Flexible, four-electrode conductivity cell for biologging applications

A. Kaidaorva, M. Marengo, Giovanni Marinaro, N.R. Geraldi, R. Wilson, Carlos M. Duarte, Jürgen Kosel

Research output: Contribution to journalArticlepeer-review

10 Scopus citations


Global ocean circulation, governed by the salinity of seawater, is a key contributor in supporting marine life and in regulating climate. Biologging has enabled researchers to record in-situ ocean parameters from free-ranging animals, as they swim through their environment. Current salinity sensors are bulky, expensive, highly intrusive and also susceptible to corrosion and biofouling. We present a four-electrode conductivity cell based on laserinduced graphene (LIG) on a polyimide substrate for salinity measurements. The flexible, lightweight and costefficient sensors operate under various bending conditions with an accuracy of 0.5 psu. The sensors offer a linear response to salinity, as well as a high sensitivity of 0.85 mS/psu, and they operate over a wide range of frequencies (10 kHz–100 kHz). These characteristics considerably relax the requirements for the circuit of the data logger. A four electrodes configuration reduces the dependency on the electrical double layer, since the electrodes used to drive a current are different from the electrodes measuring the voltage drop. The sensors’ deployment in the Red Sea has revealed its capability to withstand the harsh seawater environment. The mechanical flexibility and low thickness and weight of the conductivity cell allow for a less-intrusive attachment of this sensor to marine animals, while the versatile fabrication process enables customization of the sensor to a wide range of applications.
Original languageEnglish (US)
Pages (from-to)100009
JournalResults in Materials
StatePublished - Aug 7 2019

Bibliographical note

KAUST Repository Item: Exported on 2020-10-01
Acknowledgements: Research reported in this publication was supported by the King Abdullah University of Science and Technology and the CAASE project as
part of the KAUST Sensor Initiative. The author would like to thank Ulrich Buttner from the KAUST Microfluidics Core Laboratory for his
technical support.


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