Rhenium-Based Molecular Trap as an Evanescent Wave Infrared Chemical Sensing Medium for the Selective Determination of Amines in Air.

An evanescent wave infrared chemical sensor was developed to selectively detect volatile amines with heterocyclic or phenyl ring. To achieve this goal, a rhenium-based metallacycle with a "molecular-trap" structure was designed and synthesized as host molecules to selectively trap amines with heterocyclic or phenyl ring through Re-amine and π-π interactions. To explore the trapping properties of the material, a synthesized Re-based molecular trap was treated on an IR sensing element, and wide varieties of volatile organic compounds (VOCs) were examined to establish the selectivity for detection of amines.

Gondola-shaped tetra-rhenium metallacycles modified evanescent wave infrared chemical sensors for selective determination of volatile organic compounds.

Water-stable and cavity-contained rhenium metallacycles were synthesized, and their ability to selectively interact with volatile organic compounds (VOCs) systematically studied using attenuated total reflection infrared (ATR-IR) spectroscopy. Integrating the unique properties of rhenium metallacycles into optical sensing technologies significantly improves selectivity in detecting aromatic compounds. To explore the interaction of rhenium metallacycles with VOCs, the surface of ATR sensing elements was modified with the synthesized rhenium metallacycles and used to detect VOCs.

alpha-Cyclodextrin-modified infrared sensing system for rapidly determining the enantiomeric composition of chiral compounds.

This paper describes a new infrared (IR) sensing method for rapidly determining the enantiomeric compositions of chiral compounds through the use of a chirality-selective compound immobilized on the surface of the evanescent-wave sensing elements. alpha-Cyclodextrin (alpha-CD) was selected as this agent and it was immobilized on a zinc selenide sensing element to allow different analytical signals to be generated for each compound of a pair of enantiomers. Theoretical working equations were developed to monitor the response of the ATR-IR spectroscopic sensor during this process.

alpha-Cyclodextrin-modified infrared chemical sensor for selective determination of tyrosine in biological fluids.

In this paper, we propose an evanescent wave-based infrared (IR) spectroscopic sensing method for the selective and sensitive detection of tyrosine in aqueous solution. In this approach, alpha-cyclodextrin (alpha-CTD) was chemically immobilized onto the surface of an IR-sensing element to attract tyrosine specifically to the surface of the sensing element. Theoretical equations were developed for the quantitative analysis of tyrosine.

Development of the infrared hollow waveguide sampler for the detection of chlorophenols in aqueous solutions.

A method based on the infrared hollow waveguide sampler was developed for sensing chlorophenols in aqueous solutions. This sampler was constructed by coating a suitable hydrophobic film onto the inner surface of an infrared hollow waveguide. By passing the aqueous solution through the hollow waveguide sampler, analytes can be absorbed into the hydrophobic layer.