Investigation of chemical components, sources, and dithiothreitol (DTT) based oxidative potential of PM2.5 and its humic-like substances (HULIS) fraction

Ma, Yiqiu

27 August 2020

Air pollution caused by ambient fine particulate matter (PM 2.5 ) is a significant global environmental problem. Pollutants that adhere to PM 2.5 may be transported into human respiratory system and perturb the redox equilibrium through the generation of reactive oxygen species (ROS), thus leading to myriad health effects. This mechanism has been proposed to be related with the high redox-active components in PM 2.5, such as transition metals, quinones, and humic-like substances (HULIS). This thesis aims to improve the scientific understanding on the sources and health impacts of PM 2.5 especially its HULIS fraction. Thus, both chemical characterization and redox activity measurement of ambient PM 2.5 samples were conducted. Positive matrix factorization (PMF) was then performed to apportion the source-specific contributions to PM 2.5 and its oxidative potential. The HULIS fraction of PM 2.5 was also quantified and source apportioned regarding their mass concentration and oxidative potential. The main findings are summarized below: (1) In Chapter 2, 66 PM 2.5 samples collected in Hong Kong during 2016-2017 were analyzed, including carbonaceous components, major ions, metals, and some source markers. The oxidative potential of PM 2.5 were measured using dithiothreitol (DTT) assay. Results showed clear temporal trends for both PM 2.5 mass concentration and its major fraction, with higher levels observed on days under regional pollution than on days under long range transport (LRT) pollution and local emissions. The DTT consumption of PM 2.5 on the contrary, only showed slightly higher activity on regional and LRT days than on local days, possibly due to the comprehensive effects of different sources and species concentrations under different sampling days. We then conducted source apportionment using PMF model. Five primary sources (i.e. marine vessels, Cu-related source, Fe-Mn-Zn-related source, vehicle emissions, biomass burning) and one secondary source were resolved for both PM 2.5 mass concentration and DTT activity. Secondary formation was found to be the most significant source responsible for PM 2.5 mass concentration (30.3%), followed by Cu- related source (24.8%), marine vessels (17.9%) and vehicle emissions (14.5%). Biomass burning (6.8%) and Fe-Mn-Zn-related source (5.8%) were two minor sources contributing to PM 2.5 mass concentration. For oxidative potential of PM 2.5, Cu- related source was the predominant contributor (39.1%). Secondary formation (23.7%) and marine vessels (20.1%) were also two significant sources responsible for the DTT consumption of PM 2.5 . For intrinsic oxidative potential, PM 2.5 emitted from marine vessels and Cu-related source showed highest value, indicating more toxic feature of PM 2.5 derived from those sources regarding DTT activity. (2) In Chapter 3 and 4, the mass concentration, optical properties, and ROS- generation potential of HULIS were investigated in PM 2.5 samples collected in Hong Kong during 2011-2012. They all showed higher levels on regional days than on LRT days and local days. PMF analysis was conducted regarding the mass concentration and ROS activity of HUILS. Six sources were determined, including four primary sources (i.e. marine vessels, vehicle emissions, industrial exhaust, and biomass burning) and two secondary sources (i.e. secondary organic aerosol formation and secondary sulfate). Most sources showed higher contributions to both mass concentrations and DTT activity of HULIS on regional days than on LRT and local days, except that marine vessels had a higher contribution on local days than the other two synoptic conditions. Secondary processes were the major contributor to HULIS (54.9%) throughout the year, followed by biomass burning (27.4%) and industrial exhaust (14.7%). As or the DTT activity of HULIS, biomass burning (62.9%) and secondary processes (25.4%) were found to be the top two contributors. Intrinsic ROS-generation potential of HULIS was also investigated by normalizing the DTT activity by HULIS mass in each source. HULIS from biomass burning were the most DTT-active, followed by marine vessels; while HULIS formed through secondary processes were the least DTT-active. For the optical properties of HULIS, multiple linear regression model was adopted to evaluate the contributions of various sources to the light absorbing ability of HULIS. Biomass burning was found to be the only source significantly associated with the light absorbing property of HULIS. In Chapter 5 and 6, the predominant species of water-soluble fraction of PM 2.5, HULIS, were measured in samples collected in Beijing from 2011 to 2012. Various HULIS species, and the redox activity of HULIS were quantified together with certain source markers of PM 2.5. HULIS and their redox activity showed similar temporal trend, with higher levels measured during the heating season (November to March) than during the non-heating season (April to October). Source apportionment of both HULIS and their redox activity was performed using PMF. Four combustion-related primary sources, namely coal combustion, biomass burning, waste incineration, and vehicle exhaust, and one secondary factor were resolved. In particular, waste incineration was identified as a source of HULIS for the first time. Biomass burning and secondary aerosol formation were the major contributors (>59%) to both HULIS and associated DTT activity throughout the year. During the non-heating season, secondary aerosol formation was the most important source, whereas during the heating season, the predominant contributor was biomass burning. The four combustion-related sources accounted for about 70% of HULIS and their ROS activity, implying that future reduction in PM 2.5 emissions from combustion activities can substantially reduce the HULIS burden and their potential health impact in Beijing.

Air ; Particles ; Air quality management

Investigation of chemical components, sources, and dithiothreitol (DTT) based oxidative potential of PM2.5 and its humic-like substances (HULIS) fraction

Ma, Yiqiu

27 August 2020

Air pollution caused by ambient fine particulate matter (PM 2.5 ) is a significant global environmental problem. Pollutants that adhere to PM 2.5 may be transported into human respiratory system and perturb the redox equilibrium through the generation of reactive oxygen species (ROS), thus leading to myriad health effects. This mechanism has been proposed to be related with the high redox-active components in PM 2.5, such as transition metals, quinones, and humic-like substances (HULIS). This thesis aims to improve the scientific understanding on the sources and health impacts of PM 2.5 especially its HULIS fraction. Thus, both chemical characterization and redox activity measurement of ambient PM 2.5 samples were conducted. Positive matrix factorization (PMF) was then performed to apportion the source-specific contributions to PM 2.5 and its oxidative potential. The HULIS fraction of PM 2.5 was also quantified and source apportioned regarding their mass concentration and oxidative potential. The main findings are summarized below: (1) In Chapter 2, 66 PM 2.5 samples collected in Hong Kong during 2016-2017 were analyzed, including carbonaceous components, major ions, metals, and some source markers. The oxidative potential of PM 2.5 were measured using dithiothreitol (DTT) assay. Results showed clear temporal trends for both PM 2.5 mass concentration and its major fraction, with higher levels observed on days under regional pollution than on days under long range transport (LRT) pollution and local emissions. The DTT consumption of PM 2.5 on the contrary, only showed slightly higher activity on regional and LRT days than on local days, possibly due to the comprehensive effects of different sources and species concentrations under different sampling days. We then conducted source apportionment using PMF model. Five primary sources (i.e. marine vessels, Cu-related source, Fe-Mn-Zn-related source, vehicle emissions, biomass burning) and one secondary source were resolved for both PM 2.5 mass concentration and DTT activity. Secondary formation was found to be the most significant source responsible for PM 2.5 mass concentration (30.3%), followed by Cu- related source (24.8%), marine vessels (17.9%) and vehicle emissions (14.5%). Biomass burning (6.8%) and Fe-Mn-Zn-related source (5.8%) were two minor sources contributing to PM 2.5 mass concentration. For oxidative potential of PM 2.5, Cu- related source was the predominant contributor (39.1%). Secondary formation (23.7%) and marine vessels (20.1%) were also two significant sources responsible for the DTT consumption of PM 2.5 . For intrinsic oxidative potential, PM 2.5 emitted from marine vessels and Cu-related source showed highest value, indicating more toxic feature of PM 2.5 derived from those sources regarding DTT activity. (2) In Chapter 3 and 4, the mass concentration, optical properties, and ROS- generation potential of HULIS were investigated in PM 2.5 samples collected in Hong Kong during 2011-2012. They all showed higher levels on regional days than on LRT days and local days. PMF analysis was conducted regarding the mass concentration and ROS activity of HUILS. Six sources were determined, including four primary sources (i.e. marine vessels, vehicle emissions, industrial exhaust, and biomass burning) and two secondary sources (i.e. secondary organic aerosol formation and secondary sulfate). Most sources showed higher contributions to both mass concentrations and DTT activity of HULIS on regional days than on LRT and local days, except that marine vessels had a higher contribution on local days than the other two synoptic conditions. Secondary processes were the major contributor to HULIS (54.9%) throughout the year, followed by biomass burning (27.4%) and industrial exhaust (14.7%). As or the DTT activity of HULIS, biomass burning (62.9%) and secondary processes (25.4%) were found to be the top two contributors. Intrinsic ROS-generation potential of HULIS was also investigated by normalizing the DTT activity by HULIS mass in each source. HULIS from biomass burning were the most DTT-active, followed by marine vessels; while HULIS formed through secondary processes were the least DTT-active. For the optical properties of HULIS, multiple linear regression model was adopted to evaluate the contributions of various sources to the light absorbing ability of HULIS. Biomass burning was found to be the only source significantly associated with the light absorbing property of HULIS. In Chapter 5 and 6, the predominant species of water-soluble fraction of PM 2.5, HULIS, were measured in samples collected in Beijing from 2011 to 2012. Various HULIS species, and the redox activity of HULIS were quantified together with certain source markers of PM 2.5. HULIS and their redox activity showed similar temporal trend, with higher levels measured during the heating season (November to March) than during the non-heating season (April to October). Source apportionment of both HULIS and their redox activity was performed using PMF. Four combustion-related primary sources, namely coal combustion, biomass burning, waste incineration, and vehicle exhaust, and one secondary factor were resolved. In particular, waste incineration was identified as a source of HULIS for the first time. Biomass burning and secondary aerosol formation were the major contributors (>59%) to both HULIS and associated DTT activity throughout the year. During the non-heating season, secondary aerosol formation was the most important source, whereas during the heating season, the predominant contributor was biomass burning. The four combustion-related sources accounted for about 70% of HULIS and their ROS activity, implying that future reduction in PM 2.5 emissions from combustion activities can substantially reduce the HULIS burden and their potential health impact in Beijing.

Air ; Particles ; Air quality management

Investigating preferences for low emission buses

Loría Rebolledo, Luis Enrique

January 2018

This thesis aims to investigate preferences for Low Emission Buses (LEB). Building on the existing stated preference literature on bus service quality measures and emissions reduction valuation in private vehicles and on the few existing studies looking at LEBs, which have used Contingent Valuation, this study makes use of the multi-attribute nature of Discrete Choice Experiments (DCE) to explore valuations for reductions in two different types of emissions separately, along with other attributes traditionally related to bus travel. This thesis uses a state-of-the-art pivoted experimental design to create reference-dependent choice tasks centred on the respondent's current experience. Choice task realism was additionally sought by using quantitative and qualitative research to inform the experimental and survey design. The survey was conducted at bus stops in the city of Aberdeen during the months of October and November 2016, whilst an existing LEB pilot project was in operation: the Aberdeen Hydrogen Bus Project (AHBP). Choice data is analysed using random parameter logit models to explore preferences for reductions in the two separate emissions and other bus service characteristics. To provide greater insight of the preferences for LEBs, this thesis' additional methodological contributions include using the AHBP as a case study to explore the role of familiarity on preference formation and examining whether choice behaviour is consistent with prospect theory's three main properties: reference dependence, changing marginal sensitivities and preference asymmetry in the form of loss aversion. Policy implications from each of these contribution are discussed.

330

Buses ; Buses ; Air quality management

Inter-pollutant and reactivity-weighted air pollutant emission trading in Texas

Wang, Linlin,

January 1900

Thesis (Ph. D.)--University of Texas at Austin, 2006. / Vita. Includes bibliographical references.

Assessing control strategies for ground level ozone

Sule, Neelesh Vijay.

January 1900

Thesis (Ph.D.)--University of Texas at Arlington, 2009.

Evaluating the air quality impacts of NO[subscript x] emission trading

Nobel, Carolyn Eve.

January 2001

Thesis (Ph. D.)--University of Texas at Austin, 2001. / Vita. Includes bibliographical references. Available also from UMI/Dissertation Abstracts International.

Vehicle classification profiles for interstates and non-interstates in West Virginia to be used for MOBILE6 modeling

Madhavan, Manoj.

January 2004

Thesis (M.S.)--West Virginia University, 2004. / Title from document title page. Document formatted into pages; contains xi, 96 p. : ill. (some col.), map. Includes abstract. Includes bibliographical references (p. 75).

An overview of guidance notes for the management of indoor air quality in offices and public places /

Chu, Kiu-fung, Truman.

January 2001

Thesis (M.A.)--University of Hong Kong, 2001. / Includes bibliographical references.

Breathe the air in Hong Kong air quality sustainability /

Tang, Hing-fai.

January 2002

Thesis (M. Sc.)--University of Hong Kong, 2002. / Includes bibliographical references (leaves 79-84).

Air quality Air Air quality management

Atmospheric reactive nitrogen oxides and their relationship with urban and rural ozone formation by Tao Wang

Wang, Tao

08 1900

No description available.

Air quality management

Ozone

Atmospheric chemistry