Your search keyword '"Ming Tung Chuang"' showing total 21 results

1. Effect of flow rate on detection limit of particle size for a steam-based aerosol collector

Author

Ta Chih Hsiao, Ming-Tung Chuang, Po-Kai Chang, Guenter Engling, and Po-Yang Chang

Subjects

Detection limit, Atmospheric Science, Supersaturation, 010504 meteorology & atmospheric sciences, Nuclear engineering, Separator (oil production), 010501 environmental sciences, Particulates, complex mixtures, 01 natural sciences, Volumetric flow rate, Aerosol, Environmental science, Particle size, Chemical composition, 0105 earth and related environmental sciences, General Environmental Science

Abstract

A custom-built steam-based aerosol collector (SBAC) was developed to improve the detection limits in aerosol chemical analysis. The SBAC was coupled with wet chemical analytical instruments to characterize the chemical composition of ambient particulate matter with high-time resolution. The particulate matter was mixed with a jet of steam and formed large droplets because of the supersaturation condition in the cooling chamber. The enlarged droplets were subsequently collected using an inertial aerosol separator and delivered to selected instruments for chemical analysis. Experiments were subsequently conducted to evaluate our custom-built SBAC under various sampling flow rates. In particular, particle growth and particle collection efficiency experiments were conducted, and the SBAC was compared with a filter-based sampler. Sample solutions were collected, extracted, and analyzed to determine the influence of sampling flow rate, particle size, and aerosol chemical concentration on the SBAC's collection efficiency. The SBAC was found to provide data with a higher time resolution, to exhibit an improved detection limit, and to effectively perform aerosol chemical analysis compared with the filter-based samplers, although the effect of flow rate on SBAC performance is complicated and further experiments on this aspect are warranted. This paper contributes to the literature by providing guidelines for designing a SBAC for aerosol chemical analysis.

Published

2019

2. Simulating nitrate formation mechanisms during PM2.5 events in Taiwan and their implications for the controlling direction

Author

Ming-Tung Chuang, Tang-Huang Lin, Wei-Che Lin, Steven Soon-Kai Kong, Joshua S. Fu, Chuan-Yao Lin, Chang-Fu Wu, Chung Te Lee, and Charles C.-K. Chou

Subjects

Atmospheric Science, Daytime, Sunset, Atmospheric sciences, Aerosol, chemistry.chemical_compound, Nitrate, chemistry, Environmental science, Water content, NOx, General Environmental Science, CMAQ, Morning

Abstract

The long-term downward trend of NOX concentrations does not reflect the reduction of nitrate (NO3−) in Taiwan. Instead, the proportion of NO3− in PM2.5 increased in recent years. To probe the increasing importance of NO3− in PM2.5, this study applied the WRF/CMAQ modeling system to implement a simulation from 16 March 2017 to 30 April 2017, in which 5 p.m.2.5 events with daily average concentrations ≥35 μg m−3 and their corresponding correlation coefficients (R) of simulated and observed PM2.5 above 0.6 were selected for analysis. During the daytime, the reaction of NO2 and OH contributed more than 90% of the total HNO3. After sunset, the high concentrations of NO3 and N2O5 peaked, followed soon by the simultaneous rise of NO3−, aerosol water content, and HNO3 concentrations around midnight, which indicated that the heterogeneous reaction was the main formation mechanism of NO3−, accounting for approximately 30%–90% of total HNO3. At nighttime, the daytime-formed gaseous phase NO3− condensed, and low wind and low boundary layer height favored accumulation; therefore, PM2.5 peaked around the midnight period to the early morning. The sensitivity test showed that doubling and halving the NOX and NH3 emissions could directly lead to the highest production and reduction of NO3−, respectively, followed by doubling and halving NMHC emissions, which caused the highest and lowest O3 concentrations. The correlation analysis of the simulation results showed that the daytime maximum O3 and HNO3 were highly correlated. The relationships between daytime maximum O3, nighttime maximum NO3, N2O5, and HNO3 in pairs were also moderately to highly correlated. This study implies that in addition to direct reduction of NOX or NH3 emissions, controlling O3 is possibly another useful strategy to reduce NO3−. Because NOX emission reduction could conflict with controlling O3, this study suggests to re-examine the determination of NOX-limited and VOCS-limited regions in order to develop strategies for reducing NOX emission and O3 simultaneously.

Published

2022

3. Real-time measurements of PM2.5 water-soluble inorganic ions at a high-altitude mountain site in the western North Pacific: Impact of upslope wind and long-range transported biomass-burning smoke

Author

Wei Ren Chen, Chung Te Lee, Atinderpal Singh, Shuenn Chin Chang, Chiu Hua Huang, Neng Huei Lin, Shih-Yu Chang, Charles C.-K. Chou, Shantanu Kumar Pani, and Ming Tung Chuang

Subjects

Smoke, Atmospheric Science, Altitude, Local time, Environmental science, Particulates, Inorganic ions, Absorption (electromagnetic radiation), Atmospheric sciences, Sea level, Aerosol

Abstract

Real-time measurement of PM2.5 (particulate matter with aerodynamic diameter ≤ 2.5 μm) water-soluble inorganic ions (WSIIs) was conducted at Lulin Atmospheric Background Station (LABS; 2862 m above mean sea level) in the western North Pacific (WNP) during the autumn 2015 and spring 2016. During autumn, the mountain-valley (M-V) circulation is effective in increasing the mass concentrations of PM2.5, WSIIs, and carbon monoxide (CO) at LABS from 12:00 to 18:00 local time every day. In sharp contrast to autumn, five high aerosol-loading events were recorded during the spring, with each event persisting for a few days. These events were harmonized with the long-range transport of biomass-burning (BB) smoke emissions from northern peninsular Southeast Asia (PSEA), as disclosed from the fire count map and backward trajectories. The plumes appear to mask their characteristic diurnal features driven by the local M-V circulation. During both seasons, the prominent pathway of SO2 to SO42− conversion was aqueous phase oxidation as revealed from the relationship between sulfur oxidation ratio (SOR) and aerosol liquid-water content. Furthermore, NO3− was found to be produced primarily via homogeneous reactions during the spring season. The optical measurements were also made along with the semi-continuous measurements of WSIIs in this study. The magnitude of aerosol scattering and absorption coefficients exhibited high values when LABS was either under the influence of M-V circulation or long-range BB transport, although the latter event was apparently greater. Large surface cooling (up to −30.8 W m−2) and atmospheric warming (up to +21.3 W m−2) at LABS attributed to absorption enhancement by BB-induced aerosols can potentially influence the regional radiation budget.

Published

2021

4. Long-term (2003-2018) trends in aerosol chemical components at a high-altitude background station in the western North Pacific: Impact of long-range transport from continental Asia

Author

Kai Hsien Chi, Charles C.-K. Chou, Ming Tung Chuang, Shih-Yu Chang, Atinderpal Singh, Shantanu Kumar Pani, Chung Te Lee, Chiu Hua Huang, Shuenn Chin Chang, and Neng Huei Lin

Subjects

Asia, 010504 meteorology & atmospheric sciences, Health, Toxicology and Mutagenesis, Taiwan, 010501 environmental sciences, Toxicology, Atmospheric sciences, 01 natural sciences, chemistry.chemical_compound, Altitude, Air mass, Sea level, 0105 earth and related environmental sciences, Total organic carbon, Smoke, Aerosols, Air Pollutants, Levoglucosan, General Medicine, Particulates, Pollution, Aerosol, chemistry, Environmental science, Particulate Matter, Seasons, Environmental Monitoring

Abstract

This study examined the long-term trends in chemical components in PM2.5 (particulate matter with aerodynamic diameter ≤2.5 μm) samples collected at Lulin Atmospheric Background Station (LABS) located on the summit of Mt. Lulin (2862 m above mean sea level) in Taiwan in the western North Pacific during 2003–2018. High ambient concentrations of PM2.5 and its chemical components were observed during March and April every year. This enhancement was primarily associated with the long-range transport of biomass burning (BB) smoke emissions from Indochina, as revealed from cluster analysis of backward air mass trajectories. The decreasing trends in ambient concentrations of organic carbon (−0.67% yr−1; p = 0.01), elemental carbon (−0.48% yr−1; p = 0.18), and non–sea-salt (nss) K+ (−0.71% yr−1; p = 0.04) during 2003–2018 indicated a declining effect of transported BB aerosol over the western North Pacific. These findings were supported by the decreasing trend in levoglucosan (−0.26% yr−1; p = 0.20) during the period affected by the long-range transport of BB aerosol. However, NO3− displayed an increasing trend (0.71% yr−1; p = 0.003) with considerable enhancement resulting from the air masses transported from the Asian continent. Given that the decreasing trends were for the majority of the chemical components, the columnar aerosol optical depth (AOD) also demonstrated a decreasing trend (−1.04% yr−1; p = 0.0001) during 2006–2018. Overall decreasing trends in ambient (carbonaceous aerosol and nss-K+) as well as columnar (e.g., AOD) aerosol loadings at the LABS may influence the regional climate, which warrants further investigations. This study provides an improved understanding of the long-term trends in PM2.5 chemical components over the western North Pacific, and the results would be highly useful in model simulations for evaluating the effects of BB transport on an area.

Published

2019

5. Sensitivity analysis of the dust emission treatment in CMAQv5.2.1 and its application to long-range transport over East Asia

Author

Maggie Chel Gee Ooi, Neng Huei Lin, Stephen M. Griffith, Wei Syun Huang, Ming Tung Chuang, Shantanu Kumar Pani, Xinyi Dong, Steven Soon-Kai Kong, and Joshua S. Fu

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, 010501 environmental sciences, Atmospheric sciences, 01 natural sciences, Wind speed, Plume, Aerosol, Deposition (aerosol physics), Environmental science, Outflow, Precipitation, Air quality index, 0105 earth and related environmental sciences, General Environmental Science, CMAQ

Abstract

East Asian Dust (EAD) has had a measurable impact on global climate and air quality, including visibility and human health, in numerous locations around the globe over the past decade. The accuracy of an air quality modeling system to simulate dust events is vital for early warning systems. The most significant dust event observed in 6 years for northern Taiwan occurred during 4th–9th April 2018, and was characterized by high wind speeds (9–13 m s−1) upon arrival to the region. We assessed the windblown dust emission treatment across various modifications and found better model performance by decreasing the soil moisture factor and updating the aerosol speciation profile over East Asia. In the optimized CMAQ simulation, uplifted dust particles reached a maximum height of 500–700 hPa, which is crucial for effective transport of the dust plume to the downwind Taiwan region. However, by tracking the vertical distribution profile, we found the model was insufficient to estimate dust aerosol after exiting from over the continent and entering the marine boundary layer. Our simulation indicated the dust event consisted of two plumes, where the first one was significantly impacted by wet deposition (−70.65%) from a rainfall belt stretching across Japan, Korea and the East China Sea. Then, low wind speed during a period of no precipitation over the marine area led to even greater dust deposition (−89.11%) from the second plume, resulting in a consistent negative bias for the simulation. This modeling study highlights the importance of improving the dust emission treatment for a better simulation of dust aerosol transport over the marine boundary layer. To reduce the uncertainty in the dust outflow region, the deposition mechanisms for the CMAQ dust treatment should be revised.

Published

2021

6. Aerosol optical properties at the Lulin Atmospheric Background Station in Taiwan and the influences of long-range transport of air pollutants

Author

Peter Pantina, Ta Chih Hsiao, Chung Te Lee, Sheng Hsiang Wang, Wei-Nai Chen, Ming Tung Chuang, Tang Huang Lin, Wei Cheng Ye, Si Chee Tsay, and Neng Huei Lin

Subjects

Physics, Atmospheric Science, Angstrom exponent, 010504 meteorology & atmospheric sciences, Single-scattering albedo, Scattering, 010501 environmental sciences, Molar absorptivity, Air mass (solar energy), Atmospheric sciences, 01 natural sciences, Omega, Aerosol, Climatology, HYSPLIT, 0105 earth and related environmental sciences, General Environmental Science

Abstract

The Lulin Atmospheric Background Station (LABS, 23.47 deg. N 120.87 deg. E, 2862 m ASL) in Central Taiwan was constructed in 2006 and is the only high-altitude background station in the western Pacific region for studying the influence of continental outflow. In this study, extensive optical properties of aerosols, including the aerosol light scattering coefficient [Sigma(sub s)] and light absorption coefficient [Sigma(sub a)], were collected from 2013 to 2014. The intensive optical properties, including mass scattering efficiency [Sigma(sub s)], mass absorption efficiency [Sigma(sub a)] single scattering albedo (Omega), scattering Angstrom exponent (A), and backscattering fraction (b), were determined and investigated, and the distinct seasonal cycle was observed. The value of [Alpha(sub a)] began to increase in January and reached a maximum in April; the mean in spring was 5.89 m(exp. 2) g(exp. -1) with a standard deviation (SD) of 4.54 m(exp. 2) g(exp. -1) and a 4.48 m(exp. 2) g(exp. -1) interquartile range (IQR: 2.95-7.43 m(exp. 2) g(exp. -1). The trend was similar in [Sigma(sub a)], with a maximum in March and a monthly mean of 0.84 m(exp. 2) g(exp. -1). The peak values of Omega (Mean = 0.92, SD = 0.03, IQR: 0.90 - 0.93) and A (Mean = 2.22, SD = 0.61, IQR: 2.12 = 2.47) occurred in autumn. These annual patterns of optical properties were associated with different long-range transport patterns of air pollutants such as biomass burning (BB) aerosol in spring and potential anthropogenic emissions in autumn. The optical measurements performed at LABS during spring in 2013 were compared with those simultaneously performed at the Doi Ang Kang Meteorology Station, Chiang Mai Province, Thailand (DAK, 19.93 deg. N, 99.05 deg. E, 1536 m a.s.l.), which is located in the Southeast Asia BB source region. Furthermore, the relationships among [Sigma(sub s)], [Sigma(sub a)], and (b) were used to characterize the potential aerosol types transported to LABS during different seasons, and the data were inspected according to the HYSPLIT 5-day backward trajectories, which differentiate between different regions of air mass origin.

Published

2017

7. Aerosol transport from Chiang Mai, Thailand to Mt. Lulin, Taiwan – Implication of aerosol aging during long-range transport

Author

Guey Rong Sheu, You Jia Chang, Chung Te Lee, Charles C.-K. Chou, Ming Tung Chuang, Khajornsak Sopajaree, Neng Huei Lin, Shih-Yu Chang, Shuenn Chin Chang, Guo Jun Hong, and Guenter Engling

Subjects

Total organic carbon, Hydrology, Atmospheric Science, Chiang mai, 010504 meteorology & atmospheric sciences, Modification factor, 010501 environmental sciences, Inorganic ions, 01 natural sciences, Southeast asia, Aerosol, Environmental chemistry, Environmental science, Aerosol composition, Biomass burning, 0105 earth and related environmental sciences, General Environmental Science

Abstract

The transport of biomass burning (BB) aerosol from Indochina may cause a potential effect on climate change in Southeast Asia, East Asia, and the Western Pacific. Up to now, the understanding of BB aerosol composition modification during long-range transport (LRT) is still very limited due to the lack of observational data. In this study, atmospheric aerosols were collected at the Suthep/Doi Ang Khang (DAK) mountain sites in Chiang Mai, Thailand and the Lulin Atmospheric Background Station (Mt. Lulin) in central Taiwan from March to April 2010 and from February to April 2013, respectively. During the study period, an upwind and downwind relationship between the Suthep/DAK and Lulin sites (2400 km apart) was validated by backward trajectories. Comprehensive aerosol properties were resolved for PM 2.5 water-soluble inorganic ions, carbonaceous content, water-soluble/insoluble organic carbon (WSOC/WIOC), dicarboxylic acids and their salts (DCAS), and anhydrosugars. A Modification Factor (MF) is proposed by employing non-sea-salt potassium ion (nss-K + ) or fractionalized elemental carbon evolved at 580 °C after pyrolized OC correction (EC1-OP) as a BB aerosol tracer to evaluate the mass fraction changes of aerosol components from source to receptor regions during LRT. The MF values of nss-SO 4 2− , NH 4 + , NO 3 − , OC1 (fractionalized organic carbon evolved from room temperature to 140 °C), OP (pyrolized OC fraction), DCAS, and WSOC were above unity, which indicated that these aerosol components were enhanced during LRT as compared with those in the near-source region. In contrast, the MF values of anhydrosugars ranged from 0.1 to 0.3, indicating anhydrosugars have degraded during LRT.

Published

2016

8. Assessment of aerosol optical property and radiative effect for the layer decoupling cases over the northern South China Sea during the 7‐SEAS/Dongsha Experiment

Author

Simone Lolli, Ming Tung Chuang, Jin-Yi Yu, Chung Te Lee, Sheng Hsiang Wang, Si Chee Tsay, Somporn Chantara, Shantanu Kumar Pani, and Neng Huei Lin

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, Atmospheric circulation, respiratory system, 010501 environmental sciences, Atmospheric sciences, complex mixtures, 01 natural sciences, Aerosol, Wavelength, Geophysics, Atmospheric radiative transfer codes, Space and Planetary Science, Climatology, Earth and Planetary Sciences (miscellaneous), Atmospheric instability, Radiative transfer, Environmental science, Water cycle, Sea salt aerosol, 0105 earth and related environmental sciences

Abstract

The aerosol radiative effect can be modulated by the vertical distribution and optical properties of aerosols, particularly when aerosol layers are decoupled. Direct aerosol radiative effects over the northern South China Sea (SCS) were assessed by incorporating an observed data set of aerosol optical properties obtained from the Seven South East Asian Studies (7-SEAS)/Dongsha Experiment into a radiative transfer model. Aerosol optical properties for a two-layer structure of aerosol transport were estimated. In the radiative transfer calculations, aerosol variability (i.e., diversity of source region, aerosol type, and vertical distribution) for the complex aerosol environment was also carefully quantified. The column-integrated aerosol optical depth (AOD) at 500nm was 0.1-0.3 for near-surface aerosols and increased 1-5 times in presence of upper layer biomass-burning aerosols. A case study showed the strong aerosol absorption (single-scattering albedo (omega) approx. = 0.92 at 440nm wavelength) exhibited by the upper layer when associated with predominantly biomass-burning aerosols, and the omega (approx. = 0.95) of near-surface aerosols was greater than that of the upper layer aerosols because of the presence of mixed type aerosols. The presence of upper level aerosol transport could enhance the radiative efficiency at the surface (i.e., cooling) and lower atmosphere (i.e., heating) by up to -13.7 and +9.6W/sq m2 per AOD, respectively. Such enhancement could potentially modify atmospheric stability, can influence atmospheric circulation, as well as the hydrological cycle over the tropical and low-latitude marginal northern SCS.

Published

2016

9. Enhanced Receptor Modeling Using Expanded Equations with Parametric Variables for Secondary Components of PM2.5

Author

Ping-Wen Tsai, Chang-Fu Wu, Ming-Tung Chuang, Ho-Tang Liao, and Charles C.-K. Chou

Subjects

chemistry.chemical_classification, Condensation, Air pollution, Coal combustion products, medicine.disease_cause, Atmospheric sciences, Combustion, complex mixtures, Pollution, Aerosol, chemistry, medicine, Environmental Chemistry, Environmental science, Organic matter, Biomass burning, Parametric statistics

Abstract

Receptor modeling provides valuable information to help develop effective control strategies. Additionally, incorporating parametric variables into expanded receptor modeling improves the understanding of formation mechanisms and potential sources of secondary aerosol. This study was conducted in a rural township in central Taiwan, where the air pollution level was comparable with that in the urban area. Bihourly measurements were applied into an enhanced receptor modeling approach using positive matrix factorization (PMF). Eight potential sources, including oil combustion, coal combustion, secondary aerosol related, nitrate‐rich secondary aerosol, biomass burning, industry/vehicle, road dust, and SOM‐rich (dominated by secondary organic matter) secondary aerosol, were identified. SOM‐rich secondary aerosol (24%) contributed the most to PM2.5 mass, followed by biomass burning (19%) and nitrate‐rich secondary aerosol (18%). Contributions from three factors involving secondary formation features accounted for 55% of PM2.5 mass. Through the enhanced modeling approach, photo-oxidation formation, condensation and aqueous phase oxidation of volatile organic compounds, and transport of secondary nitrates from upwind urban area could be potential formation process and sources of secondary aerosol.

Published

2021

10. Potential Approach for Single-Peak Extinction Fitting of Aerosol Profiles Based on In Situ Measurements for the Improvement of Surface PM2.5 Retrieval from Satellite AOD Product

Author

Ta Chih Hsiao, Kuo-En Chang, Ming Tung Chuang, Tang Huang Lin, Hung Yi Yeh, Neng Huei Lin, and Hai Po Chan

Subjects

PM2.5, single-peak aerosol extinction profile, log-normal distribution, Micro Pulse LiDAR, aerosol optical depth, planetary boundary layer height, Mode, surface layer height, 010504 meteorology & atmospheric sciences, Correlation coefficient, Planetary boundary layer, Science, 010501 environmental sciences, 01 natural sciences, Standard deviation, Aerosol, Extinction (optical mineralogy), Log-normal distribution, General Earth and Planetary Sciences, Environmental science, Satellite, Surface layer, Physics::Atmospheric and Oceanic Physics, 0105 earth and related environmental sciences, Remote sensing

Abstract

The vertical distribution of aerosols is important for accurate surface PM2.5 retrieval and initial modeling forecasts of air pollution, but the observation of aerosol profiles on the regional scale is usually limited. Therefore, in this study, an approach to aerosol extinction profile fitting is proposed to improve surface PM2.5 retrieval from satellite observations. Owing to the high similarity of the single-peak extinction profile in the distribution pattern, the log-normal distribution is explored for the fitting model based on a decadal dataset (3248 in total) from Micro Pulse LiDAR (MPL) measurements. The logarithmic mean, standard deviation, and the height of peak extinction near-surface (Mode) are manually derived as the references for model construction. Considering the seasonal impacts on the planetary boundary layer height (PBLH), Mode, and the height of the surface layer, the extinction profile is then constructed in terms of the planetary boundary layer height (PBLH) and the total column aerosol optical depth (AOD). A comparison between fitted profiles and in situ measurements showed a high level of consistency in terms of the correlation coefficient (0.8973) and root-mean-square error (0.0415). The satellite AOD is subsequently applied for three-dimensional aerosol extinction, and the good agreement of the extinction coefficient with the PM2.5 within the surface layer indicates the good performance of the proposed fitting approach and the potential of satellite observations for providing accurate PM2.5 data on a regional scale.

Published

2020

11. Radiative Effect of Springtime Biomass-Burning Aerosols over Northern Indochina during 7-SEAS/BASELInE 2013 Campaign

Author

Somporn Chantara, Sheng Hsiang Wang, Si Chee Tsay, Chung Te Lee, Brent N. Holben, Neng Huei Lin, Ta Chih Hsiao, Shantanu Kumar Pani, Serm Janjai, and Ming Tung Chuang

Subjects

food.ingredient, 010504 meteorology & atmospheric sciences, Single-scattering albedo, Planetary boundary layer, Sea salt, 010501 environmental sciences, Mineral dust, Atmospheric sciences, 01 natural sciences, Pollution, Aerosol, Atmosphere, food, Atmospheric radiative transfer codes, Climatology, Radiative transfer, Environmental Chemistry, Environmental science, 0105 earth and related environmental sciences

Abstract

The direct aerosol radiative effects of biomass-burning (BB) aerosols over northern Indochina were estimated by using aerosol properties (physical, chemical, and optical) along with the vertical profile measurements from ground-based measurements with integration of an optical and a radiative transfer model during the Seven South East Asian Studies Biomass-Burning Aerosols Stratocumulus Environment: Lifecycles Interactions Experiment (7-SEASBASELInE) conducted in spring 2013. Cluster analysis of backward trajectories showed the air masses arriving at mountainous background site (Doi Ang Khang; 19.93degN, 99.05degE, 1536 m above mean sea level) in northern Indochina, mainly from near-source inland BB activities and being confined in the planetary boundary layer. The PM(sub10) and black carbon (BC)mass were 87 +/- 28 and 7 +/- 2 micrograms m(exp -3), respectively. The aerosol optical depth (AOD (sub 500) was found to be 0.26--1.13 (0.71 +/- 0.24). Finer (fine mode fraction is approximately or equal to 0.95, angstrom-exponent at 440-870 nm is approximately or equal to 1.77) and significantly absorbing aerosols(single scattering albedo is approximately or equal to 0.89, asymmetry-parameter is approximately or equal to 0.67, and absorption AOD 0.1 at 440 nm) dominated over this region. BB aerosols (water soluble and BC) were the main contributor to the aerosol radiative forcing (ARF), while others (water insoluble, sea salt and mineral dust) were negligible mainly due to their low extinction efficiency. BC contributed only 6 to the surface aerosol mass but its contribution to AOD was 12 (2 times higher). The overall mean ARF was 8.0 and -31.4 W m(exp -2) at top-of-atmosphere (TOA) and at the surface (SFC), respectively. Likely, ARF due to BC was +10.7 and -18.1 W m(exp -2) at TOA and SFC, respectively. BC imposed the heating rate of +1.4 K d(exp -1) within the atmosphere and highlighting its pivotal role in modifying the radiation budget. We propose that to upgrade our knowledge on BB aerosol radiative effects in BB source region, the long-term and extensive field measurements are needed.

Published

2016

12. Comprehensive PM2.5 Organic Molecular Composition and Stable Carbon Isotope Ratios at Sonla, Vietnam: Fingerprint of Biomass Burning Components

Author

Shao An Sun, Guenter Engling, Kai Hsien Chi, Kaori Ono, Shuenn Chin Chang, Ming Tung Chuang, Neng Huei Lin, Ta Chih Hsiao, Dac Loc Nguyen, Guey Rong Sheu, Chung Te Lee, Shidharth Sankar Ram, Chang Feng Ou Yang, and Kimitaka Kawamura

Subjects

Wax, 010504 meteorology & atmospheric sciences, Chemistry, Levoglucosan, chemistry.chemical_element, 010501 environmental sciences, Diethyl phthalate, 01 natural sciences, Pollution, Aerosol, chemistry.chemical_compound, Isotopes of carbon, visual_art, Environmental chemistry, Botany, visual_art.visual_art_medium, Hardwood, Environmental Chemistry, Sugar, Carbon, 0105 earth and related environmental sciences

Abstract

This study presents measurements of aerosol chemical properties at Sonla, northern Vietnam (675 m a.s.l.) during spring time, when biomass burning (BB) was very active in the northern Indochina Peninsula, as part of the 7-SEAS (Seven South East Asian Studies) campaign in 2013. The gas chromatography-mass spectrometry (GC-MS) analysis of BB markers in 14 selected samples indicated that mixed softwood, hardwood, grass, and non-woody vegetation were burned. More than 50 organic compounds including levoglucosan, lignin and resin products, sugar and sugar alcohol compounds, fatty acids, phthalate esters, aromatic acids, poly-acids, and biogenic oxidation products (e.g., 2-methyltetrols, alkene triols, 3-hydroxyglutaric acid) were measured in PM_(2.5). Levoglucosan, a BB tracer, was the predominant species among aerosol sugars, with an average concentration of 1.62 ± 0.89 μg m^(-3), comprising 2.23 ± 0.5% of PM_(2.5) mass. For the collection period of the selected samples, backward air mass trajectories were classified into the source regions of Indochina (BBIC), southern China (BBSC), and the South China Sea (BBSS). All resolved molecular compounds show their dominance on the trajectory from BBIC, verifying the BB smoke origin of that region. Trajectory classification provides additional information, such as higher level of diethyl phthalate associated with BBSC trajectory, revealing urban or industrial influence, and more low-molecular-weight than high-molecular-weight fatty acids, indicating distributions with more microbial and lesser plant wax/vegetation burning contributions along the BBSC trajectory. In addition, we report, for the first time, stable carbon isotopic data (δ^(13)C) for PM_(2.5) aerosols in northern Vietnam, which ranged from -26.6 to -25.4 per mille in PM_(2.5), indicating contributions from burning of C_3 plants and fossil fuel combustion.

Published

2016

13. The Simulation of Long-Range Transport of Biomass Burning Plume and Short-Range Transport of Anthropogenic Pollutants to a Mountain Observatory in East Asia during the 7-SEAS/2010 Dongsha Experiment

Author

Guey Rong Sheu, Yang Gao, Ming Tung Chuang, Chung Te Lee, Ta Chih Hsiao, Ming Cheng Yen, Sheng Hsiang Wang, Narisara Thongboonchoo, Neng Huei Lin, Joshua S. Fu, Jia Lin Wang, and Tang Huang Lin

Subjects

Pollutant, 010504 meteorology & atmospheric sciences, Subsidence (atmosphere), 010501 environmental sciences, Atmospheric sciences, Fluid parcel, 01 natural sciences, Pollution, Aerosol, Plume, Anticyclone, Environmental Chemistry, Environmental science, Air quality index, 0105 earth and related environmental sciences, CMAQ

Abstract

The Community Multi-scale Air Quality Model (CMAQ) is used to simulate the long-range transport of biomass burning (BB) pollutants from Southeast Asia (SEA) towards the Taiwan Central Mountain Range (CMR) in March and April 2010. The results show that a proportion of the BB plume was blocked and compressed at the windward side of CMR. High-altitude BB plume is shown to influence air quality on the ground via three mechanisms: (1) the subsidence in the anticyclone, (2) the downward motion in the cold surge, and (3) the vertical mixing of the boundary layer over land. Two case studies are further investigated to probe the chemical evolution of the air parcel approaching Mt. Lulin. The first case shows that the third mechanism also explained the increase in the concentrations of peroxyacyl nitrate (PAN), higher peroxyacyl nitrate (PANX), NH3, SO2, and volatile organic compounds in the BB plume when entering the land over western Taiwan. Meanwhile, the percentage of NO3– in the plume is also significantly increased. The second case reveals that valley wind transported air pollutants from the ground to the mountains. The air parcel, accompanied with considerable concentrations of PAN, PANX, SULF, and anthropogenic secondary organic aerosol, moved up Mt. Lulin. The pollutant concentrations, except for elemental carbon, in the air parcel decreased on approach to Mt. Lulin because the air parcel was mixed with a clean air.

Published

2016

14. Simulating the transport and chemical evolution of biomass burning pollutants originating from Southeast Asia during 7-SEAS/2010 Dongsha experiment

Author

Ta Chih Hsiao, Ming Cheng Yen, Joshua S. Fu, Chung Te Lee, Jia Lin Wang, Ming Tung Chuang, Wei Chen Chen, Guey Rong Sheu, Narisara Thongboonchoo, Neng Huei Lin, Sheng Hsiang Wang, Yang Gao, and Tang Huang Lin

Subjects

Pollutant, Hydrology, chemistry.chemical_classification, Atmospheric Science, Atmospheric sciences, Aerosol, Plume, Atmosphere, chemistry.chemical_compound, chemistry, Nitrate, Anticyclone, Environmental science, Organic matter, Sulfate, General Environmental Science

Abstract

This study aimed to simulate the transport of biomass burning (BB) aerosol originating from Southeast Asia (SEA) during the Dongsha Experiment conducted from March 2010 to April 2010. Transport pathways were reanalyzed and steering flow in the mid-latitude areas and anticyclones in low-latitude areas were found to control the transport of BB plume after it was injected to a high atmosphere. For the 12 simulated and observed events at Mt. Lulin (2862 m MSL; 23°28′07″ N, 120°52′25″ E), the 72 h backward trajectories were all tracked back to southern China and northern Indochina, which were the locations of the largest BB fire activities in SEA. Chemical evolutions of BB pollutants along the moving trajectories showed that organic matter was always the dominant component in PM2.5, consistent with the observations at both near-source regions and Mt. Lulin. For nitrogen species, nearly all NOx molecules oxidized into HNO3, NO3−, PAN, and PANX in fires or near fires. The synchronic consumption of NOx, SO2, and NH3 explained the production of the major components of inorganic salts. In the moving BB plume, sulfate concentration increased with decreased nitrate concentration. Ratios of ammonium to PM2.5 and elemental carbon to PM2.5 remained nearly constant because additional sources were lacking.

Published

2015

15. Carbonaceous aerosols in the air masses transported from Indochina to Taiwan: Long-term observation at Mt. Lulin

Author

Charles C.-K. Chou, Shuenn Chin Chang, Kai Hsien Chi, Yu Jia Chang, Guo Hau Weng, Horng Wen Chen, Guey Rong Sheu, Sheng Hsiang Wang, Ming Tung Chuang, Chung Te Lee, Chea Yuan Young, Jia Hon Chang, Neng Huei Lin, Shao Peng Hsu, Sin Yu Lai, Hill Huang, Xyue Chang Wu, and Jia Lin Wang

Subjects

Troposphere, Total organic carbon, Atmospheric Science, Climatology, Environmental chemistry, Environmental science, Collection period, Biomass burning, Elemental carbon, Pressure level, General Environmental Science, Aerosol, Plume

Abstract

Eight carbonaceous fractions from aerosols were resolved using the Interagency Monitoring of Protected Visual Environments (IMPROVE) protocol (Chow et al., 1993). The aerosols were collected at the Mountain Lulin Atmospheric Background Station (Mt. Lulin, 2862 m a.s.l.) in Central Taiwan from April 2003 to April 2012. The monthly and yearly levels of organic carbon (OC) and elemental carbon (EC) varied consistently with PM 2.5 mass concentrations during biomass burning (BB) period. The highest monthly carbonaceous content was observed in March and the highest yearly carbonaceous concentration was observed in 2007. This finding is consistent with the BB activity in Indochina and indicates that carbonaceous content is a major component of BB aerosols. Lee et al. (2011) classified four trajectory groups from the air masses transported to Mt. Lulin during the aerosol collection period. For the air masses transported from the BB area (the BB group) in Indochina, the carbonaceous content was greater than the water-soluble ions in PM 2.5 , and the OC/EC ratio (4.8 ± 1.5) was high. With EC as the indicator of primary emission sources, the air masses of the BB group were found to contain more primary than secondary OC. The Anthropogenic group (from the local and free troposphere below the 700-hPa pressure level over the Asian continent) probably contained more secondary than primary OC or the sources of OC and EC could be quite diverse. The average char-EC/soot-EC (low-temperature EC/high-temperature EC) ratios were 3.9 ± 3.5, 0.4 ± 0.4, 0.9 ± 0.8, and 0.3 ± 0.4 for the trajectory groups BB , SNBB (from BB source areas during the non-BB period), Anthropogenic , and FT (from the oceanic area and the free troposphere above the 700-hPa pressure level over the Asian continent), respectively. The presence of a high char-EC/soot-EC ratio confirmed the correct classification of the BB group, whereas the low ratios from the other groups indicated the strong influence of vehicle exhaust. It is noted that higher OC and EC levels were obtained at Mt. Lulin as compared with those obtained at other high-elevation sites. This difference suggested that the Indochina BB plume exhibited a more serious climatic impact on the background air in East Asia than in other places in Asia and Europe. On the basis of the carbonaceous levels of the SNBB and FT groups, the background OC and EC levels of approximately 3000 m in the West Pacific are around 1.33 μg m −3 and 0.35 μg m −3 , respectively.

Published

2014

16. Characterization of aerosol chemical properties from near-source biomass burning in the northern Indochina during 7-SEAS/Dongsha experiment

Author

You Jia Chang, Ming Tung Chuang, Chung Te Lee, Charles C.-K. Chou, Jia Lin Wang, Khajornsak Sopajaree, Neng Huei Lin, and Guey Rong Sheu

Subjects

Total organic carbon, Atmospheric Science, Softwood, Potassium, Levoglucosan, chemistry.chemical_element, Aerosol, chemistry.chemical_compound, chemistry, Environmental chemistry, Composition (visual arts), Biomass burning, General Environmental Science, Optical reflectance

Abstract

Biomass burning (BB) in Indochina produces a great amount of aerosols, but related information on this phenomenon is scarce. In the present study, aerosol samples were collected from Suthep Mountain (98° 53′E, 18° 48′N, 1396 m) in Chiangmai, Northern Indochina, in March and April 2010. To our knowledge, this study is the first to reveal the chemical characteristics of BB aerosol near the burning sources in Indochina. The composition analyzed included water-soluble ions, carbonaceous fractions obtained using the thermal optical reflectance method, low-molecular-weight dicarboxylates, anhydrosugars, and water-soluble organic carbon (WSOC). Enriched tracers from the collected aerosols, such as potassium ion (K+) and levoglucosan, confirmed that the samples were influenced by BB activity. The percentage of K+ in PM2.5 (2.51% ± 0.31%) in the present study is higher than that in other studies. The analysis also showed that directly emitted organic carbon (OC) is the most abundant component in the collected particles. The percentage of WSOC in OC in the present study is greater than that in laboratory experiments. Moreover, the char-EC to soot-EC ratio (defined as the ratio of the subtraction of pyrolized OC from the measured EC1, EC1-OP, over the sum of EC2 and EC3) of 9.4 ± 3.8 in PM2.5 is similar to the value of BB in the literature. Using the recognized BB aerosol tracers K+ and levoglucosan, the present study inferred that PM2.5 EC1-OP and OC3 are also good BB tracers near sources. The collected BB aerosols may have been contributed by the smoldering state of softwood burning.

Published

2013

17. An overview of regional experiments on biomass burning aerosols and related pollutants in Southeast Asia: From BASE-ASIA and the Dongsha Experiment to 7-SEAS

Author

Christina Hsu, Neng Huei Lin, Chang Feng Ou-Yang, Khajornsak Sopajaree, Chuen Jinn Tsai, Jyh Jian Liu, Kuen-Song Lin, Ying I. Tsai, Hal Maring, Sheng Hsiang Wang, Shih Jen Huang, Shui-Jen Chen, Lin-Chi Wang, Chi Ming Peng, Ming Tung Chuang, Ming Cheng Yen, Ben-Jei Tsuang, Jia Lin Wang, Russell C. Schnell, Wen-Jhy Lee, Andrew M. Sayer, Chang-Tang Chang, Yu Chi Chu, Guey Rong Sheu, Si Chee Tsay, Gin Rong Liu, Jeffrey S. Reid, Joshua S. Fu, Xuan Anh Nguyen, Man-Ting Cheng, Chung Te Lee, Brent N. Holben, Kai Hsien Chi, Wei Li Chiang, Tang Huang Lin, Shuenn Chin Chang, and Thomas J. Conway

Subjects

Pollution, Biogeochemical cycle, Atmospheric Science, media_common.quotation_subject, Air pollution, Climate change, Weather and climate, Dongsha Experiment, medicine.disease_cause, Atmospheric sciences, Southeast Asia, Aerosol, Troposphere, 7-SEAS, Environmental Science(all), Climatology, medicine, Water cycle, BASE-ASIA, Air toxics, General Environmental Science, media_common, Biomass burning

Abstract

By modulating the Earth-atmosphere energy, hydrological and biogeochemical cycles, and affecting regional-to-global weather and climate, biomass burning is recognized as one of the major factors affecting the global carbon cycle. However, few comprehensive and wide-ranging experiments have been conducted to characterize biomass-burning pollutants in Southeast Asia (SEA) or assess their regional impact on meteorology, the hydrological cycle, the radiative budget, or climate change. Recently, BASE-ASIA (Biomass-burning Aerosols in South-East Asia: Smoke Impact Assessment) and the 7-SEAS (7-South-East Asian Studies)/Dongsha Experiment were conducted during the spring seasons of 2006 and 2010 in northern SEA, respectively, to characterize the chemical, physical, and radiative properties of biomass-burning emissions near the source regions, and assess their effects. This paper provides an overview of results from these two campaigns and related studies collected in this special issue, entitled “Observation, modeling and impact studies of biomass burning and pollution in the SE Asian Environment”. This volume includes 28 papers, which provide a synopsis of the experiments, regional weather/climate, chemical characterization of biomass-burning aerosols and related pollutants in source and sink regions, the spatial distribution of air toxics (atmospheric mercury and dioxins) in source and remote areas, a characterization of aerosol physical, optical, and radiative properties, as well as modeling and impact studies. These studies, taken together, provide the first relatively complete dataset of aerosol chemistry and physical observations conducted in the source/sink region in the northern SEA, with particular emphasis on the marine boundary layer and lower free troposphere (LFT). The data, analysis and modeling included in these papers advance our present knowledge of source characterization of biomass-burning pollutants near the source regions as well as the physical and chemical processes along transport pathways. In addition, we raise key questions to be addressed by a coming deployment during springtime 2013 in northern SEA, named 7-SEAS/BASELInE (Biomass-burning Aerosols & Stratocumulus Environment: Lifecycles and Interactions Experiment). This campaign will include a synergistic approach for further exploring many key atmospheric processes (e.g., complex aerosol–cloud interactions) and impacts of biomass burning on the surface–atmosphere energy budgets during the lifecycles of biomass-burning emissions.

Published

2013

18. Aerosol chemical properties and related pollutants measured in Dongsha Island in the northern South China Sea during 7-SEAS/Dongsha Experiment

Author

Guey Rong Sheu, Chung Te Lee, Jia Lin Wang, Shuenn Chin Chang, Ming Tung Chuang, You Jia Chang, and Neng Huei Lin

Subjects

Pollutant, Pollution, Atmospheric Science, geography, geography.geographical_feature_category, South china, Meteorology, media_common.quotation_subject, Coal combustion products, Aerosol, Oceanography, Southern china, Peninsula, Period (geology), Environmental science, General Environmental Science, media_common

Abstract

Aerosol observations were conducted at Dongsha Island in two batches from 19 to 23 March and 10 to 19 April 2010. Dongsha Island is located in a remote area over the northern South China Sea (SCS), distantly surrounded by southern China, Taiwan, the Philippines, and the Indochinese Peninsula. During the study period, the average PM10 and PM2.5 mass concentrations were 26.5 ± 19.4 and 12.6 ± 6.0 μg m−3, respectively. In particular, a daily PM10 concentration of 94.1 μg m−3 caused by a yellow-dust event originating from the Asian Continent was recorded on 21 March. Other than this event, the PM2.5 and PM10–2.5 daily levels were 7.1 ± 1.2 and 12.6 ± 5.0 μg m−3, respectively, on days without pollution from anthropogenic sources in the surrounding areas. Water-soluble ions (WSIs) were the predominant components that accounted for 58.7% ± 10.5% and 51.1% ± 7.2% of the PM10 and PM2.5 mass. The second most abundant component was carbonaceous content, which accounted for 9.5% ± 4.7% and 17.5% ± 5.3% of PM10 and PM2.5, respectively. SO 4 2 − was the most abundant PM2.5 WSI, whereas the Na+ and Cl− pair was the most abundant PM10–2.5 WSI. Based on the U.S. IMPROVE protocol, the resolved carbonaceous fractions were mainly distributed in PM2.5 and influenced by coal combustion, mobile vehicles, and biomass burning. Most of the resolved WSIs in particles were in the liquid phase due to the humid environment around the northern SCS.

Published

2013

19. Application of WRF/Chem-MADRID for real-time air quality forecasting over the Southeastern United States

Author

Yang Zhang, Daiwen Kang, and Ming-Tung Chuang

Subjects

Atmospheric Science, Meteorology, Fine particulate, Weather Research and Forecasting Model, Precipitation, Categorical variable, Air quality index, Wind speed, General Environmental Science, Aerosol

Abstract

PM2.5 WRF/Chem-MADRID abstract A Real-Time Air Quality Forecast (RT-AQF) system that is based on a three-dimensional air quality model provides a powerful tool to forecast air quality and advise the public with proper preventive actions. In this work, a new RT-AQF system is developed based on the online-coupled Weather Research and Forecasting model with Chemistry (WRF/Chem) with the Model of Aerosol Dynamics, Reaction, Ioniza- tion, and Dissolution (MADRID) (referred to as WRF/Chem-MADRID) and deployed in the southeastern U.S. during MayeSeptember, 2009. Max 1-h and 8-h average ozone (O3) and 24-h average fine particulate matter (PM2.5) are evaluated against surface observations from the AIRNow database in terms of spatial distribution, temporal variation, and domain-wide and region-specific discrete and categorical perfor- mance statistics. WRF/Chem-MADRID demonstrates good forecasting skill that is consistent with current RT-AQF models. The overpredictions of O3 and underprediction of PM2.5 are likely due to uncertainties in emissions such as those of biogenic volatile organic compounds (BVOCs) and ammonia, inaccuracies in simulated meteorological variables such as 2-m temperature, 10-m wind speed, and precipitation, and uncertainties in the boundary conditions. Sensitivity simulations show that the use of the online BVOC emissions can improve PM2.5 forecast in areas with high BVOC emissions and adjusting lateral bound- aries can improve domain-wide O3 and PM2.5 predictions. Several limitations and uncertainties are identified to further improve the model's forecasting skill.

Published

2011

20. Aerosol characteristics from the Taiwan aerosol supersite in the Asian yellow-dust periods of 2002

Author

Chang-Chuan Chan, Ming Tung Chuang, Song Lih Huang, Chung Te Lee, and Tsun-Jen Cheng

Subjects

Atmospheric Science, Meteorology, Asian Dust, Air pollution, Storm, medicine.disease_cause, Atmospheric sciences, Aerosol, Troposphere, Anticyclone, Dust storm, medicine, Environmental science, Air quality index, General Environmental Science

Abstract

The occurrence of Asian dust storms, and the subsequent transport of yellow dust (YD) greatly influences the air quality of lee-side countries such as Korea and Japan. The dust is also frequently transported in a southward direction by a strong cold high-pressure system that affects the air quality in Taiwan. This study reports the aerosol properties that were monitored continuously at the Taiwan aerosol supersite during YD events in 2002. Based on the observations of meteorology and aerosols, we divided the time interval of a YD event into a before period , during period , and after period . Among the seven observed YD events, the second event was marked with the maximum hourly PM 10 level at 502 μg m −3 , and with the longest during period for a total of 147 h. The averages of the hourly PM 10 and PM 2.5−10 were much higher in the during period as compared to those in the before period . It is interesting to note that the time lapse in the during period was well correlated with the maximum level of both PM 10 and PM 2.5−10 . It must be noted that the PM 2.5 levels were dramatically increased in the after period , which was due to the accumulation of particles influenced by the anticyclonic outflow. The aerosol size distribution in the third YD event verified that supermicron particles dominated in the during period , and that submicron particles were predominant in the before and after periods . For the chemical properties of the aerosols, time series results indicated that sulfates were mostly contributed by the dust transport, and the others were more related to vehicle exhausts. However, they all accumulated in the period of atmospheric stagnancy.

Published

2006

21. The effects of synoptical weather pattern and complex terrain on the formation of aerosol events in the Greater Taipei area

Author

E. E. Chang, Ming Tung Chuang, Pen-Chi Chiang, Chang-Chuan Chan, Chu Fang Wang, and Chung Te Lee

Subjects

Environmental Engineering, Time Factors, Meteorology, Taiwan, North Pacific High, Terrain, Atmospheric sciences, Disasters, Atmospheric instability, Environmental Chemistry, Particle Size, Waste Management and Disposal, Weather map, Weather, Aerosols, Air Movements, Air Pollutants, Geography, Pollution, Aerosol, Cold front, Typhoon, Environmental science, Particulate Matter, Seasons, Pressure system, Environmental Monitoring

Abstract

The aerosol in the Taipei basin is difficult to transport outward under specific weather patterns owing to complex terrain blocking. In this study, seven weather patterns are identified from synoptic weather maps for aerosol events, which occurred from March 2002 to February 2005. Among the identified weather patterns, High Pressure Peripheral Circulation (HPPC), Warm area Ahead of a cold Front (WAF), TYPhoon (TYP), Pacific High Pressure system stretching westerly (PHP), Weak High Pressure system (WHP), and Weak Southern Wind (WSW) are related to terrain blocking. The remaining pattern is High Pressure system Pushing (HPP). The classification of the pollution origin of the air masses shows that 15% of event days were contributed by long-range transport (LRT), 20% by local pollution (LP), and 65% by LRT/LP mix. Terrain blocking causes aerosol accumulation from high atmospheric stability and weak winds occurring under HPPC, TYP, and PHP weather patterns when the Taipei basin is situated on the lee side of the Snow Mountains Chain (SMC). Terrain blocking also occurs when the Taipei basin is situated on the upwind of SMC and Mt. Da-Twen under WAF and WSW patterns. To study the variation of aerosol properties under the mixed influence of terrain and pollution origin, we conducted a field observation simultaneously at the urban, suburban, and background sites in the Greater Taipei area from April 14 to 23, 2004. Terrain blocking plays an important role in aerosol accumulation in the stagnant environment when the Taipei basin is on the lee side of SMC. On the other hand, the PM2.5 sulfate level is stable with a fraction of 30% in PM2.5 during the observation period at the urban (25%−33%) and background (25%−41%) sites. It indicates that background PM2.5 sulfate is high on the West Pacific in winter.

Published

2007