A Study on the Ability of Nanomaterials to Adsorb NO and SO 2 from Combustion Gases and the Effectiveness of Their Separation.
Marius ConstantinescuFelicia BucuraAntoaneta RomanOana Romina BotoranRoxana-Elena IoneteStefan-Ionut SpiridonEusebiu Ilarian IoneteAnca Maria ZaharioiuFlorian MarinSilviu-Laurentiu BadeaVioleta-Carolina NiculescuPublished in: Nanomaterials (Basel, Switzerland) (2024)
Climate neutrality for the year 2050 is the goal assumed at the level of the EU 27+UK . As Romania is no exception, it has assumed the gradual mitigation of pollution generated by the energy sector, and by 2030, according to 'Fit for 55', the share of energy from renewable sources must reach 42.5% from total energy consumption. For the rest of the energy produced from traditional sources, natural gas and/or coal, modern technologies will be used to retain the gaseous noxes. Even if they are not greenhouse gases, NO and SO 2 , generated from fossil fuel combustion, cause negative effects on the environment and biodiversity. The adsorption capacity of different materials, three nanomaterials developed in-house and three commercial adsorbents, both for NO and SO 2 , was tackled through gas chromatography, elemental analysis, and Fourier-transform infrared spectroscopy. Fe-BTC has proven to be an excellent material for separation efficiency and adsorption capacity under studied conditions, and is shown to be versatile both in the case of NO (80.00 cm 3 /g) and SO 2 (63.07 cm 3 /g). All the developed nanomaterials generated superior results in comparison to the commercial adsorbents. The increase in pressure enhanced the performance of the absorption process, while temperature showed an opposite influence, by blocking the active centers on the surface.
Keyphrases
- particulate matter
- gas chromatography
- climate change
- mass spectrometry
- heavy metals
- drinking water
- randomized controlled trial
- aqueous solution
- tandem mass spectrometry
- liquid chromatography
- risk assessment
- municipal solid waste
- systematic review
- air pollution
- room temperature
- solid phase extraction
- water quality
- anaerobic digestion