Organic and inorganic components of aerosols over the central Himalayas: winter and summer variations in stable carbon and nitrogen isotopic composition

Hegde, Prashant; Kawamura, Kimitaka; Joshi, Himanshu; Naja, Manish

doi:10.1007/s11356-015-5530-3

Cited by 39 publications

(25 citation statements)

References 107 publications

(109 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Ca 2+ was commonly derived from soil or crustal dust and construction activities (Hegde et al, 2016). Ca 2+ in Wuhan showed slightly higher value in winter and spring than those in summer and fall, similar to previous studies (Zhao et al, 2010;He et al, 2012).…”

Section: General Characteristic Of Wsi In Wuhansupporting

confidence: 89%

“…Higher Clconcentrations were measured in winter (2.87±1.25 μg m -3 ), approximately two or three times than those in other seasons. The Na + /Clratio in winter (0.09) was obviously lower than that of seawater (0.557) (Hegde et al, 2016), reflecting the dominance of other sources for Clinstead of sea salt. The weak correlation (R 2 = 0.20, p <0.05) between Cland Na + verified this.…”

Section: General Characteristic Of Wsi In Wuhanmentioning

confidence: 86%

See 1 more Smart Citation

Aerosol acidity in a megacity with high ambient temperature and relative humidity of Central China: temporal variation, determining factors and pollution transition effect

Zheng

Kong

Bao

et al. 2018

Preprint

View full text Add to dashboard Cite

Abstract. Aerosol acidity affects the chemical transformation of aerosols and subsequent haze formation. High resolution (1-h) observation of water-soluble inorganic ions in fine particles, gaseous pollutants, and meteorological parameters was conducted from September 2015 to August 2016 at Wuhan, a megacity of Central China with high relative humidity and ambient temperature, compared with north Chinese cities. By adopting thermodynamic model ISOROPPIA-II, the aerosol acidity for different time scales, pollution episodes, and air mass directions was calculated. Aerosols in Wuhan were moderate acidic, with pH averaged as 3.30&plusmn;0.49. The aerosol acidity was higher in July (pH as 2.64&plusmn;0.31), September (pH as 2.75&plusmn;0.30) and August (pH as 2.79&plusmn;0.29), and lower in January (pH as 3.77&plusmn;0.28) and March (pH as 3.70&plusmn;0.16). It decreased with the air pollution increasing, with the pH values of 3.07&plusmn;0.45, 3.63&plusmn;0.27 and 3.84&plusmn;0.22 for clean, transition and polluted episodes, respectively. The air masses in Wuhan transported from North China exhibited higher aerosol acidity, with pH averaged as 3.17&ndash;3.22. The unique environmental and meteorological conditions (high humidity, annual averaged RH as 0.74&plusmn;0.13) lead to excess ammonium (on average of 6.06&plusmn;4.51&mu;gm&minus;3) and abundant aerosol water content (AWC, on average of 71.0&plusmn;82.8&mu;gm&minus;3) in Wuhan, which can explain the lower PM2.5 acidity in Wuhan than other megacities of China. At lower AWC level (less than ~15&mu;gm&minus;3), the particle pH showed a decreasing trend with AWC increased. When the AWC continuous increased from ~15 to ~380&mu;gm&minus;3, there was an obvious increase of particle pH. Then no significant growth of pH was found when AWC was higher than ~380&mu;gm&minus;3. With atmospheric RH increasing, the aerosol pH exhibited decreasing trend firstly and then increased, with the turning point RH as about 0.48. There was a logarithmic growth of aerosol pH with total NHx (NH3+NH4+) increasing. From the fitted logarithmic curve, the aerosol pH of Wuhan was at the range of pH rapid growth stage with NHx increasing, indicating that the control of ammonia emission in Wuhan could be an effective way to reduce the aerosol pH and further mitigate air pollution. This paper firstly obtained the aerosol acidity properties at a megacity under abundant ammonium and high humidity with high time-resolution, which is an important supplementary for the current aerosol acidity research around the world.

show abstract

Section: General Characteristic Of Wsi In Wuhansupporting

confidence: 89%

Section: General Characteristic Of Wsi In Wuhanmentioning

confidence: 86%

Aerosol acidity in a megacity with high ambient temperature and relative humidity of Central China: temporal variation, determining factors and pollution transition effect

Zheng

Kong

Bao

et al. 2018

Preprint

View full text Add to dashboard Cite

show abstract

“…The bulk δ 15 N in atmospheric particulates is mainly determined by the δ 15 N of N precursors (Aggarwal et al, 2013;Hegde et al, 2015). Often, reported δ 15 N values of typical inorganic N sources (Table 1) can be used in studies on sources and fates of atmospheric N (Elliott et al, , 2009Kendall et al, 2007;Kawashima and Kurahashi, 2011;Michalski et al, 2014).…”

Section: Study Sitesmentioning

confidence: 99%

“…δ 15 N values) have been used to trace major sources and processes of atmospheric N (Heaton, 1986;Michalski et al, 2004;Kendall et al, 2007;Pavuluri et al, 2010;Savarino et al, 2013). The analysis of bulk δ 15 N in PM 2.5 is a quick method compared to δ 15 N measurements of inorganic and organic N components (Widory, 2007;Hegde et al, 2015;Bikkina et al, 2016), and it does also provide valuable information on δ 15 N of dry N deposition (Yeatman et al, 2001a; than that in rain NH + 4 and gaseous NH 3 (Yeatman et al, 2001a(Yeatman et al, , 2001bJia and Chen 2010;Felix et al, 2013). In a hypothetical model by Heaton et al (1997), the δ 15 N of particulate NH + 4 stabilized at values of 33‰ (an enrichment coefficient) higher than that of NH 3 when NH 3 ↔ NH + 4 equilibrium was achieved at 25 °C.…”

Section: Introductionmentioning

confidence: 99%

Source appointment of nitrogen in PM2.5 based on bulk δ15N signatures and a Bayesian isotope mixing model

Wang

Liu

Song

et al. 2017

Tellus B: Chemical and Physical Meteorology

View full text Add to dashboard Cite

2017) Source appointment of nitrogen in PM 2.5 based on bulk δ 15 N signatures and a Bayesian isotope mixing model, Tellus B:ABSTRACT Nitrogen isotope (δ 15 N) has been employed to differentiate major sources of atmospheric N. However, it remains a challenge to quantify contributions of multiple sources based on δ 15 N values of the N mixture in atmospheric samples. This study measured δ 15 N of bulk N in PM 2.5 at an urban site of Beijing during a severe haze episode of 22-30 January 2013 and a background site of Qinghai, north-western China from 6 September to 15 October 2013, then applied a Bayesian isotope mixing model (SIAR, Stable Isotope Analysis in R) to analyse the N sources. At Beijing site, δ 15 N values of PM 2.5 (−4.1‰ to +13.5‰, +2.8 ± 6.4‰) were distributed within the range of major anthropogenic sources (including NH 3 and NO 2 from coal combustion, vehicle exhausts and domestic wastes/sewage). At Menyuan site, δ 15 N values of PM 2.5 (+8.0‰ to +27.9‰, +18.5 ± 5.8‰) were significantly higher than that of potential sources (including NH 3 and NO 2 from biomass burning, animal wastes, soil N cycle, fertilizer application and dust N). High molar ratios of NH + 4 to NO − 3 and/or SO 2− 4 in PM 2.5 at the background site suggested that the equilibrium of NH 3 ↔ NH + 4 caused apparent 15 N enrichments in ammonium. Results of the SIAR model showed that 39 and 32% of bulk N in PM 2.5 of Beijing site were contributed from N emissions of coal combustion and vehicle exhausts, respectively, whereas N in PM 2.5 at Menyuan site was derived mainly from N emissions of biomass burning (46%) and NH 3 volatilization (34%). These results revealed that the stoichiometry between NH 3 and acidic gases plays an important role in controlling the bulk δ 15 N signatures of PM 2.5 and emissions of reactive N from coal combustion and urban transportation should be strictly controlled to advert the risk of haze episodes in Beijing.

show abstract

“…However, Hegde et al (2016) analyzed aerosols from the Himalayas (generally seen as being remote from contaminated sites) and found some worrying results. The carbon and nitrogen contents and isotopic signatures showed anthropogenic influences.…”

Section: Other Anthropogenic Contamination Scenariosmentioning

confidence: 99%

Characterization and remediation of contamination: the influences of mining and other human activities

Higueras

Sáez‐Martínez

Reyes-Bozo

2016

Environ Sci Pollut Res

View full text Add to dashboard Cite

Organic and inorganic components of aerosols over the central Himalayas: winter and summer variations in stable carbon and nitrogen isotopic composition

Cited by 39 publications

References 107 publications

Aerosol acidity in a megacity with high ambient temperature and relative humidity of Central China: temporal variation, determining factors and pollution transition effect

Aerosol acidity in a megacity with high ambient temperature and relative humidity of Central China: temporal variation, determining factors and pollution transition effect

Source appointment of nitrogen in PM<sub>2.5</sub> based on bulk δ<sup>15</sup>N signatures and a Bayesian isotope mixing model

Characterization and remediation of contamination: the influences of mining and other human activities

Contact Info

Product

Resources

About