Scale-bridging, multi-modal characterization of metal halide perovskite materials and devices

Rita Ebner; Silke Christiansen; S. Pechmann; G. Sarau; Tommaso Fontanot; Aranzazu Aguirre; Imo-Imomec Imec; Maria Hadjipanayi; V. Paraskeva; George E. Georghiou

Scale-bridging, multi-modal characterization of metal halide perovskite materials and devices

Rita Ebner
, Silke Christiansen (Speaker)
, S. Pechmann
, G. Sarau
, Tommaso Fontanot
, Aranzazu Aguirre
, Imo-Imomec Imec
, Maria Hadjipanayi
, V. Paraskeva
, George E. Georghiou

Energy Conversion & Hydrogen

Fraunhofer Institute for Ceramic Technologies and Systems IKTS
Max Planck Institute for the Science of Light
IMEC Interuniversity Microelectronics Centre
FOSS Research Centre for Sustainable Energy, Department of Electrical and Computer Engineering, University of Cyprus

Research output: Chapter in Book or Conference Proceedings › Conference Proceedings with Oral Presentation › peer-review

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.

Translated title of the contribution	Skalenüberbrückende, multimodale Charakterisierung von Metallhalogenid-Perowskit-Materialien
Original language	English
Title of host publication	Publications
Publication status	Published - Mar 2023

Research Field

Energy Conversion and Hydrogen Technologies

Cite this

@inproceedings{c3d2f8015c594f9495e118e38914be15,

title = "Scale-bridging, multi-modal characterization of metal halide perovskite materials and devices",

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{\textquoteright}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. ",

keywords = "Perovskites, Characterization",

author = "Rita Ebner and Silke Christiansen and S. Pechmann and G. Sarau and Tommaso Fontanot and Aranzazu Aguirre and Imo-Imomec Imec and Maria Hadjipanayi and V. Paraskeva and Georghiou, \{George E.\}",

year = "2023",

month = mar,

language = "English",

booktitle = "Publications",

}

TY - GEN

T1 - Scale-bridging, multi-modal characterization of metal halide perovskite materials and devices

AU - Ebner, Rita

AU - Pechmann, S.

AU - Sarau, G.

AU - Fontanot, Tommaso

AU - Aguirre, Aranzazu

AU - Imec, Imo-Imomec

AU - Hadjipanayi, Maria

AU - Paraskeva, V.

AU - Georghiou, George E.

A2 - Christiansen, Silke

PY - 2023/3

Y1 - 2023/3

N2 - 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.

AB - 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.

KW - Perovskites

KW - Characterization

M3 - Conference Proceedings with Oral Presentation

BT - Publications

ER -

Scale-bridging, multi-modal characterization of metal halide perovskite materials and devices

Abstract

Research Field

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Cite this