![The air pollution caused by the burning of fireworks during the lantern festival in Beijing [An article from: Atmospheric Environment]](https://www.ebooknetworking.net/books/B00/0PC/bigB000PC6NBI.jpg)
The air pollution caused by the burning of fireworks during the lantern festival in Beijing [An article from: Atmospheric Environment]
Book Details
Author(s)Y. Wang, G. Zhuang, C. Xu, Z. An
PublisherElsevier
ISBN / ASINB000PC6NBI
ISBN-13978B000PC6NB4
AvailabilityAvailable for download now
MarketplaceUnited States 🇺🇸
Description
This digital document is a journal article from Atmospheric Environment, published by Elsevier in 2007. The article is delivered in HTML format and is available in your Amazon.com Media Library immediately after purchase. You can view it with any web browser.
Description:
The effects of the burning of fireworks on air quality in Beijing was firstly assessed from the ambient concentrations of various air pollutants (SO"2, NO"2, PM"2"."5, PM"1"0 and chemical components in the particles) during the lantern festival in 2006. Eighteen ions, 20 elements, and black carbon were measured in PM"2"."5 and PM"1"0, and the levels of organic carbon could be well estimated from the concentrations of dicarboxylic acids. Primary components of Ba, K, Sr, Cl^-, Pb, Mg and secondary components of C"5H"6O"4^2^-, C"3H"2O"4^2^-, C"2O"4^2^-, C"4H"4O"4^2^-, SO"4^2^-, NO"3^- were over five times higher in the lantern days than in the normal days. The firework particles were acidic and of inorganic matter mostly with less amounts of secondary components. Primary aerosols from the burning of fireworks were mainly in the fine mode, while secondary formation of acidic anions mainly took place on the coarse particles. Nitrate was mainly formed through homogeneous gas-phase reactions of NO"2, while sulfate was largely from heterogeneous catalytic transformations of SO"2. Fe could catalyze the formation of nitrate through the reaction of @a-Fe"2O"3 with HNO"3, while in the formation of sulfate, Fe is not only the catalyst, but also the oxidant. A simple method using the concentration of potassium and a modified method using the ratio of Mg/Al have been developed to quantify the source contribution of fireworks. It was found that over 90% of the total mineral aerosol and 98% of Pb, 43% of total carbon, 28% of Zn, 8% of NO"3^-, and 3% of SO"4^2^- in PM"2"."5 were from the emissions of fireworks on the lantern night.
Description:
The effects of the burning of fireworks on air quality in Beijing was firstly assessed from the ambient concentrations of various air pollutants (SO"2, NO"2, PM"2"."5, PM"1"0 and chemical components in the particles) during the lantern festival in 2006. Eighteen ions, 20 elements, and black carbon were measured in PM"2"."5 and PM"1"0, and the levels of organic carbon could be well estimated from the concentrations of dicarboxylic acids. Primary components of Ba, K, Sr, Cl^-, Pb, Mg and secondary components of C"5H"6O"4^2^-, C"3H"2O"4^2^-, C"2O"4^2^-, C"4H"4O"4^2^-, SO"4^2^-, NO"3^- were over five times higher in the lantern days than in the normal days. The firework particles were acidic and of inorganic matter mostly with less amounts of secondary components. Primary aerosols from the burning of fireworks were mainly in the fine mode, while secondary formation of acidic anions mainly took place on the coarse particles. Nitrate was mainly formed through homogeneous gas-phase reactions of NO"2, while sulfate was largely from heterogeneous catalytic transformations of SO"2. Fe could catalyze the formation of nitrate through the reaction of @a-Fe"2O"3 with HNO"3, while in the formation of sulfate, Fe is not only the catalyst, but also the oxidant. A simple method using the concentration of potassium and a modified method using the ratio of Mg/Al have been developed to quantify the source contribution of fireworks. It was found that over 90% of the total mineral aerosol and 98% of Pb, 43% of total carbon, 28% of Zn, 8% of NO"3^-, and 3% of SO"4^2^- in PM"2"."5 were from the emissions of fireworks on the lantern night.
