Stratosphere‐troposphere exchange

Holton, James R.; Haynes, P. H.; McIntyre, Michael E.; Douglass, Anne R.; Rood, Richard B.; Pfister, Leonhard

doi:10.1029/95rg02097

Cited by 2,389 publications

(2,315 citation statements)

References 113 publications

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“…The aircraft reached high latitudes (> 70 • N) en route to this destination. Samples collected at higher latitudes have on average higher δD values, firstly because the TP slopes down with latitude and the aircraft therefore penetrates more deeply into the stratosphere at higher latitudes, and secondly because the average degree of stratospheric processing of the air masses is higher at higher latitudes due to the general poleward pattern of stratospheric circulation (Holton et al, 1995). The average degree of stratospheric processing of air generally increases with distance above the TP, and therefore stratospheric δD values also increase with altitude.…”

Section: The Stratospherementioning

confidence: 99%

The stable isotopic composition of molecular hydrogen in the tropopause region probed by the CARIBIC aircraft

et al. 2012

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Abstract. More than 450 air samples that were collected in the upper troposphere -lower stratosphere (UTLS) region by the CARIBIC aircraft (Civil Aircraft for the Regular Investigation of the atmosphere Based on an Instrument Container) have been analyzed for molecular hydrogen (H 2 ) mixing ratios (χ (H 2 )) and H 2 isotopic composition (deuterium content, δD).More than 120 of the analyzed samples contained air from the lowermost stratosphere (LMS). These show that χ(H 2 ) does not vary appreciably with O 3 -derived height above the thermal tropopause (TP), whereas δD does increase with height. The isotope enrichment is caused by H 2 production and destruction processes that enrich the stratospheric H 2 reservoir in deuterium (D); the exact shapes of the profiles are mainly determined by mixing of stratospheric with tropospheric air. Tight negative correlations are found between δD and the mixing ratios of methane (χ(CH 4 )) and nitrous oxide (χ (N 2 O)), as a result of the relatively long lifetimes of these three species. Samples that were collected from the Indian subcontinent up to 40 • N before, during and after the summer monsoon season show no significant seasonal change in χ(H 2 ), but δD is up to 12.3 ‰ lower in the July, August and September monsoon samples. This δD decrease is correlated with the χ(CH 4 ) increase in these samples. The significant correlation with χ (CH 4 ) and the absence of a perceptible χ(H 2 ) increase that accompanies the δD decrease indicates that microbial production of very D-depleted H 2 in the wet season may contribute to this phenomenon.Some of the samples have very high χ (H 2 ) and very low δD values, which indicates a pollution effect. Aircraft engine exhaust plumes are a suspected cause, since the effect mostly occurs in samples collected close to airports, but no similar signals are found in other chemical tracers to support this. The isotopic source signature of the H 2 pollution seems to be on the low end of the signature for fossil fuel burning.

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Section: The Stratospherementioning

confidence: 99%

The stable isotopic composition of molecular hydrogen in the tropopause region probed by the CARIBIC aircraft

et al. 2012

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“…The transfer of ozone from the lower stratosphere strongly influences the chemical budget and radiative balance of the extratropical upper troposphere [Holton et al, 1995]. This transport is typically associated with the formation of tropopause folds [Danielsen, 1968], cutoff lows [Barnber et al, 1984], and streamers [Appenzeller and Davies, 1992] along the polar-front jet (PFJ), the meandering zone of high wind speed between 250 and 300 hPa associated with midlatitude cyclonic disturbances [Mahlrnan, 1973].…”

Section: Introductionmentioning

confidence: 99%

Stratosphere‐troposphere exchange at the subtropical jet: Contribution to the tropospheric ozone budget at midlatitudes

Langford

1999

Geophysical Research Letters

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during the winter months. In an earlier publication, Langford et al. [1998] suggested that ENSO-related changes in free tropospheric ozone above Colorado might be due to variations in the intensity of STE at the STJ over the eastern Pacific. In this paper, we provide support for this hypothesis, and present evidence that such exchange may be a significant source of tropospheric ozone at this midlatitude site. Observations

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“…For global NWP, the stratosphere plays a significant role in the global circulation [48,50,71]. Inclusion of a well-represented stratosphere has implications for the chosen time-integration methods, since the stratospheric polar jet (which contributes via the advection term) reaches speeds exceeding 100 m s À1 , i.e., the advective Courant number approaches the acoustic one.…”

Section: Horizontally-explicit Vertically-implicit (Hevi) Schemesmentioning

confidence: 99%

Current and Emerging Time-Integration Strategies in Global Numerical Weather and Climate Prediction

Mengaldo

Wyszogrodzki

Diamantakis

et al. 2018

Arch Computat Methods Eng

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The continuous partial differential equations governing a given physical phenomenon, such as the Navier-Stokes equations describing the fluid motion, must be numerically discretized in space and time in order to obtain a solution otherwise not readily available in closed (i.e., analytic) form. While the overall numerical discretization plays an essential role in the algorithmic efficiency and physically-faithful representation of the solution, the time-integration strategy commonly is one of the main drivers in terms of cost-to-solution (e.g., time-or energy-to-solution), accuracy and numerical stability, thus constituting one of the key building blocks of the computational model. This is especially true in time-critical applications, including numerical weather prediction (NWP), climate simulations and engineering. This review provides a comprehensive overview of the existing and emerging time-integration (also referred to as time-stepping) practices used in the operational global NWP and climate industry, where global refers to weather and climate simulations performed on the entire globe. While there are many flavors of time-integration strategies, in this review we focus on the most widely adopted in NWP and climate centers and we emphasize the reasons why such numerical solutions were adopted. This allows us to make some considerations on future trends in the field such as the need to balance accuracy in time with substantially enhanced time-to-solution and associated implications on energy consumption and running costs. In addition, the potential for the co-design of time-stepping algorithms and underlying high performance computing hardware, a keystone to accelerate the computational performance of future NWP and climate services, is also discussed in the context of the demanding operational requirements of the weather and climate industry.

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Stratosphere‐troposphere exchange

Cited by 2,389 publications

References 113 publications

The stable isotopic composition of molecular hydrogen in the tropopause region probed by the CARIBIC aircraft

The stable isotopic composition of molecular hydrogen in the tropopause region probed by the CARIBIC aircraft

Stratosphere‐troposphere exchange at the subtropical jet: Contribution to the tropospheric ozone budget at midlatitudes

Current and Emerging Time-Integration Strategies in Global Numerical Weather and Climate Prediction

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