Vapor Transport Deposition of Methylammonium Iodide for Perovskite Solar Cells

Vapor-based processes are promising options to deposit metal halide perovskite solar cells in an industrial environment due to their ability to deposit uniform layers over large areas in a controlled environment without resorting to the use of (possibly toxic) solvents. In addition, they yield conformal layers on rough substrates, an important aspect in view of producing perovskite/ crystalline silicon tandem solar cells featuring a textured silicon wafer for light management. While the inorganic precursors of the perovskite are well suited for thermal evaporation in high vacuum, the sublimation of the organic ones is more complex to control due to their high vapor pressure. To tackle this issue, we developed a vapor transport deposition chamber for organohalide deposition that physically dissociates the organic vapor evaporation zone from the deposition chamber. Once evaporated, organic vapors, here methylammonium iodide (MAI), are transported to the deposition chamber by a carrier gas through a showerhead, ensuring a spatially homogeneous conversion of PbI2 templates to the perovskite phase. The method enables the production of homogeneous perovskite layers on a textured 6 in. wafer. Furthermore, small-scale methylammonium lead iodide solar cells are also processed to validate the quality of the absorbers produced by this hybrid thermal evaporation/vapor transport deposition process.

Investigation on the impact of passivation in perovskite solar cells

Erfan Shirzadi

Conversion of sunlight to electricity is the most plausible approach towards the generation of renewable energies. During recent decade lead halide perovskites (LHPs) have proven to be promising candidates for photovoltaic applications such as solar cells. LHPs can be made easily in laboratories around the world via solution process methods and many universities can afford to participate in their development. How-ever, LHPs suffer from instability issues and their efficiencies can be further improved. In this thesis, both instability and efficiency challenges are addressed. We showed by doping the precursor of methylammonium lead iodide (MAPbI3) perovskite with a relatively large cation of 2-Choloroethylammonium (CLEA), perovskites films with CLEA incorporated into their structures are formed. The novel perovskite is able to withstand high temperatures as high as 80°C while achieving efficiencies > 19% in MAPbI3-based perovskite solar cells (PSCs). Various approaches have been employed for the passivation of the defects in perovskite solar cells Vari-ous approaches have been employed to passivate the defects in perovskite films used in perovskite solar cells (PSCs). However, the passivation mechanism is often unclear at a molecular level and the reason for enhanced PSC performance remains elusive. Here, we describe passivation based on the deposition of two dimensional (2D) perovskites (obtained from para-halophenylethylammonium iodide) on the surface of perovskite films. Moreover, the mechanism of passivation was elucidated and was traced to the high work function of the 2D perovskites, which induce band-bending at the surface of perovskite film and therefore reduces the charge carrier recombination at the interface of perovskite and the hole transporting material (HTM). Efficiencies >22% with average voltages >1.15 V were achieved using a typical mesoporous-TiO2 and Spiro-OMeTAD device configuration. This study paves the way for PSCs efficiency improvement by rational design. The employment of 2D perovskites is a promising approach to tackle the stability and voltage issues inherent in perovskite solar cells. It remains unclear however whether other perovskites with different dimensionalities have the same effect on efficiency and stability. Here, we report the use of quasi-3D azetidinium lead iodide (AzPbI3) as a secondary layer on top of the primary 3D perovskite film that results in significant improvements in the photovoltaic parameters. Remarkably, utilization of AzPbI3 leads to the passivation resulting in a power conversion efficiency (PCE) of 22.4 %. The open-circuit voltage obtained is as high as 1.18 V, which is among the highest reported to date for single-junction perovskite solar cells, corresponding to a voltage deficit of 0.37 V for a bandgap of 1.55 eV. Studying the compositional instability of mixed ion perovskites under light illumination is important to understand the mechanisms underlying their efficiency and stability. However, current techniques are limited in resolution and are unable to deconvolute minor ion migration phenomena. Here, we describe a method that enables ion migration to be studied allowing different segregation mechanisms to be elucidated. We applied statistical analysis to cathodoluminescence data to generate compositional distribution histograms. Using these histograms, we identified two different ion migration phenomena, horizontal ion migration (HIM) and vertical ion migration (

EPFL2021

Luminescent and electronic properties of perovskite solar cells

Brian Irving Carlsen

Perovskite solar cells show great promise to serve as an alternative for traditional silicon-based solar cells, however several problems present obstacles for their commercialization. Standard perovskite cells contain lead, which is toxic to humans and harmful to the environment. Alternative perovskite compositions offer the opportunity to replace lead with non-toxic metals. Lead can be directly replaced by substituting it for tin. Unfortunately, tin-based perovskite solar cells do not show the same efficiency or stability as their lead-based counterparts. Using numerical modeling, a study of a current optimized, tin-based solar cell was performed to understand its efficiency limitations and where the most gains can be acquired. While the short-circuit current of the device is high, its limiting factors arise from those already known, primarily the alignment of the electron transport layer with the perovskite conduction band.Another option for replacing lead is by using a double perovskite. This class of perovskites replaces lead with two different metals that maintain charge neutrality. While providing more compositional freedom compared to the direct replacement of lead, double perovskites offer their own challenges. To better understand transport phenomenon between the transport layers and the perovskite, an investigation into the temperature dependent photoluminescence of Cs2AgBiBr6 with different hole and electron transport layers was performed. No clear trends appear allowing a comparison of the transport layers, but some speculations are provided to explain the results common amongst all the samples.Lead is not the only roadblock for perovskites though, as they also show instability across multiple domains. Two of the most prominent ways instability shows up are closely linked -- ionic motion and reversible degradation. A continuation of an insightful paper by Domanski \emph{et. al.} was performed to further elucidate the effects of ionic movement on reversible degradation processes. We show that these processes can be controlled by the application of a bias voltage and that the enhancement of these processes by illumination is not significant. We continued the examination of these reversible processes by studying their effects under real world conditions. Several perovskite solar cells were subjected to real world conditions in a controlled environment during which we tracked their performance. By comparing the measured data to those calculated if the cells had remained pristine we are able to quantify and separate the reversible from irreversible processes.Finally, a more fundamental investigation was made into the internal mechanisms of the perovskite cells. A temperature dependent study correlating photoluminescence spectra and current-voltage curves was performed revealing different two regimes operation. The potential mechanisms underlying each regime are explored.

EPFL2022

Investigation on the impact of passivation in perovskite solar cells

Erfan Shirzadi

EPFL2021

Luminescent and electronic properties of perovskite solar cells

Brian Irving Carlsen

EPFL2022