Carlos A. Rodríguez-Castañeda scite author profile

Cadmium sulfide nanoparticles (CdS-n) are excellent electron acceptor for hybrid solar cell applications. However, the particle size and properties of the CdS-n products depend largely on the synthesis methodologies. In this work, CdS-n were synthetized by microwave heating using thioacetamide (TA) or thiourea (TU) as sulfur sources. The obtained CdS-n(TA) showed a random distribution of hexagonal particles and contained TA residues. The latter could originate the charge carrier recombination process and cause a low photovoltage (Voc, 0.3 V) in the hybrid solar cells formed by the inorganic particles and poly(3-hexylthiophene) (P3HT). Under similar synthesis conditions, in contrast, CdS-n synthesized with TU consisted of spherical particles with similar size and contained carbonyl groups at their surface. CdS-n(TU) could be well dispersed in the nonpolar P3HT solution, leading to aVocof about 0.6–0.8 V in the resulting CdS-n(TU) : P3HT solar cells. The results of this work suggest that the reactant sources in microwave methods can affect the physicochemical properties of the obtained inorganic semiconductor nanoparticles, which finally influenced the photovoltaic performance of related hybrid solar cells.

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Microwave Synthesized Monodisperse CdS Spheres of Different Size and Color for Solar Cell Applications

Rodríguez-Castañeda

Moreno-Romero

Martínez-Alonso

et al. 2015

Journal of Nanomaterials

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Monodisperse CdS spheres of size of 40 to 140 nm were obtained by microwave heating from basic solutions. It is observed that larger CdS spheres were formed at lower solution pH (8.4–8.8) and smaller ones at higher solution pH (10.8–11.3). The color of CdS products changed with solution pH and reaction temperature; those synthesized at lower pH and temperature were of green-yellow color, whereas those formed at higher pH and temperature were of orange-yellow color. A good photovoltage was observed in CdS:poly(3-hexylthiophene) solar cells with spherical CdS particles. This is due to the good dispersion of CdS nanoparticles in P3HT solution that led to a large interface area between the organic and inorganic semiconductors. Higher photocurrent density was obtained in green-yellow CdS particles of lower defect density. The efficient microwave chemistry accelerated the hydrolysis of thiourea in pH lower than 9 and produced monodisperse spherical CdS nanoparticles suitable for solar cell applications.

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Thermal Evaporation–Oxidation Deposited Aluminum Oxide as an Interfacial Modifier to Improve the Performance and Stability of Zinc Oxide-Based Planar Perovskite Solar Cells

Rodríguez-Castañeda

Moreno-Romero

Corpus-Mendoza

et al. 2020

ACS Appl. Energy Mater.

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The acid−base chemistry at the interface of zinc oxide (ZnO) and methylammonium lead tri-iodide (perovskite) leads to a proton transfer reaction that results in perovskite degradation. In perovskite solar cells (PSCs), this reaction produces low efficiency and reduces the long-term stability. In this work, an aluminum (Al) layer of 1−2 nm thickness is thermally evaporated on top of ZnO or Al 3+ -doped ZnO (ZnO:Al) thin films and then annealed at 450 °C for 30 min. Thermal annealing converts the surface aluminum film into a transparent and approximately 2 nm thick aluminum oxide (AlO x ) layer. Also, a larger concentration of oxygen vacancies is obtained by the annealing of Al and attributed to the diffusion of Al into the ZnO surface, and the ZnO underlayer results in a more conductive material. As a result, the chemical stability of perovskite coatings on top of AlO x -coated ZnO films is significantly enhanced, and the flat-band level of ZnO shifts 0.09 eV upwards, which improves the energetic level alignment in PSCs. This allows us to obtain ZnO:Al/AlO x -based planar PSCs that show a maximum efficiency of 16.56% with the perovskite layer prepared in ambient conditions under a relative humidity of 40−50%. After continuous illumination of about 30 min in air, ZnObased PSCs without AlO x layer retain only 34.5% of their original efficiency, whereas those with AlO x retain about 92.5%. It is demonstrated that thermal evaporation−oxidation is an efficient method to modify the surface properties of inorganic semiconductor thin films and improves both the performance and stability of PSCs.

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