Spatial heterodyne observations of water (SHOW) from a high-altitude airplane: characterization, performance, and first results

Langille, Jeffery; Letros, Daniel; Bourassa, Adam; Solheim, B. H.; Degenstein, D. A.; Dupont, Fabien; Zawada, Daniel; Lloyd, N. D.

doi:10.5194/amt-12-431-2019

Cited by 10 publications

(5 citation statements)

References 36 publications

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“…The SHOW prototype flew several demonstration flights on NASA's ER-2 aircraft in July, 2017 in order to validate the measurement approach and to demonstrate the along-track sampling capabilities of the instrument. The SHOW measurement technique, retrieval approach and instrument performance was validated during an Engineering flight that was performed on July 17, 2018 (Langille et al, 2019). Comparison with co-located radiosonde measurements were found to be in excellent agreement, with differences of < 1 ppm above 15 km (near the thermal tropopause) and < 2-5 ppm below 15 km, due to both natural variability between the observations and measurement precision.…”

Section: Chemical Structures Of Quasi-isentropic Mixing Have Been Obsmentioning

confidence: 95%

“…These vertically resolved spectral images are inverted using a non-linear optimal estimation approach to obtain the vertical distribution of water vapour. The SHOW measurement technique and retrieval algorithm is discussed in previous publications [Langille et al, 2018;Langille et al, 2019].…”

Section: The Spatial Heterodyne Observations Of Water (Show) Instrumentmentioning

confidence: 99%

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Observational evidence of moistening the lowermost stratosphere via isentropic mixing across the subtropical jet

Langille¹,

Bourassa²,

Pan³

et al. 2019

Preprint

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<p><strong>Abstract.</strong> Isentropic mixing across and above the subtropical jet in the presence of a double tropopause may be a significant mechanism for moistening the lowermost stratosphere. We present an analysis of high spatial resolution two-dimensional measurements of the water vapour distribution that were obtained using the Spatial Heterodyne Observations of Water instrument during a demonstration flight from NASA&#8217;s high altitude ER-2 airplane. We focus on a set of measurements from 37&#176; to 44&#176; North, obtained on July 21, 2017 during a flight off the West coast of North America, where the instrument sampled the region above and poleward of the subtropical jet. Analysis of these measurements reveals poleward mixing of moist filaments in the region of a double tropopause. These moist filaments are examined in the context of the meteorological fields in the ECMWF (ERA-interim) model output. It is shown that the observed moist filaments are consistent with isentropic mixing across and above the sub-tropical jet. These new observations provide further evidence that the tropospheric intrusion associated with the double tropopause contributes to moistening of the lowermost stratosphere</p>

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Section: Chemical Structures Of Quasi-isentropic Mixing Have Been Obsmentioning

confidence: 95%

Section: The Spatial Heterodyne Observations Of Water (Show) Instrumentmentioning

confidence: 99%

Observational evidence of moistening the lowermost stratosphere via isentropic mixing across the subtropical jet

Langille¹,

Bourassa²,

Pan³

et al. 2019

Preprint

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“…We first compute the horizontal area-weighted average GEM water vapor data at each altitude using the horizontal resolutions and the retrieval spacings from the instruments. The horizontal resolutions used in this analysis (along track × cross track) are 200 × 7, 13.5 × 13.5, and 50 × 100 km for MLS, AIRS, and SHOW (designed spatial resolutions are used for SHOW), respectively, and are the same for all altitudes (Langille et al, 2017(Langille et al, , 2018(Langille et al, , 2019Livesey et al, 2017). The retrieval spacings used for MLS, AIRS, and SHOW are 200, 1, and 15 km, respectively.…”

Section: Detectability Of Water Vapor Plumesmentioning

confidence: 99%

“…For the AIRS vertical averaging kernels, our calculations are based on the joint AIRS-DARDAR retrieval method developed by Feng et al (2021), Feng and Huang (2018), as the standard AIRS retrieval is not sensitive to the water vapor signal from the UTLS (Fetzer et al, 2008;Gettelman et al, 2004;Read et al, 2007). Note that the vertical resolutions in the UTLS region are ∼5.5 km in AIRS (Feng et al, 2021), ∼3 km in the MLS (Livesey et al, 2017), and 0.5-1 km in the SHOW (Langille et al, 2017(Langille et al, , 2018(Langille et al, , 2019. We refer to the water vapor data calculated following the above method as GEM-MLS, GEM-AIRS, and GEM-SHOW.…”

Section: Detectability Of Water Vapor Plumesmentioning

confidence: 99%

Convectively Transported Water Vapor Plumes in the Midlatitude Lower Stratosphere

Wang

Huang

et al. 2023

JGR Atmospheres

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Water vapor in the stratosphere plays an important role in climate change both chemically and radiatively. As a major source of hydroxyl (OH) radicals, increases in stratospheric water vapor accelerate the stratospheric ozone loss rate (Dvortsov & Solomon, 2001;S. Solomon et al., 1986). As a greenhouse gas, increases in stratospheric water vapor warm the troposphere and cool the stratosphere (Forster & Shine, 2002;S. Solomon et al., 2010).Water vapor enters the stratosphere primarily through the tropical tropopause layer (TTL), where the temperatures play a predominant role in controlling the budget of stratospheric water vapor (

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“…The AURA-MLS satellite instrument obtained measurements along this track at approximately 21:50 UTC -roughly 2 h after the SHOW measurements were performed. Along this track, the MLS instrument sampled the same geophysical feature along a slightly different path with a horizontal resolution of 168-230 km and a vertical resolution of 1.3-3.2 km in the UTLS (316-46 hPa) (Livesey et al, 2018). The MLS measurements have a coarser spatial resolution, and the sampling is not exactly coincident with SHOW.…”

Section: Aura-mls Ozone and Water Vapourmentioning

confidence: 99%

Observational evidence of moistening the lowermost stratosphere via isentropic mixing across the subtropical jet

et al. 2020

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Abstract. Isentropic mixing across and above the subtropical jet is a significant mechanism for stratosphere–troposphere exchange. In this work, we show new observational evidence on the role of this process in moistening the lowermost stratosphere. The new measurement, obtained from the Spatial Heterodyne Observations of Water (SHOW) instrument during a demonstration flight on the NASA's ER-2 high-altitude research aircraft, captured an event of poleward water vapour transport, including a fine-scale (vertically <∼1 km) moist filament above the local tropopause in a high-spatial-resolution two-dimensional cross section of the water vapour distribution. Analysis of these measurements combined with ERA5 reanalysis data reveals that this poleward mixing of air with enhanced water vapour occurred in the region of a double tropopause following a large Rossby wave-breaking event. These new observations highlight the importance of high-resolution measurements in resolving processes that are important to the lowermost-stratosphere water vapour budget.

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Spatial heterodyne observations of water (SHOW) from a high-altitude airplane: characterization, performance, and first results

Cited by 10 publications

References 36 publications

Observational evidence of moistening the lowermost stratosphere via isentropic mixing across the subtropical jet

Observational evidence of moistening the lowermost stratosphere via isentropic mixing across the subtropical jet

Convectively Transported Water Vapor Plumes in the Midlatitude Lower Stratosphere

Observational evidence of moistening the lowermost stratosphere via isentropic mixing across the subtropical jet

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