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Tattooable OLEDs: new publication in Advanced Electronic Materials

OLED tattoo cross section & transfer on bottle

A new paper by Jonathan Barsotti et al. about Organic Light Emitting Diodes (OLEDs) on temporary tattoo. The study is a collaboration with groups of Dr. Virgilio Mattoli (CMBR IIT, Italy) and Prof. Franco Cacialli (UCL, London, UK). Ultrathin tattooable OLEDS are presented which can be transferred onto various target surfaces maintaining their functionality.

Publication  in Advanced Electronic Materials:

Ultrathin, Ultra‐Conformable, and Free‐Standing Tattooable Organic Light‐Emitting Diodes

Jonathan Barsotti, Alexandros G. Rapidis, Ikue Hirata, Francesco Greco, Franco Cacialli, Virgilio Mattoli

Advanced Electronic Materials, 2001145 (2021).

DOI: 10.1002/aelm.202001145
https://onlinelibrary.wiley.com/doi/full/10.1002/aelm.202001145

UPDATE:
The publication on the tattooable OLED got mentioned in the BBC article “Could electric tattoos be the next step in body art?”.

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News Publications

Book “Organic Flexible Electronics”

We contributed with a Chapter to a new book “Organic Flexible Electronics”, edited by P. Cosseddu and M. Caironi by Elsevier.

Our contribution to the book:

Chapter 15 – Ultraconformable Organic Electronics

L. M. Ferrari, S. Taccola, J. Barsotti, V. Mattoli,  F. Greco
in Organic Flexible Electronics, Eds. P. Cosseddu, M. Caironi, Elsevier 2021, pages 437-478
Publication Date: October 5, 2020
Link to the Chapter on Science Direct – Elsevier

Cover Book

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News Publications

Invited Review about Tattoos published in IOP Multifunctional Materials

Check out our INVITED REVIEW:

“Temporary tattoo as unconventional substrate for conformable and transferable electronics on skin and beyond”

Laura M. Ferrari, Kirill Keller, Bernhard Burtscher, Francesco Greco*
Multifunctional Materials, 2020, 3 3.
Published online on July 16, 2020
DOI: 10.1088/2399-7532/aba6e3

Tattoo paper structure
from Ferrari et al. Multifunctional Materials 2020, 3 3. IOP Publishing (CC BY License)
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News Publications

LIG paper published in ACS Applied Materials & Interfaces

“Stretchable and Skin-Conformable Conductors Based on Polyurethane/Laser-Induced Graphene”
Stretchable and Skin-Conformable Conductors Based on Polyurethane/Laser-Induced Graphene

Alexander Dallinger, Kirill Keller, Harald Fitzek, Francesco Greco
ACS Appl. Mater. Interfaces, 19855-19865
Publication Date: April 6, 2020
https://doi.org/10.1021/acsami.0c03148

Abstract

The conversion of various polymer substrates into laser-induced graphene (LIG) with a CO2 laser in ambient condition is recently emerging as a simple method for obtaining patterned porous graphene conductors, with a myriad of applications in sensing, actuation, and energy. In this paper, a method is presented for embedding porous LIG (LIG-P) or LIG fibers (LIG-F) into a thin (about 50 μm) and soft medical grade polyurethane (MPU) providing excellent conformal adhesion on skin, stretchability, and maximum breathability to boost the development of various unperceivable monitoring systems on skin. The effect of varying laser fluence and geometry of the laser scribing on the LIG micro–nanostructure morphology and on the electrical and electromechanical properties of LIG/MPU composites is investigated. A peculiar and distinct behavior is observed for either LIG-P or LIG-F. Excellent stretchability without permanent impairment of conductive properties is revealed up to 100% strain and retained after hundreds of cycles of stretching tests. A distinct piezoresistive behavior, with an average gauge factor of 40, opens the way to various potential strain/pressure sensing applications. A novel method based on laser scribing is then introduced for providing vertical interconnect access (VIA) into LIG/MPU conformable epidermal sensors. Such VIA enables stable connections to an external measurement device, as this represents a typical weakness of many epidermal devices so far. Three examples of minimally invasive LIG/MPU epidermal sensing proof of concepts are presented: as electrodes for electromyographic recording on limb and as piezoresistive sensors for touch and respiration detection on skin. Long-term wearability and functioning up to several days and under repeated stretching tests is demonstrated.

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News Publications

Temporary Tattoo Electrodes for EEG – Brain recordings: new publication in npj Flexible Electronics

A new paper by Laura Ferrari et al. about temporary tattoo electrodes for on-skin electrophysiological recordings, in collaboration with group of Prof. Esma Ismailova (BEL EMSE, France). Electroencephalographic (EEG) signals are recorded in a clinical environment.

Publication (Open Access) in npj Flexible Electronics:
Conducting polymer tattoo electrodes in clinical electro- and magneto-encephalography

Laura M. Ferrari, Usein Ismailov, Jean-Michel Badier, Francesco Greco & Esma Ismailova

npj Flex Electron 4, 4 (2020).

DOI: 10.1038/s41528-020-0067-z
https://www.nature.com/articles/s41528-020-0067-z