Vertical nitrogen dioxide and ozone concentrations measured from a tethered balloon in the Lower Fraser Valley

Pisano, John T.; McKendry, Ian G.; Steyn, D. G.; Hastie, D. R.

doi:10.1016/s1352-2310(96)00146-x

Cited by 44 publications

(42 citation statements)

References 15 publications

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“…3, strong vertical variations of NO 2 and O 3 mixing ratios were observed. The negative NO 2 gradient and positive O 3 gradient agree well with earlier observations in various rural and suburban areas (Glaser et al, 2003;Pisano et al, 1997;Stutz et al, 2004b), but with significantly larger magnitudes due to the higher emission rates in downtown Phoenix. The gradients were sustained until the morning hours and then gradually disappeared after the onset of convective mixing.…”

Section: Overview Of Vertical Variations Of Measured Speciessupporting

confidence: 89%

“…Vertical distribution measurements of O 3 , NO 2 , temperature and relative humidity in a suburban area show persistent vertical profiles for several hours after sunrise in some cases (Pisano et al, 1997). A similar trend has been found in the vertical profiles of O 3 , NO 2 , NO x , selected VOCs and meteorological parameters after very stable nights at a rural site (Glaser et al, 2003).…”

supporting

confidence: 71%

“…As a result, a stable nocturnal boundary layer (NBL), which is capped by a relatively well-mixed residual layer (RL) with neutral stability, develops. Due to the weak vertical mixing, ground-level emissions in urban areas accumulate near the surface throughout the night (Doran et al, 2003;Garland and Branson, 1976;Pisano et al, Published by Copernicus GmbH on behalf of the European Geosciences Union.…”

Section: Introductionmentioning

confidence: 99%

“…The study of chemistry in the NBL, especially in polluted urban areas, is thus quite challenging Stutz et al, 2004b). The altitude dependence of both chemistry and vertical trace gas profiles vanish during the morning hours when surface heating leads to convection and accelerates vertical exchange (Doran et al, 2003;Garland and Branson, 1976;Pisano et al, 1997).…”

mentioning

confidence: 99%

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Vertical profiles of O3 and NOx chemistry in the polluted nocturnal boundary layer in Phoenix, AZ: I. Field observations by long-path DOAS

2006

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Abstract. Nocturnal chemistry in the atmospheric boundary layer plays a key role in determining the initial chemical conditions for photochemistry during the following morning as well as influencing the budgets of O 3 and NO 2 . Despite its importance, chemistry in the nocturnal boundary layer (NBL), especially in heavily polluted urban areas, has received little attention so far, which greatly limits the current understanding of the processes involved. In particular, the influence of vertical mixing on chemical processes gives rise to complex vertical profiles of various reactive trace gases and makes nocturnal chemistry altitude-dependent. The processing of pollutants is thus driven by a complicated, and not well quantified, interplay between chemistry and vertical mixing.In order to gain a better understanding of the altitudedependent nocturnal chemistry in the polluted urban environment, a field study was carried out in the downtown area of Phoenix, AZ, in summer 2001. Vertical profiles of reactive species, such as O 3 , NO 2 , and NO 3 , were observed in the lowest 140 m of the troposphere throughout the night. The disappearance of these trace gas vertical gradients during the morning coincided with the morning transition from a stable NBL to a well-mixed convective layer. The vertical gradients of trace gas levels were found to be dependent on both surface NO x emission strength and the vertical stability of the NBL. The vertical gradients of O x , the sum of O 3 and NO 2 , were found to be much smaller than those of O 3 and NO 2 , revealing the dominant role of NO emissions followed by the O 3 +NO reaction for the altitude-dependence of nocturnal chemistry in urban areas. Dry deposition, direct emissions, and other chemical production pathways of NO 2 also play a role for the O x distribution. Strong positive vertical gradients of NO 3 , that are predominantly determined by NO 3 loss near the ground, were observed. The vertical profiles of NO 3 and the calculated vertical profiles of its reserCorrespondence to: J. Stutz (jochen@atmos.ucla.edu) voir species (N 2 O 5 ) confirm earlier model results suggesting complex vertical distributions of atmospheric denoxification processes during the night.

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Section: Overview Of Vertical Variations Of Measured Speciessupporting

confidence: 89%

supporting

confidence: 71%

Section: Introductionmentioning

confidence: 99%

mentioning

confidence: 99%

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Vertical profiles of O3 and NOx chemistry in the polluted nocturnal boundary layer in Phoenix, AZ: I. Field observations by long-path DOAS

2006

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“…They offer the benefit of extended flight times during times of good weather conditions, but fall short of the UASs in terms of flexibility when sampling a targeted spatial location or in capturing gradients across boundaries. Example applications include the measurement of atmospheric composition and structure (e.g., Greenberg 1999;Pisano et al 1997;Neff et al 2008;Shupe et al 2012) and cloud microphysical properties (e.g., Duda et al 1991;Kitchen and Caughey 1981;Zhang et al 1997).…”

mentioning

confidence: 99%

A Bird’s-Eye View: Development of an Operational ARM Unmanned Aerial Capability for Atmospheric Research in Arctic Alaska

Boer

Ivey

Schmid

et al. 2018

Bulletin of the American Meteorological Society

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Thorough understanding of aerosols, clouds, boundary layer structure, and radiation is required to improve the representation of the Arctic atmosphere in weather forecasting and climate models. To develop such understanding, new perspectives are needed to provide details on the vertical structure and spatial variability of key atmospheric properties, along with information over difficult-to-reach surfaces such as newly forming sea ice. Over the last three years, the U.S. Department of Energy (DOE) has supported various flight campaigns using unmanned aircraft systems [UASs, also known as unmanned aerial vehicles (UAVs) and drones] and tethered balloon systems (TBSs) at Oliktok Point, Alaska. These activities have featured in situ measurements of the thermodynamic state, turbulence, radiation, aerosol properties, cloud microphysics, and turbulent fluxes to provide a detailed characterization of the lower atmosphere. Alongside a suite of active and passive ground-based sensors and radiosondes deployed by the DOE Atmospheric Radiation Measurement (ARM) program through the third ARM Mobile Facility (AMF-3), these flight activities demonstrate the ability of such platforms to provide critically needed information. In addition to providing new and unique datasets, lessons learned during initial campaigns have assisted in the development of an exciting new community resource.

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Nocturnal loss of NO_x during the 2010 CalNex‐LA study in the Los Angeles Basin

et al. 2014

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The chemical removal of NO x at night in urban areas remains poorly constrained due to uncertainties in the contribution of various loss pathways and the impact of the suppressed nocturnal vertical mixing. Here we present long-path differential optical absorption spectroscopy observations of nocturnal vertical concentration profiles of O 3 , NO 2 , and NO 3 in the lower atmosphere (33-556 m above ground level) measured during the CalNex-LA 2010 study. Positive nocturnal vertical gradients of O 3 and NO 3 and negative gradients of NO 2 were observed during the night. Relatively short lifetime of nocturnal NO 3 (less than 1000 s) and high nighttime steady state N 2 O 5 mixing ratios (up to 2 ppb) indicated active nocturnal chemistry during CalNex.Comparison of modeled and observed altitude-resolved NO 3 loss frequencies shows that hydrolysis of N 2 O 5 on aerosols was the dominant loss pathway of NO 3 and NO x . Based on this argument, the nocturnal loss rates of NO x , L(NO x ), at different altitudes and averaged over the lowest 550 m of the atmosphere were calculated. The nocturnally averaged L(NO x ) ranged between 0.8 and 1.3 ppb h À1 for the lower atmosphere with the L(NO x ) for the first 8 days at about 1 ppb h À1 . This number is close to the one previously determined in Houston in 2009 of~0.9 ppb h À1 . Comparisons between daytime NO x loss due to the OH + NO 2 reaction and nighttime L(NO x ) show that during CalNex, nocturnal chemistry contributed an average of 60% to the removal of NO x in a 24 h period in the lower atmosphere.

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Vertical nitrogen dioxide and ozone concentrations measured from a tethered balloon in the Lower Fraser Valley

Cited by 44 publications

References 15 publications

Vertical profiles of O<sub>3</sub> and NO<sub>x</sub> chemistry in the polluted nocturnal boundary layer in Phoenix, AZ: I. Field observations by long-path DOAS

Vertical profiles of O<sub>3</sub> and NO<sub>x</sub> chemistry in the polluted nocturnal boundary layer in Phoenix, AZ: I. Field observations by long-path DOAS

A Bird’s-Eye View: Development of an Operational ARM Unmanned Aerial Capability for Atmospheric Research in Arctic Alaska

Nocturnal loss of NO_x during the 2010 CalNex‐LA study in the Los Angeles Basin

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Vertical nitrogen dioxide and ozone concentrations measured from a tethered balloon in the Lower Fraser Valley

Cited by 44 publications

References 15 publications

Vertical profiles of O&lt;sub&gt;3&lt;/sub&gt; and NO&lt;sub&gt;x&lt;/sub&gt; chemistry in the polluted nocturnal boundary layer in Phoenix, AZ: I. Field observations by long-path DOAS

Vertical profiles of O&lt;sub&gt;3&lt;/sub&gt; and NO&lt;sub&gt;x&lt;/sub&gt; chemistry in the polluted nocturnal boundary layer in Phoenix, AZ: I. Field observations by long-path DOAS

A Bird’s-Eye View: Development of an Operational ARM Unmanned Aerial Capability for Atmospheric Research in Arctic Alaska

Nocturnal loss of NOx during the 2010 CalNex‐LA study in the Los Angeles Basin

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Vertical profiles of O<sub>3</sub> and NO<sub>x</sub> chemistry in the polluted nocturnal boundary layer in Phoenix, AZ: I. Field observations by long-path DOAS

Vertical profiles of O<sub>3</sub> and NO<sub>x</sub> chemistry in the polluted nocturnal boundary layer in Phoenix, AZ: I. Field observations by long-path DOAS

Nocturnal loss of NO_x during the 2010 CalNex‐LA study in the Los Angeles Basin