Your search keyword '"Song, Mijung"' showing total 34 results

1. Impact of biomass burning on PM2.5 and organic aerosol: Quantitative estimates and spatial distributions in four Northeast Asian sites

Author

Nirmalkar, Jayant, Lee, Ji Yi, Lee, Kwangyul, Ahn, Junyoung, Qiu, Yanting, Wu, Zhijun, Natsagdorj, Amgalan, Jang, Kyoung-Soon, Kim, Changhyuk, and Song, Mijung

Published

2024

2. Improvement of the anthropogenic emission rate estimate in Ulaanbaatar, Mongolia, for 2020–21 winter

Author

Lee, Hyung-Min, Choi, Eunlak, Kim, Yong Pyo, Soyol-Erdene, Tseren-Ochir, Natsagdorj, Amgalan, Wu, Zhijun, Song, Mijung, Kim, Changhyuk, Jang, Kyoung-Soon, Ahn, Junyoung, Matsuki, Atsushi, Torabi, Esmatullah, Woo, Jung-Hun, Jung, Chang Hoon, and Lee, Ji Yi

Published

2024

3. Effects of volatile organic compounds and new particle formation on real-time hygroscopicity of PM2.5 particles in Seosan, Republic of Korea

Author

Kim, Jeongbeen, Ha, Yoonkyeong, Cho, Kyungil, Lee, Soodong, Jung, Jinsang, Lee, Seung-Bok, Lee, Ji Yi, Song, Mijung, Jang, Kyoung-Soon, Lee, Kwangyul, Ahn, Junyoung, and Kim, Changhyuk

Published

2024

4. Assessment of potential ecological risk for polycyclic aromatic hydrocarbons in urban soils with high level of atmospheric particulate matter concentration

Author

Moon, Hi Gyu, Bae, Seonhee, Chae, Yooeun, Kim, Yong-Jae, Kim, Hyung-Min, Song, Mijung, Bae, Min-Suk, Lee, Chil-Hyoung, Ha, Taewon, Seo, Jong-Su, and Kim, Sooyeon

Published

2024

5. Chemical and morphological characterization by SEM–EDS of PM2.5 collected during winter in Ulaanbaatar, Mongolia

Author

Park, Ji-In, Kim, Min Sung, Yeo, Myoung, Choi, Mira, Lee, Ji Yi, Natsagdorj, Amgalan, Kim, Changhyuk, Song, Mijung, and Jang, Kyoung-Soon

Published

2023

6. Secondary aerosol formation drives atmospheric particulate matter pollution over megacities (Beijing and Seoul) in East Asia

Author

Qiu, Yanting, Wu, Zhijun, Man, Ruiqi, Zong, Taomou, Liu, Yuechen, Meng, Xiangxinyue, Chen, Jingchuan, Chen, Shiyi, Yang, Suxia, Yuan, Bin, Song, Mijung, Kim, Changhyuk, Ahn, Junyoung, Zeng, Limin, Lee, Jiyi, and Hu, Min

Published

2023

7. Effect of inorganic-to-organic mass ratio on the heterogeneous OH reaction rates of erythritol: implications for atmospheric chemical stability of 2-methyltetrols

Author

Xu, Rongshuang, Lam, Hoi Ki, Wilson, Kevin R, Davies, James F, Song, Mijung, Li, Wentao, Tse, Ying-Lung Steve, and Chan, Man Nin

Subjects

Astronomical and Space Sciences, Atmospheric Sciences, Meteorology & Atmospheric Sciences

Abstract

The 2-methyltetrols have been widely chosen as chemical tracers for isoprene-derived secondary organic aerosols. While they are often assumed to be relatively unreactive, a laboratory study reported that pure erythritol particles (an analog of 2-methyltetrols) can be heterogeneously oxidized by gas-phase OH radicals at a significant rate. This might question the efficacy of these compounds as tracers in aerosol source-apportionment studies. Additional uncertainty could arise as organic compounds and inorganic salts often coexist in atmospheric particles. To gain more insights into the chemical stability of 2-methyltetrols in atmospheric particles, this study investigates the heterogeneous OH oxidation of pure erythritol particles and particles containing erythritol and ammonium sulfate (AS) at different dry inorganic-to-organic mass ratios (IOR) in an aerosol flow tube reactor at a high relative humidity of 85 %. The same reaction products are formed upon heterogenous OH oxidation of erythritol and erythritol-AS particles, suggesting that the reaction pathways are not strongly affected by the presence and amount of AS. On the other hand, the effective OH uptake coefficient, eff, is found to decrease by about a factor of 20 from 0:450:025 to 0:020:001 when the relative abundance of AS increases and the IOR increases from 0.0 to 5.0. One likely explanation is the presence of dissolved ions slows down the reaction rates by decreasing the surface concentration of erythritol and reducing the frequency of collision between erythritol and gas-phase OH radicals at the particle surface. Hence, the heterogeneous OH reactivity of erythritol and likely 2-methyltetrols in atmospheric particles would be slower than previously thought when the salts are present. Given 2-methyltetrols often coexist with a significant amount of AS in many environments, where ambient IOR can vary from 1:89 to 250, our kinetic data would suggest that 2-methyltetrols in atmospheric particles are likely chemically stable against heterogeneous OH oxidation under humid conditions.

Published

2020

8. Liquid-liquid phase separation and viscosity within secondary organic aerosol generated from diesel fuel vapors

Author

Song, Mijung, Maclean, Adrian M, Huang, Yuanzhou, Smith, Natalie R, Blair, Sandra L, Laskin, Julia, Laskin, Alexander, DeRieux, Wing-Sy Wong, Li, Ying, Shiraiwa, Manabu, Nizkorodov, Sergey A, and Bertram, Allan K

Subjects

Meteorology & Atmospheric Sciences, Atmospheric Sciences, Astronomical and Space Sciences

Abstract

Abstract. Information on liquid–liquid phase separation (LLPS) and viscosity (ordiffusion) within secondary organic aerosol (SOA) is needed to improvepredictions of particle size, mass, reactivity, and cloud nucleatingproperties in the atmosphere. Here we report on LLPS and viscosities withinSOA generated by the photooxidation of diesel fuel vapors. Diesel fuelcontains a wide range of volatile organic compounds, and SOA generated bythe photooxidation of diesel fuel vapors may be a good proxy for SOA fromanthropogenic emissions. In our experiments, LLPS occurred over the relativehumidity (RH) range of ∼70 % to ∼100 %,resulting in an organic-rich outer phase and a water-rich inner phase. Theseresults may have implications for predicting the cloud nucleating propertiesof anthropogenic SOA since the presence of an organic-rich outer phase athigh-RH values can lower the supersaturation with respect to water requiredfor cloud droplet formation. At ≤10 % RH, the viscosity was ≥1×108 Pa s, which corresponds to roughly the viscosity of tarpitch. At 38 %–50 % RH, the viscosity was in the range of 1×108 to 3×105 Pa s. These measured viscosities areconsistent with predictions based on oxygen to carbon elemental ratio (O:C)and molar mass as well as predictions based on the number of carbon,hydrogen, and oxygen atoms. Based on the measured viscosities and theStokes–Einstein relation, at ≤10 % RH diffusion coefficients oforganics within diesel fuel SOA is ≤5.4×10-17 cm2 s−1 and the mixing time of organics within 200 nm diesel fuel SOAparticles (τmixing) is 50 h. These small diffusion coefficientsand large mixing times may be important in laboratory experiments, where SOAis often generated and studied using low-RH conditions and on timescales ofminutes to hours. At 38 %–50 % RH, the calculated organic diffusioncoefficients are in the range of 5.4×10-17 to 1.8×10-13 cm2 s−1 and calculated τmixing values arein the range of ∼0.01 h to ∼50 h. These valuesprovide important constraints for the physicochemical properties ofanthropogenic SOA.

Published

2019

9. Spatiotemporal differences on the real-time physicochemical characteristics of PM2.5 particles in four Northeast Asian countries during Winter and Summer 2020–2021

Author

Ha, Yoonkyeong, Kim, Jeongbeen, Lee, Soodong, Cho, Kyungil, Shin, Jiyoon, Kang, Giwon, Song, Mijung, Lee, Ji Yi, Jang, Kyoung-Soon, Lee, Kwangyul, Ahn, Junyoung, Wu, Zhijun, Matsuki, Atsushi, Tang, Ning, Sadanaga, Yasuhiro, Natsagdorj, Amgalan, and Kim, Changhyuk

Published

2023

10. Effects of inorganic salts on the heterogeneous OH oxidation of organic compounds: insights from methylglutaric acid-ammonium sulfate

Author

Lam, Hoi Ki, Shum, Sze Man, Davies, James F, Song, Mijung, Zuend, Andreas, and Chan, Man Nin

Subjects

Atmospheric Sciences, Astronomical and Space Sciences, Meteorology & Atmospheric Sciences

Abstract

Abstract. Atmospheric particles, consisting of inorganic salts, organic compounds anda varying amount of water, can continuously undergo heterogeneous oxidationinitiated by gas-phase oxidants at the particle surface, changing thecomposition and properties of particles over time. To date, most studiesfocus on the chemical evolution of pure organic particles upon oxidation. Togain more fundamental insights into the effects of inorganic salts on theheterogeneous kinetics and chemistry of organic compounds, we investigatethe heterogeneous OH oxidation of 3-methylglutaric acid (3-MGA) particlesand particles containing both 3-MGA and ammonium sulfate (AS) in anorganic-to-inorganic mass ratio of 2 in an aerosol flow tube reactor at ahigh relative humidity of 85.0 %. The molecular information of theparticles before and after OH oxidation is obtained using the directanalysis in real time (DART), a soft atmospheric pressure ionization sourcecoupled to a high-resolution mass spectrometer. Optical microscopymeasurements reveal that 3-MGA–AS particles are in a single liquid phaseprior to oxidation at high relative humidity. Particle mass spectra showthat C6 hydroxyl and C6 ketone functionalization products arethe major products formed upon OH oxidation in the absence and presence ofAS, suggesting that the dissolved salt does not significantly affectreaction pathways. The dominance of C6 hydroxyl products over C6 ketone products could be explained by the intermolecular hydrogenabstraction by tertiary alkoxy radicals formed at the methyl-substitutedtertiary carbon site. On the other hand, kinetic measurements show that theeffective OH uptake coefficient, γeff, for 3-MGA–AS particles(0.99±0.05) is smaller than that for 3-MGA particles (2.41±0.13) by about a factor of ∼2.4. A smaller reactivity observed in 3-MGA–AS particles might be attributed to a higher surfaceconcentration of water molecules and the presence of ammonium and sulfateions, which are chemically inert to OH radicals, at the particle surface.This could lower the collision probability between the 3-MGA and OHradicals, resulting in a smaller overall reaction rate. Our results suggestthat inorganic salts likely alter the overall heterogeneous reactivity oforganic compounds with gas-phase OH radicals rather than reaction mechanismsin well-mixed aqueous organic–inorganic droplets at a high humidity, i.e.,85 % relative humidity (RH). It also acknowledges that the effects of inorganic salts on theheterogeneous reactivity could vary greatly, depending on the particlecomposition and environmental conditions (e.g., RH and temperature). Forinstance, at lower relative humidities, aqueous 3-MGA–AS droplets likelybecome more concentrated and more viscous before efflorescence, possiblygiving rise to diffusion limitation during oxidation under relatively dry orcold conditions. Further studies on the effects of inorganic salts on thediffusivity of the species under different relative humidities within theorganic–inorganic particles are also desirable to better understand therole of inorganic salts in the heterogeneous reactivity of organiccompounds.

Published

2019

11. Influence of Relative Humidity and Composition on PM2.5 Phases in Northeast Asia.

Author

Seong, Changjoon, Kim, Daeun, Jeong, Rani, Qiu, Yanting, Wu, Zhijun, Lee, Ji Yi, Lee, Kwangyul, Ahn, Joonyoung, Jang, Kyoung-Soon, Zuend, Andreas, Kim, Changhyuk, Natsagdorj, Amgalan, and Song, Mijung

Published

2024

12. Particle phase state and aerosol liquid water greatly impact secondary aerosol formation: insights into phase transition and its role in haze events.

Author

Meng, Xiangxinyue, Wu, Zhijun, Chen, Jingchuan, Qiu, Yanting, Zong, Taomou, Song, Mijung, Lee, Jiyi, and Hu, Min

Subjects

PHASE transitions, AEROSOLS, SULFATE aerosols, HAZE, CHEMICAL reactions, HUMIDITY

Abstract

The particle phase state is crucial for reactive gas uptake, heterogeneous, and multiphase chemical reactions, thereby impacting secondary aerosol formation. This study provides valuable insights into the significance of particle-phase transition and aerosol liquid water (ALW) in particle mass growth during winter. Our findings reveal that particles predominantly exist in a semi-solid or solid state during clean winter days with ambient relative humidity (RH) below 30 %. However, a non-liquid to liquid phase transition occurs when the ALW mass fraction exceeds 15 % (dry mass) at transition RH thresholds of 40 %–60 %. During haze episodes, the transformation rates of sulfate and nitrate aerosols rapidly increase through phase transition and increased ALW by 48 % and 11 %, respectively, resulting in noticeable increases in secondary inorganic aerosols (SIA). The presence of abundant ALW, favored by elevated RH and higher proportion of SIA, facilitates the partitioning of water-soluble compounds from the gas to the particle phase, as well as heterogeneous and aqueous processes in liquid particles. This leads to a substantial increase in the formation of secondary organic aerosols and elevated aerosol oxidation. Consequently, the overall hygroscopicity parameters exhibit a substantial enhancement, with a mean value of 23 %. These results highlight phase transition as a key factor initiating the positive feedback loops between ALW and secondary aerosol formation during haze episodes over the North China Plain. Accurate predictions of secondary aerosol formation necessitate explicit consideration of the particle phase state in chemical transport models. [ABSTRACT FROM AUTHOR]

Published

2024

13. Ammonia and Particulate Matter Emissions at a Korean Commercial Pig Farm and Influencing Factors.

Author

Choi, Lak-yeong, Lee, Se-yeon, Jeong, Hanna, Park, Jinseon, Hong, Se-woon, Kwon, Kyeong-Seok, and Song, Mijung

Subjects

PARTICULATE matter, SWINE farms, AMMONIA, SPRING, SUSTAINABLE development, SUSTAINABLE agriculture, FEED additives

Abstract

Simple Summary: This study examined the levels of certain pollutants, primarily ammonia and particulate matter (PM), emitted by a commercial pig farm in Korea. Understanding these levels is vital for reducing the environmental impact of pig farming and ensuring a sustainable future for this industry. Interestingly, the study found that previous guidelines in Korea might have overestimated these pollution levels, although the current findings are consistent with global research. Seasonal variations also impacted pollution levels: more ammonia was released in spring and autumn, while other pollutants increased in summer. Factors such as the number and age of the pigs significantly influenced these emission levels, as did airflow and ventilation. In essence, continued research in this area will help to improve pig farming practices in Korea, ensuring a balance between successful farming and environmental preservation. Quantifying emission factors of ammonia and particulate matter (PM) in livestock production systems is crucial for assessing and mitigating the environmental impact of animal production and for ensuring industry sustainability. This study aimed to determine emission factors of ammonia, total suspended particles (TSPs), PM10, and PM2.5 for piglets and growing–finishing pigs at a commercial pig farm in Korea. It also sought to identify factors influencing these emission factors. The research found that the emission factors measured were generally lower than those currently used in Korea, but were consistent with findings from individual research studies in the literature. Seasonal variations were observed, with ammonia emissions peaking in spring and autumn, and PM emissions rising in summer. Correlation analyses indicated that the number of animals and their average age correlated positively with both ammonia and PM emission factors. Ventilation rate was also positively correlated with PM emissions. Future extended field measurements across diverse pig farms will offer deeper insights into the emission factors of pig farms in Korea, guiding the development of sustainable livestock management practices. [ABSTRACT FROM AUTHOR]

Published

2023

14. Particle Phase State and Aerosol Liquid Water Greatly Impact Secondary Aerosol Formation: Insights into Phase Transition and Role in Haze Events.

Author

Meng, Xiangxinyue, Wu, Zhijun, Chen, Jingchuan, Qiu, Yanting, Zong, Taomou, Song, Mijung, Lee, Jiyi, and Hu, Min

Subjects

PHASE transitions, AEROSOLS, SULFATE aerosols, HAZE, CHEMICAL reactions, HUMIDITY

Abstract

The particle-phase state is crucial for reactive gas uptake, heterogeneous, and multiphase chemical reactions, thereby impacting secondary aerosol formation. This study provides valuable insights into the significance of particle-phase transition and aerosol liquid water (ALW) in winter particulate growth. Our findings reveal that particles predominantly exist as semi-solid or solid during clean winter days with ambient relative humidity (RH) below 30 %. However, non-liquid to liquid phase transition occurs when the ALW mass fraction exceeds 15 % (dry mass) at transition RH thresholds of 40–60 %. During haze episodes, the transformation rates of sulfate and nitrate aerosols rapidly increase through phase transition and increased ALW by 48 % and 11 %, respectively, resulting in noticeable increases in secondary inorganic aerosols (SIA). The presence of abundant ALW, favored by elevated RH and higher proportion of SIA, facilitates heterogeneous and aqueous processes in liquid particles, leading to a substantial increase in the formation of secondary organic aerosols and elevated aerosol oxidation. Consequently, the overall hygroscopicity parameters exhibit a substantial enhancement with a mean value of 23 %. These results highlight phase transition as a key factor initiating the positive feedback loops between ALW and secondary aerosol formation during haze episodes over the North China Plain. Accurate predictions of secondary aerosol formation necessitate explicit consideration of the particle-phase state in chemical transport models. [ABSTRACT FROM AUTHOR]

Published

2023

15. Resolving the mechanisms of hygroscopic growth and cloud condensation nuclei activity for organic particulate matter

Author

Liu, Pengfei, Song, Mijung, Zhao, Tianning, Gunthe, Sachin S., Ham, Suhan, He, Yipeng, Qin, Yi Ming, Gong, Zhaoheng, Amorim, Juliana C., Bertram, Allan K., and Martin, Scot T.

Published

2018

16. Comparisons of Spatial and Temporal Variations in PM 2.5 -Bound Trace Elements in Urban and Rural Areas of South Korea, and Associated Potential Health Risks.

Author

Nirmalkar, Jayant, Lee, Kwangyul, Ahn, Junyoung, Lee, Jiyi, and Song, Mijung

Subjects

TRACE elements, X-ray spectroscopy, SPATIAL variation, AIR quality standards, RURAL geography, HEALTH risk assessment

Abstract

PM2.5-bound trace elements were chosen for health risk assessment because they have been linked to an increased risk of respiratory and cardiovascular illness. Since the Korean national air quality standard for ambient particulate matter is based on PM2.5 mass concentration, there have only been a few measurements of PM2.5 particles together with trace elements that can be utilized to evaluate their effects on air quality and human health. Thus, this study describes the trace elements bound to PM2.5 in Seoul (urban area) and Seosan (rural area) using online nondestructive energy-dispersive X-ray fluorescence analysis from December 2020 to January 2021. At both the Seoul and Seosan sites, S, K, Si, Ca, and Fe constituted most of the PM2.5-bound trace elements (~95%); major components such as S, K, and soil (estimatedcalculatedcalculated based on oxides of Si, Fe, Ca, and Ti) were presumably from anthropogenic and crustal sources, as well as favorable meteorological conditions. During winter, synoptic meteorology favored the transport of particles from severely contaminated regions, such as the East Asian outflow and local emissions. The total dry deposition flux for crustal elements was 894.5 ± 320.8 µg m−2 d−1 in Seoul and 1088.8 ± 302.4 µg m−2 d−1 in Seosan. Moreover, potential health risks from the trace elements were estimated. Cancer risk values for carcinogenic trace elements (Cr, As, Ni, and Pb) were within the tolerable limit (1 × 10−6), suggesting that adults and children were not at risk of cancer throughout the study period in Seoul and Seosan. Furthermore, a potential risk assessment of human exposure to remaining carcinogens (Cr, As, Ni, and Pb) and non-carcinogens (Cu, Fe, Zn, V, Mn, and Se) indicated that these trace elements posed no health risks. Nevertheless, trace element monitoring, risk assessment, and mitigation must be strengthened throughout the study area to confirm that trace-element-related health effects remain harmless. Researchers and policymakers can use the database from this study on spatial and temporal variation to establish actions and plans in the future. [ABSTRACT FROM AUTHOR]

Published

2023

17. Comparison of Phase States of PM2.5 over Megacities, Seoul and Beijing, and Their Implications on Particle Size Distribution.

Author

Song, Mijung, Jeong, Rani, Kim, Daeun, Qiu, Yanting, Meng, Xiangxinyue, Wu, Zhijun, Zuend, Andreas, Ha, Yoonkyeong, Kim, Changhyuk, Kim, Haeri, Gaikwad, Sanjit, Jang, Kyoung-Soon, Lee, Ji Yi, and Ahn, Joonyoung

Published

2022

18. New particle formation and growth in relation to vertical mixing and chemical species during ABC-EAREX2005

Author

Song, Mijung, Lee, Meehye, Kim, Jong H., Yum, Seong S., Lee, Gangwoong, and Kim, Kyung-Ryul

Published

2010

19. Viscosity and physical state of sucrose mixed with ammonium sulfate droplets.

Author

Jeong, Rani, Lilek, Joseph, Zuend, Andreas, Xu, Rongshuang, Chan, Man Nin, Kim, Dohyun, Moon, Hi Gyu, and Song, Mijung

Subjects

AMMONIUM sulfate, VISCOSITY, TERNARY system, ATMOSPHERIC chemistry, ACTIVITY coefficients, SUCROSE

Abstract

Although knowledge of the physical state of aerosol particles is essential to understand atmospheric chemistry model and measurements, information on the viscosity and physical state of aerosol particles consisting of organic and inorganic salts is still rare. Herein, we quantified viscosities at 293 ± 1 K upon dehydration for the binary systems, sucrose– H2O and ammonium sulfate (AS)– H2O , and the ternary systems, sucrose– AS – H2O for organic-to-inorganic dry mass ratios (OIRs) = 4:1 , 1:1 , and 1:4 using bead-mobility and poke-and-flow techniques. Based on the viscosity value of the aerosol particles, we defined the physical states of the total aerosol particles studied in this work. For binary systems, the viscosity of sucrose– H2O particles gradually increased from ∼ 4 × 10 -1 to > ∼ 1 × 10 8 Pas when the relative humidity (RH) decreased from ∼ 81 % to ∼ 24 %, ranging from liquid to semisolid or solid state, which agrees with previous studies. The viscosity of AS – H2O particles remained in the liquid state (< 10 2 Pas) for RH > ∼ 50 %, while for RH ≤∼ 50 %, the particles showed a viscosity of > ∼ 1 × 10 12 Pas , corresponding to a solid state. In case of the ternary systems, the viscosity of organic-rich particles (OIR = 4:1) gradually increased from ∼ 1 × 10 -1 to ∼ 1 × 10 8 Pas for a RH decrease from ∼ 81 % to ∼ 18 %, similar to the binary sucrose– H2O particles. This indicates that the sucrose– AS – H2O particles range from liquid to semisolid or solid across the RH. In the ternary particles for OIR = 1:1 , the viscosities ranged from less than ∼ 1 × 10 2 for RH > 34 % to > ∼ 1 × 10 8 Pas at ∼ 27 %RH. The viscosities correspond to liquid for RH > ∼ 34 %, semisolid for ∼ 34 % < RH < ∼ 27 %, and semisolid or solid for RH < ∼ 27 %. Compared to the organic-rich particles, in the inorganic-rich particles (OIR = 1:4), drastic enhancement in viscosity was observed as RH decreased; the viscosity increased by approximately 8 orders of magnitude during a decrease in RH from 43 % to 25 %, resulting in liquid to semisolid or solid in the RH range. Overall, all particles studied in this work were observed to exist as a liquid, semisolid, or solid depending on the RH. Furthermore, we compared the measured viscosities of ternary systems with OIRs of 4:1 , 1:1 , and 1:4 to the predicted viscosities using the Aerosol Inorganic–Organic Mixtures Functional groups Activity Coefficients Viscosity model (AIOMFAC-VISC) predictions with the Zdanovskii–Stokes–Robinson (ZSR) organic–inorganic mixing model, with excellent model–measurement agreement for all OIRs. [ABSTRACT FROM AUTHOR]

Published

2022

20. Viscosity and phase state of aerosol particles consisting of sucrose mixed with inorganic salts.

Author

Song, Young-Chul, Lilek, Joseph, Lee, Jae Bong, Chan, Man Nin, Wu, Zhijun, Zuend, Andreas, and Song, Mijung

Subjects

MEASUREMENT of viscosity, VISCOSITY, SUCROSE, AEROSOLS, HUMIDITY, ACTIVITY coefficients

Abstract

Research on the viscosity and phase state of aerosol particles is essential because of their significant influence on the particle growth rate, equilibration times, and related evolution of mass concentration as well as heterogeneous reactions. So far, most studies of viscosity and phase state have been focused on organic aerosol particles, yet data on how viscosity can vary when the organic materials are mixed with inorganic salts remain scarce. Herein, using bead-mobility and poke-and-flow techniques, we quantified viscosities at 293 ± 1 K for binary mixtures of organic material / H2O and inorganic salts / H2O , as well as ternary mixtures of organic material / inorganic salts / H2O over the atmospheric relative humidity (RH) range. Sucrose as the organic species and calcium nitrate (Ca(NO3)2) or magnesium nitrate (Mg(NO3)2) as the inorganic salts were examined. For binary sucrose / H2O particles, the viscosities gradually increased from ∼ 3 × 10 -2 to ≳ 1 × 10 8 Pas as RH decreased from ∼ 75 % to ∼ 25 %. Compared with the results for the sucrose / H2O particles, binary Ca(NO3)2/H2O and Mg(NO3)2/H2O particles showed drastic enhancements to ≳ 1 × 10 8 Pas at low RH close to the efflorescence RH. For ternary mixtures of sucrose / Ca(NO3)2 / H2O or sucrose / Mg(NO3)2 / H2O , with organic-to-inorganic mass ratios of 1:1 , the viscosities of the particles gradually increased from ∼ 3 × 10 -2 to greater than ∼ 1 × 10 8 Pas for RH values from ∼ 75 % to ∼ 5 %. Compared to the viscosities of the Ca(NO3)2/H2O particles, higher viscosities were observed for the ternary sucrose / Ca(NO3)2 / H2O particles, with values increased by about 1 order of magnitude at 50 % RH and about 6 orders of magnitude at 35 % RH. Moreover, we applied a thermodynamics-based group-contribution model (AIOMFAC-VISC, Aerosol Inorganic–Organic Mixtures Functional groups Activity Coefficients Viscosity) to predict aerosol viscosities for the studied systems. The model predictions and viscosity measurements show good agreement within ∼ 1 order of magnitude in viscosity. The viscosity measurements indicate that the studied mixed organic–inorganic particles range in phase state from liquid to semi-solid or even solid across the atmospheric RH range at a temperature of 293 K. These results support our understanding that organic / inorganic / H2O particles can exist in a liquid, semisolid, or even a solid state in the troposphere. [ABSTRACT FROM AUTHOR]

Published

2021

21. Effects of liquid–liquid phase separation and relative humidity on the heterogeneous OH oxidation of inorganic–organic aerosols: insights from methylglutaric acid and ammonium sulfate particles.

Author

Lam, Hoi Ki, Xu, Rongshuang, Choczynski, Jack, Davies, James F., Ham, Dongwan, Song, Mijung, Zuend, Andreas, Li, Wentao, Tse, Ying-Lung Steve, and Chan, Man Nin

Subjects

AMMONIUM sulfate, HUMIDITY, AEROSOLS, PHASE separation, ATMOSPHERIC aerosols, CHEMICAL reactions

Abstract

Organic compounds residing near the surface of atmospheric aerosol particles are exposed to chemical reactions initiated by gas-phase oxidants, such as hydroxyl (OH) radicals. Aqueous droplets composed of inorganic salts and organic compounds can undergo phase separation into two liquid phases, depending on aerosol composition and relative humidity (RH). Such phase behavior can govern the surface characteristics and morphology of the aerosols, which in turn affect the heterogeneous reactivity of organic compounds toward gas-phase oxidants. In this work, we used an aerosol flow tube reactor coupled with an atmospheric pressure ionization source (direct analysis in real time) and a high-resolution mass spectrometer to investigate how phase separation in model aqueous droplets containing an inorganic salt (ammonium sulfate, AS) and an organic acid (3-methylglutaric acid, 3-MGA) with an organic-to-inorganic dry mass ratio (OIR) of 1 alters the heterogeneous OH reactivity. At high RH, 3-MGA/AS aerosols were aqueous droplets with a single liquid phase. When the RH decreased, aqueous 3-MGA/AS droplets underwent phase separation at ∼75 % RH. Once the droplets were phase-separated, they exhibited either a core–shell, partially engulfed or a transition from core–shell to partially engulfed structure, with an organic-rich outer phase and an inorganic-rich inner phase. The kinetics, quantified by an effective heterogenous OH rate constant, was found to increase gradually from 1.01±0.02×10-12 to 1.73±0.02×10-12 cm 3 molec. -1 s -1 when the RH decreased from 88 % to 55 %. The heterogeneous reactivity of phase-separated droplets is slightly higher than that of aqueous droplets with a single liquid phase. This could be explained by the finding that when the RH decreases, higher concentrations of organic molecules (i.e., 3-MGA) are present at or near the droplet surface, which are more readily exposed to OH oxidation, as demonstrated by phase separation measurements and model simulations. This could increase the reactive collision probability between 3-MGA molecules and OH radicals dissolved near the droplet surface and secondary chain reactions. Even for phase-separated droplets with a fully established core–shell structure, the diffusion rate of organic molecules across the organic-rich outer shell is predicted to be fast in this system. Thus, the overall rate of reactions is likely governed by the surface concentration of 3-MGA rather than a diffusion limitation. Overall, understanding the aerosol phase state (single liquid phase versus two separate liquid phases) is essential to better probe the heterogenous reactivity under different aerosol chemical composition and environmental conditions (e.g., RH). [ABSTRACT FROM AUTHOR]

Published

2021

22. Liquid–liquid phase separation and morphologies in organic particles consisting of α-pinene and β-caryophyllene ozonolysis products and mixtures with commercially available organic compounds.

Author

Song, Young-Chul, Bé, Ariana G., Martin, Scot T., Geiger, Franz M., Bertram, Allan K., Thomson, Regan J., and Song, Mijung

Subjects

CLOUD condensation nuclei, PHASE separation, ORGANIC compounds, LIQUID phase epitaxy, DISCONTINUOUS precipitation, PARTICLES, CARBONACEOUS aerosols, HUMIDITY

Abstract

Liquid–liquid phase separation (LLPS) in organic aerosol particles can impact several properties of atmospheric particulate matter, such as cloud condensation nuclei (CCN) properties, optical properties, and gas-to-particle partitioning. Yet, our understanding of LLPS in organic aerosols is far from complete. Here, we report on the LLPS of one-component and two-component organic particles consisting of α -pinene- and β -caryophyllene-derived ozonolysis products and commercially available organic compounds of relevance to atmospheric organic particles. In the experiments involving single-component organic particles, LLPS was observed in 8 out of 11 particle types studied. LLPS almost always occurred when the oxygen-to-carbon elemental ratio (O:C) was ≤0.44 but did not occur when O:C was >0.44. The phase separation occurred by spinodal decomposition as well as the nucleation and growth mechanism, and when LLPS occurred, two liquid phases coexisted up to ∼100 % relative humidity (RH). In the experiments involving two-component organic particles, LLPS was observed in 23 out of 25 particles types studied. LLPS almost always occurred when the average was O:C ≤0.67 but never occurred when the average O:C was >0.67. The phase separation occurred by spinodal decomposition as well as the nucleation and growth mechanism. When LLPS occurred, two liquid phases coexisted up to ∼100 % RH. These results provide further evidence that LLPS is likely a frequent occurrence in organic aerosol particles in the troposphere, even in the absence of inorganic salts. [ABSTRACT FROM AUTHOR]

Published

2020

23. Effects of Liquid-Liquid Phase Separation and Relative Humidity on the Heterogeneous OH Oxidation of Inorganic-Organic Aerosols: Insights from Methylglutaric Acid/Ammonium Sulfate Particles.

Author

Lam, Hoi Ki, Xu, Rongshuang, Choczynski, Jack, Davies, James F., Ham, Dongwan, Song, Mijung, Zuend, Andreas, Li, Wentao, Tse, Ying-Lung Steve, and Chan, Man Nin

Abstract

Organic compounds residing near the surface of atmospheric aerosol particles are exposed to chemical reactions initiated by gas-phase oxidants, such as hydroxyl (OH) radicals. Aqueous droplets composed of inorganic salts and organic compounds can undergo phase separation into two liquid phases, depending on aerosol composition and relative humidity (RH). Such phase behavior can govern the surface characteristics and morphology of the aerosols, which in turn affect the heterogeneous reactivity of organic compounds toward gas-phase oxidants. In this work, we used an aerosol flow tube reactor coupled with an atmospheric pressure ionization source (Direct Analysis in Real Time) and a high-resolution mass spectrometer to investigate how phase separation in model aqueous droplets containing an inorganic salt (ammonium sulfate, AS) and an organic acid (3-methyglutaric acid, 3-MGA) with an organicto- inorganic dry mass ratio (OIR) of 1 alters the heterogeneous OH reactivity. At high RH, 3- MGA/AS aerosols were aqueous droplets with a single liquid phase. When the RH decreased, aqueous 3-MGA/AS droplets underwent phase separation at ~75% RH. Once the droplets were phase-separated, they exhibited either a core-shell, partially engulfed, 35 or a transition from core-shell to partially engulfed structure, with an organic-rich outer phase and an inorganicrich inner phase. The kinetics, quantified by an effective heterogenous OH rate constant, was found to increase gradually from 1.01 ± 0.02 × 10-12 to 1.73 ± 0.02 × 10-12 cm3 molecule-1 s-1 when the RH decreased from 88% to 55%. The heterogeneous reactivity of phase-separated droplets is slightly higher than that of aqueous droplets with a single liquid phase. This could be explained by the finding that when the RH decreases, higher concentrations of organic molecules (i.e. 3-MGA) are present at or near the droplet surface, which are more readily exposed to OH oxidation, as demonstrated by phase separation measurements and model simulations. This could increase the reactive collision probability between 3-MGA molecules and OH radicals dissolved near the droplet surface and secondary chain reactions. Even for phase-separated droplets with a fully established core-shell structure, the diffusion rate of organic molecules across the organic-rich outer shell is predicted to be fast in this system. Thus, the overall rate of reactions is likely governed by the surface concentration of 3-MGA rather than a diffusion limitation. Overall, understanding the aerosol phase state (single liquid phase versus two separate liquid phases) is essential to better probe the heterogenous reactivity under different aerosol chemical composition and environmental conditions (e.g. RH). [ABSTRACT FROM AUTHOR]

Published

2020

24. Liquid–liquid phase separation in secondary organic aerosol particles produced from α-pinene ozonolysis and α-pinene photooxidation with/without ammonia.

Author

Ham, Suhan, Babar, Zaeem Bin, Lee, Jae Bong, Lim, Ho-Jin, and Song, Mijung

Subjects

PINENE, PHOTOOXIDATION, PHASE separation

Abstract

Recently, liquid–liquid phase separation (LLPS) of secondary organic aerosol (SOA) particles free of inorganic salts has been intensively studied due to the importance of cloud condensation nuclei (CCN) properties. In this study, we investigated LLPS in four different types of SOA particles generated from α -pinene ozonolysis and α -pinene photooxidation in the absence and presence of ammonia (NH3). LLPS was observed in SOA particles produced from α -pinene ozonolysis at ∼95.8 % relative humidity (RH) and α -pinene ozonolysis with NH3 at ∼95.4 % RH. However, LLPS was not observed in SOA particles produced from α -pinene photooxidation and α -pinene photooxidation with NH3. Based on datasets of the average oxygen to carbon elemental ratio (O:C) for different types of SOA particles from this study and from previous studies, there appears to be a relationship between the occurrence of LLPS and the O:C of the SOA particles. When LLPS was observed, the two liquid phases were present up to ∼100 % RH. This result can help more accurately predict the CCN properties of organic aerosol particles. [ABSTRACT FROM AUTHOR]

Published

2019

25. Liquid-liquid phase separation in organic particles containing one and two organic species: importance of the average O:C.

Author

Song, Mijung, Ham, Suhan, Andrews, Ryan J., You, Yuan, and Bertram, Allan K.

Subjects

LIQUID-liquid transformations, HUMIDITY, NUCLEATION, ATMOSPHERE, CLOUD condensation nuclei

Abstract

Recently, experimental studies have shown that liquid-liquid phase separation (LLPS) can occur in organic particles free of inorganic salts. Most of these studies used organic particles consisting of secondary organic materials generated in environmental chambers. To gain additional insight into LLPS in organic particles free of inorganic salts, we studied LLPS in organic particles consisting of one and two commercially available organic species. For particles containing one organic species, three out of the six particle types investigated underwent LLPS. In these cases, LLPS was observed when the O:C was ≤ 0:44 (but not always) and the relative humidity (RH) was between ~ 97% and ~ 100%. The mechanism of phase separation was likely nucleation and growth. For particles containing two organic species, 13 out of the 15 particle types investigated underwent LLPS. In these cases, LLPS was observed when the O:C was ≤ 0:58 (but not always) and mostly when the RH was between ~ 90% RH and ~ 100% RH. The mechanism of phase separation was likely spinodal decomposition. In almost all cases when LLPS was observed (for both onecomponent and two-component particles), the highest RH at which two liquids was observed was 100±2:0%, which has important implications for the cloud condensation nuclei (CCN) properties of these particles. These combined results provide additional evidence that LLPS needs to be considered when predicting the CCN properties of organic particles in the atmosphere. [ABSTRACT FROM AUTHOR]

Published

2018

26. Effect of viscosity on photodegradation rates in complex secondary organic aerosol materials.

Author

Hinks, Mallory L., Brady, Monica V., Lignell, Hanna, Song, Mijung, Grayson, James W., Bertram, Allan K., Lin, Peng, Laskin, Alexander, Laskin, Julia, and Nizkorodov, Sergey A.

Abstract

This work explores the effect of environmental conditions on the photodegradation rates of atmospherically relevant, photolabile, organic molecules embedded in a film of secondary organic material (SOM). Three types of SOM were studied: α-pinene/O3 SOM (PSOM), limonene/O3 SOM (LSOM), and aged limonene/O3 obtained by exposure of LSOM to ammonia (brown LSOM). PSOM and LSOM were impregnated with 2,4-dinitrophenol (2,4-DNP), an atmospherically relevant molecule that photodegrades faster than either PSOM or LSOM alone, to serve as a probe of SOM matrix effects on photochemistry. Brown LSOM contains an unidentified chromophore that absorbs strongly at 510 nm and photobleaches upon irradiation. This chromophore served as a probe molecule for the brown LSOM experiments. In all experiments, either the temperature or relative humidity (RH) surrounding the SOM films was varied. The extent of photochemical reaction in the samples was monitored using UV-vis absorption spectroscopy. For all three model systems examined, the observed photodegradation rates were slower at lower temperatures and lower RH, conditions that make SOM more viscous. Additionally, the activation energies for photodegradation of each system were positively correlated with the viscosity of the SOM matrix as measured in poke-flow experiments. These activation energies were calculated to be 50, 24, and 17 kJ mol−1 for 2,4-DNP in PSOM, 2,4-DNP in LSOM, and the chromophore in brown LSOM, respectively, and PSOM was found to be the most viscous of the three. These results suggest that the increased viscosity is hindering the motion of the molecules in SOM and is slowing down their respective photochemical reactions. [ABSTRACT FROM AUTHOR]

Published

2016

27. Liquid–liquid phase separation in atmospherically relevant particles consisting of organic species and inorganic salts.

Author

You, Yuan, Smith, Mackenzie L., Song, Mijung, Martin, Scot T., and Bertram, Allan K.

Subjects

LIQUID-liquid extraction, HUMIDITY, PHASE separation, SULFATES, FUNCTIONAL groups, SALTING out (Chemistry), MORPHOLOGY

Abstract

Laboratory studies of liquid–liquid phase separation in particles containing organic species and inorganic salts of atmospheric relevance are reviewed. The oxygen-to-carbon elemental ratio (O:C) of the organic component appears to be the most useful parameter for estimating, to a first approximation, the occurrence of liquid–liquid phase separation and the separation relative humidity (SRH) in these particles. A trend of decreasing SRH for increasing O:C was found for simple organic–inorganic mixtures (<11 species). Phase separation in particles composed of laboratory-produced secondary organic material and sulphate species and in ambient particles is generally consistent with this trend. A further constraint is that liquid–liquid phase separation was always observed for O:C < 0.5 and was never observed for O:C ≥ 0.8. For organic materials of intermediate O:C ranging from 0.5 to 0.8, phase separation in simple organic–inorganic mixtures was influenced by the organic functional groups represented. The organic-to-inorganic mass ratio (OIR) affected the occurrence of liquid–liquid phase separation in a small number of cases. A dependence on salt type was observed with 87% of the studied organics exhibiting the following trend in SRH values: (NH4)2SO4 ≥ NH4HSO4 ≥ NaCl ≥ NH4NO3, consistent with previous salting-out studies and the Hofmeister series. Liquid–liquid phase separation does not appear to be strongly influenced by the number of species making up the organic material. The morphology of phase separated particles appears to depend on composition, including O:C of the organic material, the inorganic salt and the OIR. [ABSTRACT FROM PUBLISHER]

Published

2014

28. Morphologies of mixed organic/inorganic/aqueous aerosol droplets.

Author

Song, Mijung, Marcolli, Claudia, Krieger, Ulrich K., Lienhard, Daniel M., and Peter, Thomas

Abstract

Despite major progress in the understanding of properties of tropospheric aerosol particles, it remains challenging to understand their physical state and morphology. To obtain more detailed knowledge of the phases, phase transitions and morphologies of internally mixed organic/inorganic aerosol particles, we evaluated liquid–liquid phase separation (LLPS), deliquescence relative humidity (DRH) and efflorescence relative humidity (ERH) of 33 organic/ammonium sulfate (AS)/H2O systems from our own and literature data. The organic fraction consists of single compounds or mixtures with up to ten aliphatic and/or aromatic components with carboxylic acid, hydroxyl, carbonyl, ether, and ester functionalities, covering O : C ratios between 0.29 and 1.33. Thirteen out of these 33 systems did not show LLPS for any of the studied organic-to-inorganic mixing ratios, sixteen underwent LLPS showing core–shell morphology, and four showed both core–shell and partially engulfed configurations depending on the organic-to-inorganic ratio and RH. In all cases the organic fractions of the systems with partially engulfed configurations consisted of dicarboxylic acids. AS in mixed organic/AS/H2O particles deliquesced between 70 and 84% RH. AS effloresced below 58% RH or remained in a one-liquid-phase state. AS in droplets with LLPS always showed efflorescence with ERH between 30 and 50% RH, providing clear evidence that the presence of LLPS facilitates AS efflorescence. Spreading coefficients of the organic-rich phase on the AS-rich phase for systems containing polyethylene glycol 400 (PEG-400) and a mixture of dicarboxylic acids are in agreement with the optically observed morphologies of droplets deposited on the hydrophobic substrate. Analysis of high resolution elastic Mie resonance spectra allowed the detection of LLPS for single levitated droplets consisting of PEG-400/AS/H2O, whereas LLPS was difficult to detect in (2-methylglutaric acid + 3-methylglutaric acid + 2,2-dimethylsuccinic acid)/AS/H2O. Measured Mie spectra of PEG-400/AS/H2O at 93.5% and at 80.9% RH agreed with computed Mie spectra for a homogeneous and a core–shell configuration, respectively, confirming the results obtained from droplets deposited on a hydrophobic substrate. Based on the presented evidence, we therefore consider the core–shell morphology to be the prevalent configuration of liquid–liquid-phase-separated tropospheric organic/AS/H2O particles. [ABSTRACT FROM AUTHOR]

Published

2013

29. Contributions of Ammonia to High Concentrations of PM 2.5 in an Urban Area.

Author

Park, Junsu, Kim, Eunhye, Oh, Sangmin, Kim, Haeri, Kim, Soontae, Kim, Yong Pyo, and Song, Mijung

Subjects

ATMOSPHERIC ammonia, AMMONIA, AMMONIUM ions, HUMIDITY, THREE-dimensional modeling, LOW temperatures

Abstract

Atmospheric ammonia (NH3) plays a critical role in PM2.5 pollution. Data on atmospheric NH3 are scanty; thus, the role of NH3 in the formation of ammonium ions (NH4+) in various environments is understudied. Herein, we measured concentrations of NH3, PM2.5, and its water-soluble SO42−, NO3−, and NH4+ ions (SNA) at an urban site in Jeonju, South Korea from May 2019 to April 2020. During the measurement period, the average concentrations of NH3 and PM2.5 were 10.5 ± 4.8 ppb and 24.0 ± 12.8 μg/m3, respectively, and SNA amounted to 4.3 ± 3.1, 4.4 ± 4.9, and 1.6 ± 1.8 μg/m3, respectively. A three-dimensional photochemical model analysis revealed that a major portion of NH3, more than 88%, originated from Korea. The enhancement of the ammonium-to-total ratio of NH3, NHX (NHR = [NH4+]/[NH4+] + [NH3]) was observed up to ~0.61 during the increase of PM2.5 concentration (PM2.5 ≥ 25 μg/m3) under low temperature and high relative humidity conditions, particularly in winter. The PM2.5 and SNA concentrations increased exponentially as NHR increased, indicating that NH3 contributed significantly to SNA formation by gas-to-particle conversion. Our study provided experimental evidence that atmospheric NH3 in the urban area significantly contributed to SNA formation through gas-to-particle conversion during PM2.5 pollution episodes. [ABSTRACT FROM AUTHOR]

Published

2021

30. Spatial Distributions of Atmospheric Ammonia in a Rural Area in South Korea and the Associated Impact on a Nearby Urban Area.

Author

Oh, Sangmin, Kim, Seung-Gi, Lee, Jae Bong, Park, Junsu, Jee, Joon-Bum, Hong, Se-Woon, Kwon, Kyeong-Seok, and Song, Mijung

Subjects

ATMOSPHERIC ammonia, CITIES & towns, RURAL geography, PASSIVE sampling devices (Environmental sampling), RURAL conditions, SWINE farms

Abstract

Ammonia (NH3) plays an important role in air quality and atmospheric chemistry, yet studies on the characteristics and impacts of NH3 are limited. Herein, we revealed the spatial distribution of atmospheric NH3, as measured by passive samplers, at three different sites (R1, R2, and R3) in the rural area (livestock environment) of Jeongeup, South Korea, from September 2019 to August 2020. At site R1, the boundary of a large-scale pig farm, dramatically high daily mean concentrations of NH3 were observed (118.7 ppb), whereas sites R2 and R3, located ~1 km from R1, exhibited lower concentrations of 18.2 and 30.4 ppb, respectively. In the rural environment, the monthly NH3 variations showed a peak in June (34.2 ppb), which was significantly higher than in the urban and remote areas. To examine the impact of NH3 from the rural area on a nearby urban area in June 2020, simultaneous measurements were performed using a real-time instrument in Jeonju. When high NH3 events occurred in the urban area in June, the results for the NH3 concentrations and observed meteorological conditions in the rural and urban areas showed that the rural area influenced the NH3 levels in the adjacent urban area. [ABSTRACT FROM AUTHOR]

Published

2021

31. Origins and chemical characteristics of fine aerosols during the northeastern Asia regional experiment (Atmospheric Brown Cloud-East Asia Regional Experiment 2005).

Author

Lee, Meehye, Song, Mijung, Moon, Kwang J., Han, Jin S., Lee, Gangwoong, and Kim, Kyung-Ryul

Published

2007

32. Ammonia and Particulate Matter Emissions at a Korean Commercial Pig Farm and Influencing Factors.

Author

Choi LY, Lee SY, Jeong H, Park J, Hong SW, Kwon KS, and Song M

Abstract

Quantifying emission factors of ammonia and particulate matter (PM) in livestock production systems is crucial for assessing and mitigating the environmental impact of animal production and for ensuring industry sustainability. This study aimed to determine emission factors of ammonia, total suspended particles (TSPs), PM 10 , and PM 2.5 for piglets and growing-finishing pigs at a commercial pig farm in Korea. It also sought to identify factors influencing these emission factors. The research found that the emission factors measured were generally lower than those currently used in Korea, but were consistent with findings from individual research studies in the literature. Seasonal variations were observed, with ammonia emissions peaking in spring and autumn, and PM emissions rising in summer. Correlation analyses indicated that the number of animals and their average age correlated positively with both ammonia and PM emission factors. Ventilation rate was also positively correlated with PM emissions. Future extended field measurements across diverse pig farms will offer deeper insights into the emission factors of pig farms in Korea, guiding the development of sustainable livestock management practices.

Published

2023

33. Comparison of Phase States of PM 2.5 over Megacities, Seoul and Beijing, and Their Implications on Particle Size Distribution.

Author

Song M, Jeong R, Kim D, Qiu Y, Meng X, Wu Z, Zuend A, Ha Y, Kim C, Kim H, Gaikwad S, Jang KS, Lee JY, and Ahn J

Subjects

Beijing, Cities, Particle Size, Seoul, Environmental Monitoring methods, Seasons, Water, Aerosols analysis, China, Particulate Matter analysis, Air Pollutants analysis

Abstract

Although the particle phase state is an important property, there is scant information on it, especially, for real-world aerosols. To explore the phase state of fine mode aerosols (PM 2.5 ) in two megacities, Seoul and Beijing, we collected PM 2.5 filter samples daily from Dec 2020 to Jan 2021. Using optical microscopy combined with the poke-and-flow technique, the phase states of the bulk of PM 2.5 as a function of relative humidity (RH) were determined and compared to the ambient RH ranges in the two cities. PM 2.5 was found to be liquid to semisolid in Seoul but mostly semisolid to solid in Beijing. The liquid state was dominant on polluted days, while a semisolid state was dominant on clean days in Seoul. These findings can be explained by the aerosol liquid water content related to the chemical compositions of the aerosols at ambient RH; the water content of PM 2.5 was much higher in Seoul than in Beijing. Furthermore, the overall phase states of PM 2.5 observed in Seoul and Beijing were interrelated with the particle size distribution. The results of this study aid in a better understanding of the fundamental physical properties of aerosols and in examining how these are linked to PM 2.5 in polluted urban atmospheres.

Published

2022

34. Maternal exposure to fine particulate matter during pregnancy induces progressive senescence of hematopoietic stem cells under preferential impairment of the bone marrow microenvironment and aids development of myeloproliferative disease.

Author

Bhattarai G, Lee JB, Kim MH, Ham S, So HS, Oh S, Sim HJ, Lee JC, Song M, and Kook SH

Subjects

Age Factors, Animals, Bone Marrow drug effects, Female, Hematopoietic Stem Cells drug effects, Myeloproliferative Disorders chemically induced, Pregnancy, Bone Marrow pathology, Cellular Senescence, Hematopoietic Stem Cells pathology, Maternal Exposure adverse effects, Myeloproliferative Disorders pathology, Particulate Matter toxicity

Published

2020