Abstract
Organic-inorganic hybrid metal halide perovskite solar cells show exceptional optoelectronic properties in line with low-cost and large-scale fabrication and have demonstrated a leap forward in power conversion efficiency (PCE). PCEs emerged from 3.8% in initial studies [1] to today’s certified 25.5% (single-junction) and close to 30% (perovskite-silicon tandem devices) [2]. The main challenge prior to large scale commercialization of this type of solar cells, is now to improve long term stability at the module level.
Here, the interplay of multi-modal, scale-bridging (macro to nano) materials and device characterization with probes like focused electron, ion or laser beams and tips and will play a significant role to further advance long term stability, sustainability and recyclability.
Here, the interplay of multi-modal, scale-bridging (macro to nano) materials and device characterization with probes like focused electron, ion or laser beams and tips and will play a significant role to further advance long term stability, sustainability and recyclability.
Translated title of the contribution | Skalenüberbrückende, multimodale Charakterisierung von Metallhalogenid-Perowskit-Materialien |
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Original language | English |
Title of host publication | Publications |
Publication status | Published - Mar 2023 |
Research Field
- Energy Conversion and Hydrogen Technologies