Perovskite Solar Cells: Insights into early stages of structure formation

Using Small-Angle Scattering the early stages of structure formation in precursor solutions of perovskite solar cells have been explored.

Using Small-Angle Scattering the early stages of structure formation in precursor solutions of perovskite solar cells have been explored. © M. Flatken/HZB

Using small-angle scattering at the PTB X-ray beamline of BESSY II, an HZB team was able to experimentally investigate the colloidal chemistry of perovskite precursor solutions used for solar cell production. The results contribute to the targeted and systematic optimization of the manufacturing process and quality of these exciting semiconductor materials.

Halide perovskite semiconductors are inexpensive, versatile, and high-performance materials used in solar cells as well as optoelectronic devices. The crystalline perovskite thin films required for this purpose are prepared at low temperature from solution: While the solvent evaporates during an annealing step, highly coordinated iodoplumbates interact and subsequently form the polycrystalline thin film. The quality of the thin film ultimately determines the performance of the semiconductor material. Up to now, it has not been possible to achieve a comprehensive impression of the role of the colloidal chemistry in the precursor that is considered to be directional for crystallinity and the further processing.

Observing the formation of structures

Now, an HZB team led by Prof. Antonio Abate has used small-angle scattering to experimentally determine how the initially disordered elements in the precursor solution find their way into primary subunits, interacting and thus providing a first "pre crystalline" arrangement for further conversion to perovskite thin films.

The results indicate that primary subgroups consisting of lead and iodine are formed, so-called iodoplumbates, in which a lead atom is octahedral surrounded by six iodine atoms. These subunits further form a dynamic colloidal network into which the organic methylammonium cation is incorporated, from which the familiar perovskite structure arises.

"While conventional methods have so far limited us to measure only highly diluted precursor solutions, HZB's ASAXS instrument at PTB's FCM beamline at BESSY II makes it possible to study the precursor at a concentration applicable for solar cell fabrication," emphasizes Marion Flatken, who carried out the measurements as part of her PhD thesis.

Small Angle Scattering data show clear evidence

"Small-angle scattering is ideally suited for measuring nanoparticles and substructures in solutions," explains Dr. Armin Hoell, an expert for small-angle scattering and a corresponding author of the study.  "The measured data provide clear evidence for the formation of initial nanometer-sized clusters, which fit the PbI6 octahedron well in terms of dimension and organize themselves in a concentration-dependent manner. Importantly, the measurements are also highly reproducible."

The presented technique and related results can help to further optimize the fabrication process and to more systematically control the quality of perovskite thin films during solar cell fabrication striving for optimal performances.   

arö


You might also be interested in

  • Key role of nickel ions in the Simons process discovered
    News
    21.05.2024
    Key role of nickel ions in the Simons process discovered
    Researchers at the Federal Institute for Materials Research and Testing (BAM) and Freie Universität Berlin have discovered the exact mechanism of the Simons process for the first time. The interdisciplinary research team used the BESSY II light source at the Helmholtz Zentrum Berlin for this study.

  • Watching indium phosphide at work
    Science Highlight
    15.05.2024
    Watching indium phosphide at work
    Indium phosphide is a versatile semiconductor. The material can be used for solar cells, for hydrogen production and even for quantum computers – and with record-breaking efficiency. However, little research has been conducted into what happens on its surface. Researchers have now closed this gap and used ultra-fast lasers to scrutinise the dynamics of the electrons in the material.
  • Freeze casting - a guide to creating hierarchically structured materials
    Science Highlight
    25.04.2024
    Freeze casting - a guide to creating hierarchically structured materials
    Freeze casting is an elegant, cost-effective manufacturing technique to produce highly porous materials with custom-designed hierarchical architectures, well-defined pore orientation, and multifunctional surface structures. Freeze-cast materials are suitable for many applications, from biomedicine to environmental engineering and energy technologies. An article in "Nature Reviews Methods Primer" now provides a guide to freeze-casting methods that includes an overview on current and future applications and highlights characterization techniques with a focus on X-ray tomoscopy.