal source have been established by doing a deposition profile of temperature data vs. growth rate by co-evaporation to obtain CIGS thin film for solar cells. Characterization of the co-evaporated CIGS thin films was performed by X-ray diffraction (X-RD), scanning electron microscopy (SEM) and energy dispersive x-ray spectroscopy (EDS) techniques. Good quality polycrystalline films were obtained as shown by X-RD patterns. SEM micrographs show films having a very uniform appearance with large grain sizes (\sim 1 \μ m). Photoluminescence (PL) studies on CIGS samples with different Ga and Cu concentrations (Ga/Ga+In) = 0.25 and 0.34 and (Cu/In+Ga) = 0.83, 0.88 and 0.94) have been performed. The EDS results have shown that is possible to control very precisely the CIGS thin film composition using these Knudsen cells. Film thicknesses of\sim 3-4 \μ m, were measured with an Ambios profilemeter XP 100 stylus type. A conversion efficiency of 10.9 % has been achieved for solar cells made from the co-evaporated absorbers.
Tema
Cu(In; Ga)Se; Co-evaporation; thin films; solar cells
Idioma
eng
ISSN
2683-2224 (digital); 0035-001X (impresa)

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