Beyond Karl Fischer Titration: a Monolithic Quantum Cascade Sensor for Monitoring Residual Water Concentration in Solvents

Overview

Journal Lab Chip

Publisher Royal Society of Chemistry

Specialties Biotechnology
Chemistry

Date 2023 Feb 17

PMID 36800171

Authors

Florian Pilat

Benedikt Schwarz

Bettina Baumgartner

Daniela Ristanic

Hermann Detz

Aaron M Andrews

Bernhard Lendl

Gottfried Strasser

Borislav Hinkov

Affiliations

Soon will be listed here.

Abstract

Quality control of liquids is an important part of analytical chemistry. The gold standard for measuring residual water in organic solvents and pharmaceutical applications is Karl Fischer titration. It has a high sensitivity, selectivity and accuracy. The downsides are a time-consuming offline analysis, together with the need for toxic reagents producing waste, and it suffers from poor inter-laboratory reproducibility. In this work, we present a high-performance lab-on-a-chip sensor exploiting mid-IR spectroscopy for liquid sensing. It is operating at 6.1 μm wavelength and is suitable for robust and flexible real-time analysis of the residual water concentration in isopropyl alcohol. This is demonstrated in two experiments. A custom-made 60 μL flow cell is employed to measure only minute amounts of analyte in an inline configuration. In a second approach, the whole sensor is immersed into the analyte to demonstrate sensitive and rapid operation on the millisecond time scale. This is confirmed by the ability for time resolved single water-droplet monitoring, while they are mixed into the liquid sample. We obtain a limit of detection between 120 ppm and 150 ppm with a concentration coverage spanning three orders of magnitude from 1.2 × 10% to 25% for the flow cell and 1.5 × 10% to 19% in the configuration, respectively.

Citing Articles

Mid-infrared Ring Interband Cascade Laser: Operation at the Standard Quantum Limit.

Marschick G, Pelini J, Gabbrielli T, Cappelli F, Weih R, Knotig H ACS Photonics. 2024; 11(2):395-403.

PMID: 38405392 PMC: 10885206. DOI: 10.1021/acsphotonics.3c01159.

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