Formaldehyde passive sampler using an optical chemical sensor: how to limit the humidity interference.

The behaviour of a new formaldehyde diffusive sampler using an optical chemical sensor with respect to high humidity conditions is examined in controlled atmospheres. Five prototypes of the radial diffusion sampler having the same chemical sensor and different designs were tested. In addition, a set of experiments were performed on the chemical sensor to characterise its efficiency of trapping water vapour in the absence and in the presence of the reactants, Fluoral-P and formaldehyde. Differences in humidity interference between the five diffusive sampler prototypes were studied and discussed. From all the results obtained, it was shown that the prototype LDE1.4 combining a small diffusion slot, a reduced internal volume and a sensor shifted upwards from the diffusion slot provided formaldehyde measurements least affected by humidity up to 80% RH at 20 °C. This new type of diffusive sampler with on-site direct reading is intended to ultimately replace conventional passive samplers with DNPH requiring offset laboratory analyses.

Facile and fast detection of bacteria via the detection of exogenous volatile metabolites released by enzymatic hydrolysis.

A low-cost, innovative and non-invasive colorimetric test, which can be universally used, is proposed to detect pathogenic bacteria via the simple and fast detection of volatile metabolites released by enzymatic hydrolysis. The proof of concept is shown via three sets of experiments studying the release of the p-nitrophenol metabolite in solution in the E. coli cultures containing 4-nitrophenyl-ß-d-glucuronide, the trapping efficiency of the gaseous metabolite by various tailored and functionalized xerogels, and the trapping and detection of gaseous p-nitrophenol released by E. coli bacteria.

Multi-tool formaldehyde measurement in simulated and real atmospheres for indoor air survey and concentration change monitoring.

Formaldehyde is of particular health concern since it is carcinogenic for human and ubiquitous in indoor air where people spend most of their time. Therefore, it is important to have suitable methods and techniques to measure its content in indoor air. In the present work, four different techniques have been tested in the INERIS exposure chamber and in indoor environments in comparison to a standard active method: passive sampling method based on the reaction of 2,4-dinitrophenylhydrazine with formaldehyde, two on-line continuous monitoring systems based on fluorescence and UV measurements and a portable commercialised analyser based on electrochemical titration. Two formaldehyde concentrations, about 10 and 25 µg m(-3) were generated in an exposure chamber under controlled conditions of temperature, relative humidity, and wind speed to simulate real conditions and assess potential influence on passive sampling and continuous systems response. Influence of sampling periods on passive sampling has also been evaluated. The real atmosphere experiments have been performed in four different indoor environments: an office, a furniture shop, a shopping mall, and residential dwellings in which several potential formaldehyde sources linked to household activities have been tested. The analytical and sampling problems associated with each measurement method have been identified and discussed. An overall agreement between each technique has been observed and continuous analyzers allowed for formaldehyde concentrations change monitoring and secondary formation of that pollutant observation.

Optical chemical sensors based on hybrid organic-inorganic sol-gel nanoreactors.

Sol-gel porous materials with tailored or nanostructured cavities have been increasingly used as nanoreactors for the enhancement of reactions between entrapped chemical reactants. The domains of applications issued from these designs and engineering are extremely wide. This tutorial review will focus on one of these domains, in particular on optical chemical sensors, which are the subject of extensive research and development in environment, industry and health.

Exciplexes or ground state complexes of (dibenzoylmethanato)boron difluoride and benzene derivatives? A study of their optical properties revisited via liquid state investigations and structure calculations.

(Dibenzoylmethanato)boron difluoride (DBMBF2) was found to form with benzene (B) and its methylated derivatives (MB) in cyclohexane (cHex) two types of ground state complexes. The first complexes with low stoichiometries 2 : 1, 1 : 1 and 1 : 2 do not fluoresce when they are excited. On the other hand, the ground state complexes with high stoichiometry, DBMBF2-(B)(n) or DBMBF2-(MB)(n) (with n>> 2), exhibit a strong fluorescence in their excited states. These findings differ from the previous results, where the strongly fluorescing complexes have been argued to be the 1 : 1 and 1 : 2 exciplexes, complexes of the singlet excited state of DBMBF2 with one or two B or MB molecules. These differences are discussed in terms of the solute-solute and solute-solvent interactions when DBMBF2 and MB are solutes in cyclohexane or when MB is a co-solvent of cyclohexane in binary mixtures of DBMBF2. We also argue that the use of well-suited analytical methods is important for the determination of the nature of the various complexes. Furthermore, to understand the nature of the interactions between benzene and DBMBF2 molecules, we attempt to predict the sites of interaction between DBMBF2 and benzene molecules by determining theoretically the structure of the 1 : 1 complex.