Your search keyword '"Tejada, Alvaro"' showing total 4 results

1. Field Effect Passivation in Perovskite Solar Cells by a LiF Interlayer.

Author

Menzel, Dorothee, Al‐Ashouri, Amran, Tejada, Alvaro, Levine, Igal, Guerra, Jorge Andrés, Rech, Bernd, Albrecht, Steve, and Korte, Lars

Subjects

SOLAR cells, INDUCTIVE effect, ELECTRON transport, PASSIVATION, PHOTOVOLTAIC power systems, PEROVSKITE, OPEN-circuit voltage, SURFACE photovoltage

Abstract

The fullerene C60 is commonly applied as the electron transport layer in high‐efficiency metal halide perovskite solar cells and has been found to limit their open circuit voltage. Through ultra‐sensitive near‐UV photoelectron spectroscopy in constant final state mode (CFSYS), with an unusually high probing depth of 5–10 nm, the perovskite/C60 interface energetics and defect formation is investigated. It is demonstrated how to consistently determine the energy level alignment by CFSYS and avoid misinterpretations by accounting for the measurement‐induced surface photovoltage in photoactive layer stacks. The energetic offset between the perovskite valence band maximum and the C60 HOMO‐edge is directly determined to be 0.55 eV. Furthermore, the voltage enhancement upon the incorporation of a LiF interlayer at the interface can be attributed to originate from a mild dipole effect and probably the presence of fixed charges, both reducing the hole concentration in the vicinity of the perovskite/C60 interface. This yields a field effect passivation, which overcompensates the observed enhanced defect density in the first monolayers of C60. [ABSTRACT FROM AUTHOR]

Published

2022

2. Hybrid Perovskite Degradation from an Optical Perspective: A Spectroscopic Ellipsometry Study from the Deep Ultraviolet to the Middle Infrared.

Author

Tejada, Alvaro, Peters, Sven, Al‐Ashouri, Amran, Turren‐Cruz, Silver Hamill, Abate, Antonio, Albrecht, Steve, Ruske, Florian, Rech, Bernd, Guerra, Jorge Andrés, and Korte, Lars

Subjects

ELLIPSOMETRY, PEROVSKITE

Abstract

A quantitative analysis of the thermally induced degradation of various device‐relevant multi‐cation hybrid perovskite films is performed using spectroscopic ellipsometry, for temperatures between 80 and 120 °C. The studied compositions are a triple cation perovskite Cs0.05(MA0.17FA0.83)0.95Pb(Br0.17I0.83)3, a Rb‐containing variant Rb0.05Cs0.05(MA0.17FA0.83)0.90Pb(Br0.17I0.83)3, and a methylammonium‐free Rb0.05Cs0.10FA0.85PbI3 composition. A very wide combined spectral range of 200 nm to 25 μm is covered by combining the data from two separate instruments. The relative changes in organic cation concentrations are quantified from the middle infrared molecular absorption bands, leveraging the use of point‐by‐point fitting for increased sensitivity. Additionally, the formation of PbI2 and non‐perovskite δ‐CsPbI3 phases is evidenced from Bruggemann effective medium fits to the visible and ultraviolet complex refractive indices. Methylammonium is almost completely depleted from the relevant compositions within 100 to 285 min of thermal annealing. The MA‐free perovskite degrades faster at intermediate temperatures, which is attributed to phase instability due to the formation of δ‐CsPbI3 in addition to PbI2. [ABSTRACT FROM AUTHOR]

Published

2022

3. Analysis of the physical and photoelectrochemical properties of c-Si(p)/a-SiC:H(p) photocathodes for solar water splitting.

Author

del Carmen Mejia, María, Sánchez, Luis Francisco, Kurniawan, Mario, Eggert, Lara, Tejada, Alvaro, Camargo, Magali, Grieseler, Rolf, Rumiche, Francisco, Díaz, Isabel, Bund, Andreas, and Guerra, Jorge Andrés

Subjects

SILICON solar cells, PHOTOELECTROCHEMICAL cells, ALUMINUM films, SILICON carbide thin films, HYDROGENATED amorphous silicon, PHOTOCATHODES, SPACE charge, CHARGE transfer

Abstract

The photoelectrochemical (PEC) properties of sputtered aluminum doped hydrogenated amorphous silicon carbide thin films grown on p-type crystalline silicon substrates were investigated in 1 M solution under chopped light illumination. Optical and structural properties of the top absorber layer were systematically assessed after post-deposition isochronical annealing treatments. Samples exhibited a noticeable improvement of the opto-electronic properties after thermal treatments. In addition, an abrupt enhancement of the photocurrent was observed reaching a saturation value of 17 mA cm−2 at −1.75 V vs. Ag/AgCl (3.5 M KCl). In this research we propose that this enhancement effect is associated to a charge transfer kinetic mechanism influenced by surface states and the p-type substrate. The latter most likely due to the space charge region extending beyond the absorber layer reaching the substrate. Current density-potential and electrochemical impedance spectroscopy measurements in dark revealed a reduction of the native layer at cathodic potentials higher than −1 V vs. Ag/AgCl (3.5 M KCl), which contributes to the high charge transfer kinetic of the system. We believe that these results will contribute to understand the substrate influence in the PEC performance of top absorber layers in multilayer structures for solar water splitting. [ABSTRACT FROM AUTHOR]

Published

2021

4. Erratum: Analysis of the physical and photoelectrochemical properties of c-Si(p)/a-SiC:H(p) photocathodes for solar water splitting (2021 J. Phys. D: Appl. Phys.54 195101).

Author

del Carmen Mejia, María, Sánchez, Luis Francisco, Kurniawan, Mario, Eggert, Lara, Tejada, Alvaro, Camargo, Magali, Grieseler, Rolf, Rumiche, Francisco, Díaz, Isabel, Bund, Andreas, and Guerra, Jorge Andrés

Subjects

PHOTOCATHODES, REDUCTION potential, SOLAR cells, ELECTRONIC journals

Abstract

Ph y s. 54 (2021) 26960 1 (3pp) ht tps://doi.or g/1 0.1 088/1 361-6463/abef ee Er r at um: Anal y sis of the ph y sical and phot oelectr oc hemical pr oper ties of c-Si(p)/a-SiC:H(p) phot ocathodes f or solar w at er split ting (2021 J. Ph y s. D: Appl. J our nal of Ph y sics D: Applied Ph y sics J. Ph y s. D: Appl. Erratum: Analysis of the physical and photoelectrochemical properties of c-Si(p)/a-SiC:H(p) photocathodes for solar water splitting (2021 J. Phys. [Extracted from the article]

Published

2021