Chlorine Deficiency in Coastal Aerosols

Okada, Kikuo; Ishizaka, Yutaka; Masuzawa, Toshiyuk; Isono, K.

doi:10.2151/jmsj1965.56.5_501

Cited by 15 publications

(6 citation statements)

References 17 publications

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“…The first Cl peak occurs in late evening April 24 near the temperature minimum and corresponds to gentle westerly winds and S and Fe, but not CNC, peaks. This Cl is more difficult to explain, but one possible hypothesis is that it is related to a lesser acidity of the air mass inhibiting gaseous Cl evolution from aerosols as may occur by, for example, reaction with H2SO4 and HNO3 [Okada et al, 1978]. The S aerosol concentration would not be sensitive to such conditions but would exist to a greater extent as a salt, such as (NH4)2SO4, and would still track the Fe concentration as it typically does during much of this sampling period.…”

Section: Moreover Higher Frequency Variations Of Cnc and B450 Are Somentioning

confidence: 99%

Aerosol characteristics at Mauna Loa Observatory, Hawaii, after east Asian dust storm episodes

Darzi¹,

Winchester²

1982

J. Geophys. Res.

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Concentrations of elements, including S, Al, Si, K, Ca, Ti, and Fe, in aerosols sampled sequentially with 3.7‐hour time resolution over a 2‐week period in April and May 1979 at the Mauna Loa Observatory, Hawaii, indicate that long‐range transported ‘background’ crustal dust aerosol can reach concentrations in excess of 20 μg m−3 with more than 8μg m−3 of additional sulfate. Favorable regional meteorology after known dust storm episodes, as well as similarities in crustal element ratios, point to dry areas of northern China as the major source region for this crustal aerosol. Time series analyses for crustal elements show a dominant 21‐hour but no 24‐hour period, a result that can be accounted for by a diurnally varying source process with subsequent modification of periodicity, e.g., by wind speed convergence during transport. Time‐dependent associations between S and the crustal elements, especially high coherency at long periodicities, also imply a long‐range transport for much of the S, possibly from populated areas in eastern Asia, including China and Japan. This source may contribute much of the sulfuric acid believed to cause the relatively high acidity of rainwater observed at higher altitudes in Hawaii. Mauna Loa Observatory, at 3400 m altitude, is apparently an excellent location for detecting Asian dust and pollutant transport during spring with little interference from Hawaii‐derived aerosol.

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Section: Moreover Higher Frequency Variations Of Cnc and B450 Are Somentioning

confidence: 99%

Aerosol characteristics at Mauna Loa Observatory, Hawaii, after east Asian dust storm episodes

Darzi¹,

Winchester²

1982

J. Geophys. Res.

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“…The modification of sea-salt particles has been of interest in connection with the origin of atmospheric gaseous chlorine in the field of air chemistry (e.g., Oddie, 1959;Junge, 1956Junge, , 1963Martens et al, 1973;van de Vate et al, 1978;Okada et al, 1978Okada et al, , 1989. Junge (1963) reviewed that the Cl/Na ratios in rainwater were always smaller than that in seawater.…”

Section: Introductionmentioning

confidence: 99%

The Effect of Continental Air Mass on the Modification of Individual Sea-Salt Particles Collected over the Coast and the Open Sea

Miura

Kumakura

Sekikawa

1991

Journal of the Meteorological Society of Japan

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“…Because the NO 3 − /Na + concentration ratio in surface seawater is <0.001 [ James , 2005], high NO 3 − /Na + ratios (0.01–1.03) observed in coarse particles suggest that most of the NO 3 − in coarse particles was added from the atmosphere and derived from nonsea‐salt compounds [ Parungo et al , 1986; Mamane and Mehler , 1987; Pósfai et al , 1995; Hara et al , 1999; Zhuang et al , 1999; Pryor and Sørensen , 2000]. Similarly, absorption and subsequent oxidation of SO 2 injects additional SO 4 2− to coarse SSA particles as nss‐SO 4 2− [ Okada et al , 1978; Parungo et al , 1986; McInnes et al , 1994; Pósfai et al , 1995; Buseck and Pósfai , 1999]. Although the HNO 3 concentration in the atmosphere was almost the same or lower than SO 2 , the NO 3 − concentration found in coarse particles was more than four times higher than that of nss‐SO 4 2− in most samples (Figure 4).…”

Section: Resultsmentioning

confidence: 99%

“…Sea salt aerosol particles derived from the ocean constitute the major component of the total aerosol mass in the lower atmosphere [ Andreae , 1995]. Sea salt aerosol particles (SSA particles) are often modified by various acidic gases such as HNO 3 and SO 2 [ Okada et al , 1978; Parungo et al , 1986; Mamane and Mehler , 1987; McInnes et al , 1994; Pósfai et al , 1995; Pio and Lopes , 1998; Buseck and Pósfai , 1999; Hara et al , 1999; Zhuang et al , 1999; Spokes et al , 2000; Rossi , 2003]. Because supermicrometer SSA particles are quickly deposited onto the Earth's surface or are returned to the ocean, once they are absorbed and react with acidic gases, they carry nonsea‐salt (nss) components, such as NO 3 − and nss‐SO 4 2− , from the atmosphere to Earth's surface.…”

Section: Introductionmentioning

confidence: 99%

Factors controlling sea salt modification and dry deposition of nonsea‐salt components to the ocean

Kawakami¹,

Osada²,

Nishita³

et al. 2008

J. Geophys. Res.

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[1] Modification of sea salt aerosol particles (SSA particles) by HNO 3 and SO 2 is an important process for changing phase partitioning of acidic gases from industrial regions to the ocean. During 12-29 September 2005, size-segregated aerosol particles and acidic gases were sampled around the western part of the Japanese Islands to elucidate controlling factors of modification of SSA particles by acidic gases and to estimate dry deposition flux over the ocean. For coarse (>2 mm diameter) SSA particles, the amount of Cl À deficiency from the seawater ratio was comparable to the sum of the equivalent concentrations of NO 3 À and nonsea-salt (nss) SO 4 2À , suggesting Cl À displacement of SSA particles by acidic gases such as HNO 3 and SO 2 . The Cl À deficiency of SSA particles varied according to the size range and wind speed. Decreasing modification occurred with increasing wind speed for particles of 2-8 mm. Under high (low) wind conditions, the NO 3 À concentration per unit surface area of coarse SSA particles was lower (higher) for particles >8 mm than for those of 2-8 mm diameter. The respective dry deposition fluxes (F dry ) of NO 3 À , nss-SO 4 2À , HNO 3 , and SO 2 were estimated according to the wind speed and size of aerosol particles. On average, the F dry of particulate NO 3 À was 10 times larger than that of HNO 3 , but F dry of nss-SO 4 2À was almost equal to that of SO 2 . Phase partitioning of dry deposition for NO 3 À and nss-SO 4 2À over the ocean differs from that of coastal marine areas.Citation: Kawakami, N., K. Osada, C. Nishita, M. Yabuki, H. Kobayashi, K. Hara, and M. Shiobara (2008), Factors controlling sea salt modification and dry deposition of nonsea-salt components to the ocean,

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Chlorine Deficiency in Coastal Aerosols

Cited by 15 publications

References 17 publications

Aerosol characteristics at Mauna Loa Observatory, Hawaii, after east Asian dust storm episodes

Aerosol characteristics at Mauna Loa Observatory, Hawaii, after east Asian dust storm episodes

The Effect of Continental Air Mass on the Modification of Individual Sea-Salt Particles Collected over the Coast and the Open Sea

Factors controlling sea salt modification and dry deposition of nonsea‐salt components to the ocean

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