Bedoukian   RussellIPM   RussellIPM   Piezoelectric Micro-Sprayer


Home
Animal Taxa
Plant Taxa
Semiochemicals
Floral Compounds
Semiochemical Detail
Semiochemicals & Taxa
Synthesis
Control
Invasive spp.
References

Abstract

Guide

Alphascents
Pherobio
InsectScience
E-Econex
Counterpart-Semiochemicals
Print
Email to a Friend
Kindly Donate for The Pherobase

« Previous Abstract"Influence of Temperature, Relative Humidity, and Soil Properties on the Soil-Air Partitioning of Semivolatile Pesticides: Laboratory Measurements and Predictive Models"    Next AbstractLabellar Structure of the Maxillaria splendens Alliance (Orchidaceae: Maxillariinae) Indicates Floral Polyphenols as a Reward for Stingless Bees »

Environ Sci Process Impacts


Title:A measurement and modelling investigation of the indoor air chemistry following cooking activities
Author(s):Davies HL; O'Leary C; Dillon T; Shaw DR; Shaw M; Mehra A; Phillips G; Carslaw N;
Address:"Department of Environment and Geography, University of York, Heslington, York, UK. nicola.carslaw@york.ac.uk. Wolfson Atmospheric Chemistry Laboratories, Department of Chemistry, University of York, Heslington, York, UK. Department of Physical, Mathematical and Engineering Sciences, University of Chester, Chester, UK"
Journal Title:Environ Sci Process Impacts
Year:2023
Volume:20230920
Issue:9
Page Number:1532 - 1548
DOI: 10.1039/d3em00167a
ISSN/ISBN:2050-7895 (Electronic) 2050-7887 (Linking)
Abstract:"Domestic cooking is a source of indoor air pollutants, including volatile organic compounds (VOCs), which can impact on indoor air quality. However, the real-time VOC emissions from cooking are not well characterised, and similarly, the resulting secondary chemistry is poorly understood. Here, selected-ion flow-tube mass spectrometry (SIFT-MS) was used to monitor the real-time VOC emissions during the cooking of a scripted chicken and vegetable stir-fry meal, in a room scale, semi-realistic environment. The VOC emissions were dominated by alcohols (70% of total emission), but also contained a range of aldehydes (14%) and terpenes (5%), largely attributable to the heating of oil and the preparation and heating of spices, respectively. The direct cooking-related VOC emissions were then simulated using the Indoor Chemical Model in Python (INCHEM-Py), to investigate the resulting secondary chemistry. Modelling revealed that VOC concentrations were dominated by direct emissions, with only a small contribution from secondary products, though the secondary species were longer lived than the directly emitted species. Following cooking, hydroxyl radical concentrations reduced by 86%, while organic peroxy radical levels increased by over 700%, later forming secondary organic nitrates, peroxyacylnitrates (PANs) and formaldehyde. Monoterpene emissions were shown to drive the formation of secondary formaldehyde, albeit to produce relatively modest concentrations (average of 60 ppt). Sensitivity analysis of the simulation conditions revealed that increasing the outdoor concentrations of ozone and NOx species (2.9x and 9x, respectively) resulted in the greatest increase in secondary product formation indoors ( approximately 400%, 200% and 600% increase in organic nitrates, PANs and formaldehyde production, respectively). Given the fact that climate change is likely to result in increased ozone concentrations in the future, and that increased window-opening in response to rising temperatures is also likely, higher concentrations of indoor oxidants are likely in homes in the future. This work, therefore, suggests that cooking could be a more important source of secondary pollutants indoors in the future"
Keywords:"*Air Pollution, Indoor Nitrates *Volatile Organic Compounds Cooking Formaldehyde;"
Notes:"MedlineDavies, Helen L O'Leary, Catherine Dillon, Terry Shaw, David R Shaw, Marvin Mehra, Archit Phillips, Gavin Carslaw, Nicola eng England 2023/08/23 Environ Sci Process Impacts. 2023 Sep 20; 25(9):1532-1548. doi: 10.1039/d3em00167a"

 
Back to top
 
Citation: El-Sayed AM 2024. The Pherobase: Database of Pheromones and Semiochemicals. <http://www.pherobase.com>.
© 2003-2024 The Pherobase - Extensive Database of Pheromones and Semiochemicals. Ashraf M. El-Sayed.
Page created on 25-11-2024