Urban emissions of water vapor in winter
Elevated water vapor (H2Ov) mole fractions were occasionally observed downwind of Indianapolis, IN, and the Washington, D.C.‐Baltimore, MD, area during airborne mass balance experiments conducted during winter months between 2012 and 2015. On days when an urban H2Ov excess signal was observed, H2Ov...
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Archīum Ateneo
2017
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ph-ateneo-arc.physics-faculty-pubs-10342020-05-04T05:26:20Z Urban emissions of water vapor in winter Salmon, Olivia E Shepson, Paul B Ren, Xinrong Marquardt Collow, Allison B Miller, Mark A Carlton, Annmarie G Cambaliza, Maria Obiminda L Heimburger, Alexie M F Morgan, Kristan L Fuentes, Jose D Stirm, Brian H Grundman, Robert, II Dickerson, Russell R Elevated water vapor (H2Ov) mole fractions were occasionally observed downwind of Indianapolis, IN, and the Washington, D.C.‐Baltimore, MD, area during airborne mass balance experiments conducted during winter months between 2012 and 2015. On days when an urban H2Ov excess signal was observed, H2Ov emission estimates range between 1.6 × 104 and 1.7 × 105 kg s−1 and account for up to 8.4% of the total (background + urban excess) advected flow of atmospheric boundary layer H2Ov from the urban study sites. Estimates of H2Ov emissions from combustion sources and electricity generation facility cooling towers are 1–2 orders of magnitude smaller than the urban H2Ov emission rates estimated from observations. Instances of urban H2Ov enhancement could be a result of differences in snowmelt and evaporation rates within the urban area, due in part to larger wintertime anthropogenic heat flux and land cover differences, relative to surrounding rural areas. More study is needed to understand why the urban H2Ov excess signal is observed on some days, and not others. Radiative transfer modeling indicates that the observed urban enhancements in H2Ov and other greenhouse gas mole fractions contribute only 0.1°C d−1 to the urban heat island at the surface. This integrated warming through the boundary layer is offset by longwave cooling by H2Ov at the top of the boundary layer. While the radiative impacts of urban H2Ov emissions do not meaningfully influence urban heat island intensity, urban H2Ov emissions may have the potential to alter downwind aerosol and cloud properties. 2017-08-17T07:00:00Z text https://archium.ateneo.edu/physics-faculty-pubs/35 https://agupubs.onlinelibrary.wiley.com/doi/10.1002/2016JD026074 Physics Faculty Publications Archīum Ateneo Atmospheric Sciences |
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Atmospheric Sciences Salmon, Olivia E Shepson, Paul B Ren, Xinrong Marquardt Collow, Allison B Miller, Mark A Carlton, Annmarie G Cambaliza, Maria Obiminda L Heimburger, Alexie M F Morgan, Kristan L Fuentes, Jose D Stirm, Brian H Grundman, Robert, II Dickerson, Russell R Urban emissions of water vapor in winter |
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Elevated water vapor (H2Ov) mole fractions were occasionally observed downwind of Indianapolis, IN, and the Washington, D.C.‐Baltimore, MD, area during airborne mass balance experiments conducted during winter months between 2012 and 2015. On days when an urban H2Ov excess signal was observed, H2Ov emission estimates range between 1.6 × 104 and 1.7 × 105 kg s−1 and account for up to 8.4% of the total (background + urban excess) advected flow of atmospheric boundary layer H2Ov from the urban study sites. Estimates of H2Ov emissions from combustion sources and electricity generation facility cooling towers are 1–2 orders of magnitude smaller than the urban H2Ov emission rates estimated from observations. Instances of urban H2Ov enhancement could be a result of differences in snowmelt and evaporation rates within the urban area, due in part to larger wintertime anthropogenic heat flux and land cover differences, relative to surrounding rural areas. More study is needed to understand why the urban H2Ov excess signal is observed on some days, and not others. Radiative transfer modeling indicates that the observed urban enhancements in H2Ov and other greenhouse gas mole fractions contribute only 0.1°C d−1 to the urban heat island at the surface. This integrated warming through the boundary layer is offset by longwave cooling by H2Ov at the top of the boundary layer. While the radiative impacts of urban H2Ov emissions do not meaningfully influence urban heat island intensity, urban H2Ov emissions may have the potential to alter downwind aerosol and cloud properties. |
| format |
text |
| author |
Salmon, Olivia E Shepson, Paul B Ren, Xinrong Marquardt Collow, Allison B Miller, Mark A Carlton, Annmarie G Cambaliza, Maria Obiminda L Heimburger, Alexie M F Morgan, Kristan L Fuentes, Jose D Stirm, Brian H Grundman, Robert, II Dickerson, Russell R |
| author_facet |
Salmon, Olivia E Shepson, Paul B Ren, Xinrong Marquardt Collow, Allison B Miller, Mark A Carlton, Annmarie G Cambaliza, Maria Obiminda L Heimburger, Alexie M F Morgan, Kristan L Fuentes, Jose D Stirm, Brian H Grundman, Robert, II Dickerson, Russell R |
| author_sort |
Salmon, Olivia E |
| title |
Urban emissions of water vapor in winter |
| title_short |
Urban emissions of water vapor in winter |
| title_full |
Urban emissions of water vapor in winter |
| title_fullStr |
Urban emissions of water vapor in winter |
| title_full_unstemmed |
Urban emissions of water vapor in winter |
| title_sort |
urban emissions of water vapor in winter |
| publisher |
Archīum Ateneo |
| publishDate |
2017 |
| url |
https://archium.ateneo.edu/physics-faculty-pubs/35 https://agupubs.onlinelibrary.wiley.com/doi/10.1002/2016JD026074 |
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1681506588240642048 |