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Author: Yunliang Zhao Publisher: ISBN: Category : Languages : en Pages : 96
Book Description
Understanding organic aerosol (OA) sources and secondary OA (SOA) formation is crucial to elucidate their human health and climate change effects, but has been limited by lack of instrumentation capable of in-situ measurements of organic speciation in the atmosphere across the vapor pressure range of semi-volatile organic compounds (SVOCs) and OA. This dissertation describes 1) the development of a novel instrument based on a thermal desorption aerosol gas chromatograph (TAG), called semi-volatile TAG (SV-TAG) which enables quantitative measurements of specific chemical tracers in SVOCs and OA and 2) application of this new instrument to investigate the various source contributions to OA and SOA formation. The development of the SV-TAG was initiated by employing a denuder difference method to improve the capability of the TAG for quantitative gas/particle separation. Using this technique, hourly time resolution in-situ measurements of organic species were made and then used to investigate the pathways of gas-to-particle partitioning for oxygenated compounds and particle-phase organics were used for source apportionment calculations. The measurements of gas/particle partitioning of phthalic acid, pinonaldehyde and 6, 10, 14-trimethyl-2-pentadecanone were explored to elucidate the pathways of gas-to-particle partitioning whereby SOA was formed. The observations show that multiple pathways of gas-to-particle partitioning contribute to formation of SOA in the atmosphere and the dominance of different pathways are compound-dependent. Absorption into particles is shown to be the dominant pathway for 6, 10, 14-trimethyl-2-pentadecanone to contribute to SOA in Bakersfield, CA. The major pathway to form particle-phase phthalic acid is likely attributed to formation of condensable salts through reactions between phthalic acid and gas-phase ammonia. The observations of pinonaldehyde in particles while inorganic acids in particles were fully neutralized suggest that the occurrence of reactive uptake of pinonaldehyde onto particles does not require the presence of inorganic acids. The relationship between particle-phase pinonaldehyde and RH suggests that aerosol water content plays a significant role in the formation of particle-phase pinonaldehyde. To investigate the contributions of various sources to OA in Bakersfield, CA, positive matrix factorization (PMF) analysis was performed on a subset of the measured particle-phase organic compounds. Six OA source factors were identified, including one representing primary organic aerosol (POA), four different types of secondary organic aerosol (SOA) representing local, regional, and nighttime production, and one representing a complex mixture of additional OA sources that were not further resolvable. POA accounted for 15% of OA on average with a significant contribution from local vehicles. SOA was the dominant contributor to OA, accounting for on average 72% of OA. The rest of OA was unresolved as a mixture of OA sources. Both local and regional SOA had a significant contribution to OA during the day but regional SOA was the largest contributor to OA during the afternoon. SOA formed from the oxidation of biogenic SOA precursors substantially contributed to OA at night. The absorption of organic compounds into particles is suggested to be the major pathway to form SOA, although other pathways also played significant roles. To achieve quantitative collection of SVOCs following improved gas/particle separation, a new collection and thermal desorption system was developed with the key component being a passivated metal fiber filter collector. This final configuration of the SV-TAG enabled in-situ quantitative measurements of speciated SVOCs with vapor pressures lower than n-tetradecane (C14). The capability for measurements of gas/particle partitioning was demonstrated by measurements of n-alkanes in both gas and particle phases. Organic tracers in both gas and particle phases can be quantified. Percentages of speciated organic compounds in total measured organics can be estimated. For example, ~7% and less than 1% of total measured organics in the same retention range of n-alkanes (C14-C20) in the atmosphere in Berkeley, CA were accounted for by the sum of measured n-alkanes (C14-C20) and the sum of n alkylcyclohexanes (C14-C20). The SV-TAG has been demonstrated to enable investigation of the pathways of gas-to-particle partitioning and source apportionment of OA with hourly time resolution. The SV-TAG is also capable of quantitative measurements of speciated SVOCs, defining their gas/particle partitioning in-situ for the first time, and providing observational constraints on the abundance of SVOCs with which to investigate their primary emissions, chemical transformation, and fate.
Author: Yunliang Zhao Publisher: ISBN: Category : Languages : en Pages : 96
Book Description
Understanding organic aerosol (OA) sources and secondary OA (SOA) formation is crucial to elucidate their human health and climate change effects, but has been limited by lack of instrumentation capable of in-situ measurements of organic speciation in the atmosphere across the vapor pressure range of semi-volatile organic compounds (SVOCs) and OA. This dissertation describes 1) the development of a novel instrument based on a thermal desorption aerosol gas chromatograph (TAG), called semi-volatile TAG (SV-TAG) which enables quantitative measurements of specific chemical tracers in SVOCs and OA and 2) application of this new instrument to investigate the various source contributions to OA and SOA formation. The development of the SV-TAG was initiated by employing a denuder difference method to improve the capability of the TAG for quantitative gas/particle separation. Using this technique, hourly time resolution in-situ measurements of organic species were made and then used to investigate the pathways of gas-to-particle partitioning for oxygenated compounds and particle-phase organics were used for source apportionment calculations. The measurements of gas/particle partitioning of phthalic acid, pinonaldehyde and 6, 10, 14-trimethyl-2-pentadecanone were explored to elucidate the pathways of gas-to-particle partitioning whereby SOA was formed. The observations show that multiple pathways of gas-to-particle partitioning contribute to formation of SOA in the atmosphere and the dominance of different pathways are compound-dependent. Absorption into particles is shown to be the dominant pathway for 6, 10, 14-trimethyl-2-pentadecanone to contribute to SOA in Bakersfield, CA. The major pathway to form particle-phase phthalic acid is likely attributed to formation of condensable salts through reactions between phthalic acid and gas-phase ammonia. The observations of pinonaldehyde in particles while inorganic acids in particles were fully neutralized suggest that the occurrence of reactive uptake of pinonaldehyde onto particles does not require the presence of inorganic acids. The relationship between particle-phase pinonaldehyde and RH suggests that aerosol water content plays a significant role in the formation of particle-phase pinonaldehyde. To investigate the contributions of various sources to OA in Bakersfield, CA, positive matrix factorization (PMF) analysis was performed on a subset of the measured particle-phase organic compounds. Six OA source factors were identified, including one representing primary organic aerosol (POA), four different types of secondary organic aerosol (SOA) representing local, regional, and nighttime production, and one representing a complex mixture of additional OA sources that were not further resolvable. POA accounted for 15% of OA on average with a significant contribution from local vehicles. SOA was the dominant contributor to OA, accounting for on average 72% of OA. The rest of OA was unresolved as a mixture of OA sources. Both local and regional SOA had a significant contribution to OA during the day but regional SOA was the largest contributor to OA during the afternoon. SOA formed from the oxidation of biogenic SOA precursors substantially contributed to OA at night. The absorption of organic compounds into particles is suggested to be the major pathway to form SOA, although other pathways also played significant roles. To achieve quantitative collection of SVOCs following improved gas/particle separation, a new collection and thermal desorption system was developed with the key component being a passivated metal fiber filter collector. This final configuration of the SV-TAG enabled in-situ quantitative measurements of speciated SVOCs with vapor pressures lower than n-tetradecane (C14). The capability for measurements of gas/particle partitioning was demonstrated by measurements of n-alkanes in both gas and particle phases. Organic tracers in both gas and particle phases can be quantified. Percentages of speciated organic compounds in total measured organics can be estimated. For example, ~7% and less than 1% of total measured organics in the same retention range of n-alkanes (C14-C20) in the atmosphere in Berkeley, CA were accounted for by the sum of measured n-alkanes (C14-C20) and the sum of n alkylcyclohexanes (C14-C20). The SV-TAG has been demonstrated to enable investigation of the pathways of gas-to-particle partitioning and source apportionment of OA with hourly time resolution. The SV-TAG is also capable of quantitative measurements of speciated SVOCs, defining their gas/particle partitioning in-situ for the first time, and providing observational constraints on the abundance of SVOCs with which to investigate their primary emissions, chemical transformation, and fate.
Author: Ian Colbeck Publisher: John Wiley & Sons ISBN: 1405139196 Category : Science Languages : en Pages : 276
Book Description
Aerosol particles are ubiquitous in the Earth’s atmosphere and are central to many environmental issues such as climate change, stratospheric ozone depletion and air quality. In urban environments, aerosol particles can affect human health through their inhalation. Atmospheric aerosols originate from naturally occurring processes, such as volcanic emissions, sea spray and mineral dust emissions, or from anthropogenic activity such as industry and combustion processes. Aerosols present pathways for reactions, transport, and deposition that would not occur in the gas phase alone. Understanding the ways in which aerosols behave, evolve, and exert these effects requires knowledge of their formation and removal mechanism, transport processes, as well as their physical and chemical characteristics. Motivated by climate change and adverse health effects of traffic-related air pollution, aerosol research has intensified over the past couple of decades, and recent scientific advances offer an improved understanding of the mechanisms and factors controlling the chemistry of atmospheric aerosols. Environmental Chemistry of Aerosols brings together the current state of knowledge of aerosol chemistry, with chapters written by international leaders in the field. It will serve as an authoritative and practical reference for scientists studying the Earth’s atmosphere and as an educational and training resource for both postgraduate students and professional atmospheric scientists.
Author: Yue Zhang Publisher: American Chemical Society ISBN: 0841299293 Category : Science Languages : en Pages : 176
Book Description
The uncertainties in the aerosol effects on radiative forcing limit our knowledge of climate change, presenting us with an important research challenge. Aerosols in Atmospheric Chemistry introduces basic concepts about the characterization, formation, and impacts of ambient aerosol particles as an introduction to graduate students new to the field. Each chapter also provides an up-to-date synopsis of the latest knowledge of aerosol particles in atmospheric chemistry.
Author: Hajime Akimoto Publisher: John Wiley & Sons ISBN: 1119422426 Category : Science Languages : en Pages : 539
Book Description
An important guide that highlights the multiphase chemical processes for students and professionals who want to learn more about aerosol chemistry Atmospheric Multiphase Reaction Chemistry provides the information and knowledge of multiphase chemical processes and offers a review of the fundamentals on gas-liquid equilibrium, gas phase reactions, bulk aqueous phase reactions, and gas-particle interface reactions related to formation of secondary aerosols. The authors—noted experts on the topic—also describe new particle formation, and cloud condensation nuclei activity. In addition, the text includes descriptions of field observations on secondary aerosols and PM2.5. Atmospheric aerosols play a critical role in air quality and climate change. There is growing evidence that the multiphase reactions involving heterogeneous reactions on the air-particle interface and the reactions in the bulk liquid phase of wet aerosol and cloud/fog droplets are important processes forming secondary aerosols in addition to gas-phase oxidation reactions to form low-volatile compounds. Comprehensive in scope, the book offers an understanding of the topic by providing a historical overview of secondary aerosols, the fundamentals of multiphase reactions, gas-phase reactions of volatile organic compounds, aqueous phase and air-particle interface reactions of organic compound. This important text: Provides knowledge on multiphase chemical processes for graduate students and research scientists Includes fundamentals on gas-liquid equilibrium, gas phase reactions, bulk aqueous phase reactions, and gas-particle interface reactions related to formation of secondary aerosols Covers in detail reaction chemistry of secondary organic aerosols Written for students and research scientists in atmospheric chemistry and aerosol science of environmental engineering, Atmospheric Multiphase Reaction Chemistry offers an essential guide to the fundamentals of multiphase chemical processes.
Author: François Dulac Publisher: Springer Nature ISBN: 3030823857 Category : Science Languages : en Pages : 622
Book Description
This two-volume set provides an extensive review of the abundant past and recent literature on the atmospheric chemistry in the Mediterranean region. The books document the experience gained on the atmospheric composition over the Mediterranean basin and close areas after six decades of research, starting from early studies of radioactive aerosol fallouts and intense desert dust events in the 1960s, followed by studies of aerosols collected during oceanographic cruises in the early 1980s, and including subsequent knowledge from various surface monitoring stations, intensive campaigns, satellite climatologies, laboratory studies, as well as chemistry-transport and climate models. Through ten thematic sections, the authors examine the sources and fates of atmospheric pollutants over the Mediterranean basin and what we know about the main impacts of the regional atmospheric chemistry. This overview not only considers the full regional cycle of both aerosol and reactive gases including emissions, transport, transformations, and sinks, but also addresses their major impacts on air quality and health, on the radiative budget and climate, on marine chemistry and biogeochemistry . The volumes are an initiative from the ChArMEx project that has federated many studies on those topics in the 2010-2020decade, and update the scientific knowledge by integrating the ChArMEx and non-ChArMEx literature. The books are contributed by a large pool of well-known authors from the respective fields, mainly from France and Greece, but also from six other Mediterranean and eight non-Mediterranean countries. All Chapters have been peer-reviewed by international scientific experts in the corresponding domains. Volume 2 focuses on emissions and their sources, recent progress on chemical processes, aerosol properties, atmospheric deposition, and the impacts of air pollution on human health, regional climate and ecosystems. Recommendations for future research in these fields are finally proposed. The targeted audience is the academic community working on atmospheric chemistry and its impacts, especially teams having a special interest in the Mediterranean region, which includes many countries and institutes worldwide.
Author: V. Faye McNeill Publisher: Springer ISBN: 3642412157 Category : Science Languages : en Pages : 267
Book Description
Christian George, Barbara D’Anna, Hartmut Herrmann, Christian Weller, Veronica Vaida, D. J. Donaldson, Thorsten Bartels-Rausch, Markus Ammann - Emerging Areas in Atmospheric Photochemistry. Lisa Whalley, Daniel Stone, Dwayne Heard - New Insights into the Tropospheric Oxidation of Isoprene: Combining Field Measurements, Laboratory Studies, Chemical Modelling and Quantum Theory. Neil M. Donahue, Allen L. Robinson, Erica R. Trump, Ilona Riipinen, Jesse H. Kroll - Volatility and Aging of Atmospheric Organic Aerosol. P. A. Ariya, G. Kos, R. Mortazavi, E. D. Hudson, V. Kanthasamy, N. Eltouny, J. Sun, C. Wilde - Bio-Organic Materials in the Atmosphere and Snow: Measurement and Characterization. V. Faye McNeill, Neha Sareen, Allison N. Schwier - Surface-Active Organics in Atmospheric Aerosols.
Author: Rekha Kale Publisher: Scitus Academics LLC ISBN: 9781681171326 Category : Aerosols Languages : en Pages : 0
Book Description
Atmospheric Aerosols is a vital problem in current environmental research due to its importance in atmospheric optics, energetics, radiative transfer studies, chemistry, climate, biology and public health. Aerosols can influence the energy balance of the terrestrial atmosphere, the hydrological cycle, atmospheric dynamics and monsoon circulations. Because of the heterogeneous aerosol field with large spatial and temporal variability and reduction in uncertainties in aerosol quantification is a challenging task in atmospheric sciences. Keeping this in view the present study aims to assess the impact of aerosols on coastal Indian station Visakhapatnam and the adjoining Bay of Bengal. An aerosol is a colloid of fine solid particles or liquid droplets, in air or another gas. Aerosols can be natural or not. Examples of natural aerosols are fog, forest exudates and geyser steam.
Author: Publisher: ISBN: Category : Languages : en Pages : 9
Book Description
The research conducted on this project aimed to improve our understanding of secondary organic aerosol (SOA) formation in the atmosphere, and how the properties of the SOA impact climate through its size, phase state, and optical properties. The goal of this project was to demonstrate that the use of molecular composition information to mechanistically connect source apportionment and climate properties can improve the physical basis for simulation of SOA formation and properties in climate models. The research involved developing and improving methods to provide online measurements of the molecular composition of SOA under atmospherically relevant conditions and to apply this technology to controlled simulation chamber experiments and field measurements. The science we have completed with the methodology will impact the simulation of aerosol particles in climate models.
Author: Yunliang Zhao
Author: Yunliang Zhao
Author: Ian Colbeck
Author: Manuel Dekermenjian
Author: Yue Zhang
Author: Hajime Akimoto
Author: François Dulac
Author: Qi Zhang
Author: V. Faye McNeill
Author: Rekha Kale
Author: