Observations of inorganic bromine (HOBr, BrO, and Br2) speciation at Barrow, Alaska, in spring 2009. Liao, J., Huey, L., G., Tanner, D., J., Flocke, F., M., Orlando, J., J., Neuman, J., A., Nowak, J., B., Weinheimer, A., J., Hall, S., R., Smith, J., N., Fried, A., Staebler, R., M., Wang, Y., Koo, J., H., Cantrell, C., A., Weibring, P., Walega, J., Knapp, D., J., Shepson, P., B., & Stephens, C., R. Journal of Geophysical Research Atmospheres, 117(6):n/a-n/a, 7, 2012.
Observations of inorganic bromine (HOBr, BrO, and Br2) speciation at Barrow, Alaska, in spring 2009 [link]Website  doi  abstract   bibtex   
Inorganic bromine plays a critical role in ozone and mercury depletions events (ODEs and MDEs) in the Arctic marine boundary layer. Direct observations of bromine species other than bromine oxide (BrO) during ODEs are very limited. Here we report the first direct measurements of hypobromous acid (HOBr) as well as observations of BrO and molecular bromine (Br2) by chemical ionization mass spectrometry at Barrow, Alaska in spring 2009 during the Ocean-Atmospheric-Sea Ice-Snowpack (OASIS) campaign. Diurnal profiles of HOBr with maximum concentrations near local noon and no significant concentrations at night were observed. The measured average daytime HOBr mixing ratio was 10 pptv with a maximum value of 26 pptv. The observed HOBr was reasonably well correlated (R2 = 0.57) with predictions from a simple steady state photochemical model constrained to observed BrO and HO2 at wind speeds <6 m s−1. However, predicted HOBr levels were considerably higher than observations at higher wind speeds. This may be due to enhanced heterogeneous loss of HOBr on blowing snow coincident with higher wind speeds. BrO levels were also found to be higher at elevated wind speeds. Br2 was observed in significant mixing ratios (maximum = 46 pptv; average = 13 pptv) at night and was strongly anti-correlated with ozone. The diurnal speciation of observed gas phase inorganic bromine species can be predicted by a time-dependent box model that includes efficient heterogeneous recycling of HOBr, hydrogen bromide (HBr), and bromine nitrate (BrONO2) back to more reactive forms of bromine.
@article{
 title = {Observations of inorganic bromine (HOBr, BrO, and Br2) speciation at Barrow, Alaska, in spring 2009},
 type = {article},
 year = {2012},
 pages = {n/a-n/a},
 volume = {117},
 websites = {http://doi.wiley.com/10.1029/2011JD016641},
 month = {7},
 day = {27},
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 last_modified = {2023-01-31T22:46:06.157Z},
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 citation_key = {Liao2012},
 source_type = {Journal Article},
 notes = {<b>From Duplicate 1 (<i>Observations of inorganic bromine (HOBr, BrO, and Br2) speciation at Barrow, Alaska, in spring 2009</i> - Liao, J.; Huey, L. G.; Tanner, D. J.; Flocke, F. M.; Orlando, J. J.; Neuman, J. A.; Nowak, J. B.; Weinheimer, A. J.; Hall, S. R.; Smith, J. N.; Fried, A.; Staebler, R. M.; Wang, Y.; Koo, J. H.; Cantrell, C. A.; Weibring, P.; Walega, J.; Knapp, D. J.; Shepson, P. B.; Stephens, C. R.)<br/></b><br/>Times Cited: 2<br/>Liao, J. Huey, L. G. Tanner, D. J. Flocke, F. M. Orlando, J. J. Neuman, J. A. Nowak, J. B. Weinheimer, A. J. Hall, S. R. Smith, J. N. Fried, A. Staebler, R. M. Wang, Y. Koo, J-H. Cantrell, C. A. Weibring, P. Walega, J. Knapp, D. J. Shepson, P. B. Stephens, C. R.<br/><br/><b>From Duplicate 2 (<i>Observations of inorganic bromine (HOBr, BrO, and Br2) speciation at Barrow, Alaska, in spring 2009</i> - Liao, J.; Huey, L. G.; Tanner, D. J.; Flocke, F. M.; Orlando, J. J.; Neuman, J. A.; Nowak, J. B.; Weinheimer, A. J.; Hall, S. R.; Smith, J. N.; Fried, A.; Staebler, R. M.; Wang, Y.; Koo, J. H.; Cantrell, C. A.; Weibring, P.; Walega, J.; Knapp, D. J.; Shepson, P. B.; Stephens, C. R.)<br/></b><br/><b>From Duplicate 1 (<i>Observations of inorganic bromine (HOBr, BrO, and Br2) speciation at Barrow, Alaska, in spring 2009</i> - Liao, J.; Huey, L. G.; Tanner, D. J.; Flocke, F. M.; Orlando, J. J.; Neuman, J. A.; Nowak, J. B.; Weinheimer, A. J.; Hall, S. R.; Smith, J. N.; Fried, A.; Staebler, R. M.; Wang, Y.; Koo, J. H.; Cantrell, C. A.; Weibring, P.; Walega, J.; Knapp, D. J.; Shepson, P. B.; Stephens, C. R.)<br/></b><br/>Times Cited: 2 Liao, J. Huey, L. G. Tanner, D. J. Flocke, F. M. Orlando, J. J. Neuman, J. A. Nowak, J. B. Weinheimer, A. J. Hall, S. R. Smith, J. N. Fried, A. Staebler, R. M. Wang, Y. Koo, J-H. Cantrell, C. A. Weibring, P. Walega, J. Knapp, D. J. Shepson, P. B. Stephens, C. R.<br/><br/><b>From Duplicate 2 (<i>Observations of inorganic bromine (HOBr, BrO, and Br-2) speciation at Barrow, Alaska, in spring 2009</i> - Liao, J; Huey, L G; Tanner, D J; Flocke, F M; Orlando, J J; Neuman, J A; Nowak, J B; Weinheimer, A J; Hall, S R; Smith, J N; Fried, A; Staebler, R M; Wang, Y; Koo, J H; Cantrell, C A; Weibring, P; Walega, J; Knapp, D J; Shepson, P B; Stephens, C R)<br/></b><br/>Times Cited: 2<br/>Liao, J. Huey, L. G. Tanner, D. J. Flocke, F. M. Orlando, J. J. Neuman, J. A. Nowak, J. B. Weinheimer, A. J. Hall, S. R. Smith, J. N. Fried, A. Staebler, R. M. Wang, Y. Koo, J-H. Cantrell, C. A. Weibring, P. Walega, J. Knapp, D. J. Shepson, P. B. Stephens, C. R.},
 private_publication = {false},
 abstract = {Inorganic bromine plays a critical role in ozone and mercury depletions events (ODEs and MDEs) in the Arctic marine boundary layer. Direct observations of bromine species other than bromine oxide (BrO) during ODEs are very limited. Here we report the first direct measurements of hypobromous acid (HOBr) as well as observations of BrO and molecular bromine (Br2) by chemical ionization mass spectrometry at Barrow, Alaska in spring 2009 during the Ocean-Atmospheric-Sea Ice-Snowpack (OASIS) campaign. Diurnal profiles of HOBr with maximum concentrations near local noon and no significant concentrations at night were observed. The measured average daytime HOBr mixing ratio was 10 pptv with a maximum value of 26 pptv. The observed HOBr was reasonably well correlated (R2 = 0.57) with predictions from a simple steady state photochemical model constrained to observed BrO and HO2 at wind speeds <6 m s−1. However, predicted HOBr levels were considerably higher than observations at higher wind speeds. This may be due to enhanced heterogeneous loss of HOBr on blowing snow coincident with higher wind speeds. BrO levels were also found to be higher at elevated wind speeds. Br2 was observed in significant mixing ratios (maximum = 46 pptv; average = 13 pptv) at night and was strongly anti-correlated with ozone. The diurnal speciation of observed gas phase inorganic bromine species can be predicted by a time-dependent box model that includes efficient heterogeneous recycling of HOBr, hydrogen bromide (HBr), and bromine nitrate (BrONO2) back to more reactive forms of bromine.},
 bibtype = {article},
 author = {Liao, J. and Huey, L. G. and Tanner, D. J. and Flocke, F. M. and Orlando, J. J. and Neuman, J. A. and Nowak, J. B. and Weinheimer, A. J. and Hall, S. R. and Smith, J. N. and Fried, A. and Staebler, R. M. and Wang, Y. and Koo, J. H. and Cantrell, C. A. and Weibring, P. and Walega, J. and Knapp, D. J. and Shepson, P. B. and Stephens, C. R.},
 doi = {10.1029/2011jd016641},
 journal = {Journal of Geophysical Research Atmospheres},
 number = {6}
}
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