Innovation in sensor technology: development of a new pH sensing layer successfully integrated into an ISFET

The pH of a solution is the most important parameter in chemical and biochemical analysis. An ISFET with a novel sensor layer developed by Fraunhofer IPMS, in combination with a conventional reference electrode, enables highly precise pH measurement in the range from pH 1 to pH 13. The compact, unbreakable sensor chip with dimensions of 5 x 5 mm² is characterized by a minimal drift of < 20 µV/h as well as low hysteresis while being easy to integrate. A significant improvement has also been achieved in the reduction of light sensitivity.

The dry storage capability of the sensor is one of its primary advantages. Moreover, the electrical operating point of the sensor can be flexibly adjusted via the design and the operating parameters, whereby an operating voltage (VDS) of below 1V is possible.

Dr. Hild, head of the research team, expressed his enthusiasm for the measurement data achieved by the mechanically robust sensor: "With these properties, the new ISFET is particularly suitable for on-site environmental analysis." Dr. Hild went on to emphasize that the next important research goal is to develop a sensor layer that enables a purely chip-based pH measurement that eliminates the need for conventional reference electrodes. This breakthrough technology would then have the potential to continuously collect environmental data over long time periods without the need for intervention by operating personnel.




Physical principles of the ISFET from Fraunhofer IPMS
The novel ISFET from Fraunhofer IPMS is based on metal-oxide-semiconductor (MOS) field-effect transistor technology, whereby the sensor area in contact with the medium consists of an amphoteric metal oxide layer. Hydronium or hydroxide ions from the medium are reversibly adsorbed on this sensing layer, allowing for the pH of the medium to be measured. The gate-to-source voltage (VGS) response versus a reference electrode (Ag/AgCl in 3 M KCl) is then used as the measurement signal.

Some of the research results were achieved in the "REISen" project, a project from the Department of Materials Science, which was co-financed from tax funds on the basis of the budget approved by the Saxon state parliament.

The developments of Fraunhofer IPMS contribute significantly to the further development of environmental analysis and open up new possibilities for more precise and more efficient data acquisition in the field of chemical analysis.

www.ipms.fraunhofer.com