Congrats on Carol’s paper in Advanced Electronic Materials!
Paper title: Polycaprolactone-Based Zinc Ink for High Conductivity Transient Printed Electronics and Antennas
Abstract: Distributed sensors and electronics can be used in agriculture to optimize crop management and improve environmental outcomes. Electronic devices in these outdoor spaces require medium to long range (>1m) wireless communication of data over several weeks or months, which in turn requires high conductivity (1 × 105 Sm−1) antennas. Printed bioinert or ecoresorbable conductors, comprising carbon, magnesium, or zinc fillers, typically exhibit conductivity on the order of 10–1000 Sm−1 and lifetimes from a few hours to a few days. A print-based fabrication process for chemically treated zinc traces, which achieves conductivity of up to 6 × 105 Sm−1 is reported here. The ink formulation uses a non-water-soluble soil biodegradable polycaprolactone binder. The ink and printing processes reported here led to stable conductive traces that are used in ultra high frequency radio frequency identification (UHF-RFID) folded dipole antennas operating at 915 MHz. The conductivity of the printed traces is maintained for over 70 days in ambient environments when traces are protected by a biodegradable beeswax encapsulation layer.
Publication:
-
Polycaprolactone-Based Zinc Ink for High Conductivity Transient Printed Electronics and Antennas
Carol L. Baumbauer,
Anupam Gopalakrishnan,
Madhur Atreya,
Gregory L. Whiting,
and
Ana C. Arias
Advanced Electronic Materials,
2024
,
.
[Abstract]
[Bibtex]
[PDF]
Distributed sensors and electronics can be used in agriculture to optimize crop management and improve environmental outcomes. Electronic devices in these outdoor spaces require medium to long range (>1m) wireless communication of data over several weeks or months, which in turn requires high conductivity (1 × 105 Sm−1) antennas. Printed bioinert or ecoresorbable conductors, comprising carbon, magnesium, or zinc fillers, typically exhibit conductivity on the order of 10–1000 Sm−1 and lifetimes from a few hours to a few days. A print-based fabrication process for chemically treated zinc traces, which achieves conductivity of up to 6 × 105 Sm−1 is reported here. The ink formulation uses a non-water-soluble soil biodegradable polycaprolactone binder. The ink and printing processes reported here led to stable conductive traces that are used in ultra high frequency radio frequency identification (UHF-RFID) folded dipole antennas operating at 915 MHz. The conductivity of the printed traces is maintained for over 70 days in ambient environments when traces are protected by a biodegradable beeswax encapsulation layer.
@article{Carol_Zinc,
author = {Baumbauer, Carol L. and Gopalakrishnan, Anupam and Atreya, Madhur and Whiting, Gregory L. and Arias, Ana C.},
title = {Polycaprolactone-Based Zinc Ink for High Conductivity Transient Printed Electronics and Antennas},
year = {2024},
doi = {10.1002/aelm.202300658},
publisher = {},
url = {https://doi.org/10.1021/acssensors.3c00630},
journal = {Advanced Electronic Materials},
volume = {},
number = {},
thumbnail = {carol2024Zinc.png},
pdf = {carol2024Zinc.pdf}
}
