Journal
JOURNAL OF ENVIRONMENTAL CHEMICAL ENGINEERING
Volume 8, Issue 4, Pages -Publisher
ELSEVIER SCI LTD
DOI: 10.1016/j.jece.2020.103986
Keywords
Formaldehyde; Adsorption; Zeolites; Indoor air; Gas analysis; Realistic concentrations
Categories
Funding
- European Union's through the LIFE SMART IN'AIR - Smart indoor air monitoring network to reduce the impacts of pollutants on environment and health [LIFE17 ENV/FR/000330]
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Due to analytical reasons, adsorption capacity is often determined at very high concentrations which is not representative of a real environment. The aim of this work is to provide experimental data of formaldehyde adsorption capacity at realistic levels (similar to 164 ppb) thanks to a near real-time powerful formaldehyde analyser recently developed in our laboratory. Gaseous formaldehyde breakthrough experiments were conducted on a broad spectrum of materials including carbon, zeolites, metal organic framework and mesoporous silica in order to determine their adsorption capacity. Among these materials, HKUST-1 exhibited the highest adsorption capacity (504 mu g/g ads) followed by MgZSM-5 (35 mu g/g ads), SBA-16 (29 mu g/g ads), ZSM-5 (10-26 mu g/g ads) and Carbopack (R) B (4 mu g/g ads). In the case of ZSM-5 zeolites, the results revealed that formaldehyde adsorption was related to their aluminium content. The presence of aluminium implies more bridging hydroxyl groups Si-(OH)-Al that act as Bronsted acid sites interacting with formaldehyde molecules. Despite the moderate adsorption capacity of ZSM-5 zeolites, they can be considered as promising candidates for gas analysis applications, for example where a good analytical blank is essential for accurate measurements.
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