Implications of iodine chemistry for daytime HO2 levels at Rishiri Island

Yugo Kanaya; Yoko Yokouchi; Jun Matsumoto; Kenji Nakamura; Shungo Kato; Hiroshi Tanimoto; Hiroshi Furutani; Kenjiro Toyota; Hajime Akimoto

doi:10.1029/2001gl014061

Implications of iodine chemistry for daytime HO₂ levels at Rishiri Island

Yugo Kanaya^*, Yoko Yokouchi, Jun Matsumoto, Kenji Nakamura, Shungo Kato, Hiroshi Tanimoto, Hiroshi Furutani, Kenjiro Toyota, Hajime Akimoto

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

35 Citations (Scopus)

Abstract

The observed midday maximum in the mixing ratio of HO₂ at Rishiri Island in June 2000 was ∼10 pptv, but photochemical box model simulations overpredicted HO₂ at this location by an average of 70%. This overestimation was significant only when the mixing ratio of NO was lower than 300 pptv, and was coincident with overprediction of the NO/NO₂ ratio. We detected several organoiodines, presumably emitted from seaweeds, and propose the presence of the IO radical. IO could reduce HO₂ mixing ratios via the formation of HOI that may subsequently be scavenged by aerosols or lost by photolysis and may also convert NO to NO₂ directly. Model calculations with known iodine chemistry could reproduce the observed HO₂ with 12-25 pptv of 10. Although iodine chemistry is unlikely to explain the entire discrepancy in HO₂, several pptv of IO could significantly reduce HO₂ mixing ratios and NO/No₂ ratios.

Original language	English
Pages (from-to)	53-1 - 53-4
Journal	Geophysical Research Letters
Volume	29
Issue number	8
DOIs	https://doi.org/10.1029/2001gl014061
Publication status	Published - 2002 Apr 15
Externally published	Yes

ASJC Scopus subject areas

Geophysics
Earth and Planetary Sciences(all)

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10.1029/2001gl014061

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title = "Implications of iodine chemistry for daytime HO2 levels at Rishiri Island",

abstract = "The observed midday maximum in the mixing ratio of HO2 at Rishiri Island in June 2000 was ∼10 pptv, but photochemical box model simulations overpredicted HO2 at this location by an average of 70%. This overestimation was significant only when the mixing ratio of NO was lower than 300 pptv, and was coincident with overprediction of the NO/NO2 ratio. We detected several organoiodines, presumably emitted from seaweeds, and propose the presence of the IO radical. IO could reduce HO2 mixing ratios via the formation of HOI that may subsequently be scavenged by aerosols or lost by photolysis and may also convert NO to NO2 directly. Model calculations with known iodine chemistry could reproduce the observed HO2 with 12-25 pptv of 10. Although iodine chemistry is unlikely to explain the entire discrepancy in HO2, several pptv of IO could significantly reduce HO2 mixing ratios and NO/No2 ratios.",

author = "Yugo Kanaya and Yoko Yokouchi and Jun Matsumoto and Kenji Nakamura and Shungo Kato and Hiroshi Tanimoto and Hiroshi Furutani and Kenjiro Toyota and Hajime Akimoto",

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AU - Kanaya, Yugo

AU - Yokouchi, Yoko

AU - Matsumoto, Jun

AU - Nakamura, Kenji

AU - Kato, Shungo

AU - Tanimoto, Hiroshi

AU - Furutani, Hiroshi

AU - Toyota, Kenjiro

AU - Akimoto, Hajime

PY - 2002/4/15

Y1 - 2002/4/15

N2 - The observed midday maximum in the mixing ratio of HO2 at Rishiri Island in June 2000 was ∼10 pptv, but photochemical box model simulations overpredicted HO2 at this location by an average of 70%. This overestimation was significant only when the mixing ratio of NO was lower than 300 pptv, and was coincident with overprediction of the NO/NO2 ratio. We detected several organoiodines, presumably emitted from seaweeds, and propose the presence of the IO radical. IO could reduce HO2 mixing ratios via the formation of HOI that may subsequently be scavenged by aerosols or lost by photolysis and may also convert NO to NO2 directly. Model calculations with known iodine chemistry could reproduce the observed HO2 with 12-25 pptv of 10. Although iodine chemistry is unlikely to explain the entire discrepancy in HO2, several pptv of IO could significantly reduce HO2 mixing ratios and NO/No2 ratios.

AB - The observed midday maximum in the mixing ratio of HO2 at Rishiri Island in June 2000 was ∼10 pptv, but photochemical box model simulations overpredicted HO2 at this location by an average of 70%. This overestimation was significant only when the mixing ratio of NO was lower than 300 pptv, and was coincident with overprediction of the NO/NO2 ratio. We detected several organoiodines, presumably emitted from seaweeds, and propose the presence of the IO radical. IO could reduce HO2 mixing ratios via the formation of HOI that may subsequently be scavenged by aerosols or lost by photolysis and may also convert NO to NO2 directly. Model calculations with known iodine chemistry could reproduce the observed HO2 with 12-25 pptv of 10. Although iodine chemistry is unlikely to explain the entire discrepancy in HO2, several pptv of IO could significantly reduce HO2 mixing ratios and NO/No2 ratios.

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Implications of iodine chemistry for daytime HO₂ levels at Rishiri Island

Abstract

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