Influence of Mountain Waves and NAT Nucleation Mechanisms on Polar Stratospheric Cloud Formation at Local and Synoptic Scales during the 1999-2000 Arctic Winter

A scheme for introducing mountain wave-induced temperature perturbations in a microphysical polar stratospheric cloud (PSC) model has been developed. A data set of temperature fluctuations attributable to mountain waves as computed by the Mountain Wave Forecast Model (MWFM-2) has been used for the s...

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Bibliographic Details
Main Authors: Svendsen, S. H., Larsen, N., Knudsen, B., Eckermann, S. D., Browell, E. V.
Other Authors: NAVAL RESEARCH LAB WASHINGTON DC
Format: Text
Language:English
Published: 2005
Subjects:
Atmospheric Physics
Meteorology
*HYDRATES
*GRAVITY WAVES
*STRATOSPHERE
*NITRIC ACID
*PARTICLES
*ICE FORMATION
*NUCLEATION
*CLOUDS
OZONE DEPLETION
PERTURBATIONS
WINTER
OBSERVATION
COMPUTERIZED SIMULATION
ARCTIC REGIONS
REPRINTS
SCENARIOS
TEMPERATURE
*MOUNTAIN WAVES
*POLAR STRATOSPHERIC CLOUDS
*NITRIC ACID TRIHYDRATE
*ICE PARTICLES
GRAVITATIONAL SEDIMENTATION
MICROPHYSICAL MODELS
MWFM-2(MOUNTAIN WAVE FORECAST MODEL-2)
TEMPERATURE FLUCTUATIONS
Arctic
Online Access:http://www.dtic.mil/docs/citations/ADA526730
http://oai.dtic.mil/oai/oai?&verb=getRecord&metadataPrefix=html&identifier=ADA526730
id ftdtic:ADA526730
record_format openpolar
spelling ftdtic:ADA526730 2023-05-15T15:04:51+02:00 Influence of Mountain Waves and NAT Nucleation Mechanisms on Polar Stratospheric Cloud Formation at Local and Synoptic Scales during the 1999-2000 Arctic Winter Svendsen, S. H. Larsen, N. Knudsen, B. Eckermann, S. D. Browell, E. V. NAVAL RESEARCH LAB WASHINGTON DC 2005-03-07 text/html http://www.dtic.mil/docs/citations/ADA526730 http://oai.dtic.mil/oai/oai?&verb=getRecord&metadataPrefix=html&identifier=ADA526730 en eng http://www.dtic.mil/docs/citations/ADA526730 Approved for public release; distribution is unlimited. DTIC Atmospheric Physics Meteorology *HYDRATES *GRAVITY WAVES *STRATOSPHERE *NITRIC ACID *PARTICLES *ICE FORMATION *NUCLEATION *CLOUDS OZONE DEPLETION PERTURBATIONS WINTER OBSERVATION COMPUTERIZED SIMULATION ARCTIC REGIONS REPRINTS SCENARIOS TEMPERATURE *MOUNTAIN WAVES *POLAR STRATOSPHERIC CLOUDS *NITRIC ACID TRIHYDRATE *ICE PARTICLES GRAVITATIONAL SEDIMENTATION MICROPHYSICAL MODELS MWFM-2(MOUNTAIN WAVE FORECAST MODEL-2) TEMPERATURE FLUCTUATIONS Text 2005 ftdtic 2016-02-23T03:03:47Z A scheme for introducing mountain wave-induced temperature perturbations in a microphysical polar stratospheric cloud (PSC) model has been developed. A data set of temperature fluctuations attributable to mountain waves as computed by the Mountain Wave Forecast Model (MWFM-2) has been used for the study. The PSC model has variable microphysics, enabling different nucleation mechanisms for nitric acid trihydrate, NAT, to be employed. In particular, the difference between the formation of NAT and ice particles in a scenario where NAT formation is not dependent on preexisting ice particles, allowing NAT to form at temperatures above the ice frost point, T(sub ice), and a scenario where NAT nucleation is dependent on preexisting ice particles, is examined. The performance of the microphysical model in the different microphysical scenarios and a number of temperature scenarios with and without the influence of mountain waves is tested through comparisons with lidar measurements of PSCs made from the NASA DC-8 on 23 and 25 January during the SOLVE/THESEO 2000 campaign in the 1999-2000 winter and the effect of mountain waves on local PSC production is evaluated in the different microphysical scenarios. Mountain waves are seen to have a pronounced effect on the amount of ice particles formed in the simulations. Quantitative comparisons of the amount of solids seen in the observations and the amount of solids produced in the simulations show the best correspondence when NAT formation is allowed to take place at temperatures above T(sub ice). Mountain wave-induced temperature fluctuations are introduced in vortex-covering model runs, extending the full 1999-2000 winter season, and the effect of mountain waves on large-scale PSC production is estimated in the different microphysical scenarios. Regardless of the choice of microphysics, the inclusion of mountain waves increases the amount of NAT particles by as much as 10%. Published in the Journal of Atmospheric Chemistry and Physics, v5 p739-753, 2005. Text Arctic Defense Technical Information Center: DTIC Technical Reports database Arctic
institution Open Polar
collection Defense Technical Information Center: DTIC Technical Reports database
op_collection_id ftdtic
language English
topic Atmospheric Physics
Meteorology
*HYDRATES
*GRAVITY WAVES
*STRATOSPHERE
*NITRIC ACID
*PARTICLES
*ICE FORMATION
*NUCLEATION
*CLOUDS
OZONE DEPLETION
PERTURBATIONS
WINTER
OBSERVATION
COMPUTERIZED SIMULATION
ARCTIC REGIONS
REPRINTS
SCENARIOS
TEMPERATURE
*MOUNTAIN WAVES
*POLAR STRATOSPHERIC CLOUDS
*NITRIC ACID TRIHYDRATE
*ICE PARTICLES
GRAVITATIONAL SEDIMENTATION
MICROPHYSICAL MODELS
MWFM-2(MOUNTAIN WAVE FORECAST MODEL-2)
TEMPERATURE FLUCTUATIONS
spellingShingle Atmospheric Physics
Meteorology
*HYDRATES
*GRAVITY WAVES
*STRATOSPHERE
*NITRIC ACID
*PARTICLES
*ICE FORMATION
*NUCLEATION
*CLOUDS
OZONE DEPLETION
PERTURBATIONS
WINTER
OBSERVATION
COMPUTERIZED SIMULATION
ARCTIC REGIONS
REPRINTS
SCENARIOS
TEMPERATURE
*MOUNTAIN WAVES
*POLAR STRATOSPHERIC CLOUDS
*NITRIC ACID TRIHYDRATE
*ICE PARTICLES
GRAVITATIONAL SEDIMENTATION
MICROPHYSICAL MODELS
MWFM-2(MOUNTAIN WAVE FORECAST MODEL-2)
TEMPERATURE FLUCTUATIONS
Svendsen, S. H.
Larsen, N.
Knudsen, B.
Eckermann, S. D.
Browell, E. V.
Influence of Mountain Waves and NAT Nucleation Mechanisms on Polar Stratospheric Cloud Formation at Local and Synoptic Scales during the 1999-2000 Arctic Winter
topic_facet Atmospheric Physics
Meteorology
*HYDRATES
*GRAVITY WAVES
*STRATOSPHERE
*NITRIC ACID
*PARTICLES
*ICE FORMATION
*NUCLEATION
*CLOUDS
OZONE DEPLETION
PERTURBATIONS
WINTER
OBSERVATION
COMPUTERIZED SIMULATION
ARCTIC REGIONS
REPRINTS
SCENARIOS
TEMPERATURE
*MOUNTAIN WAVES
*POLAR STRATOSPHERIC CLOUDS
*NITRIC ACID TRIHYDRATE
*ICE PARTICLES
GRAVITATIONAL SEDIMENTATION
MICROPHYSICAL MODELS
MWFM-2(MOUNTAIN WAVE FORECAST MODEL-2)
TEMPERATURE FLUCTUATIONS
description A scheme for introducing mountain wave-induced temperature perturbations in a microphysical polar stratospheric cloud (PSC) model has been developed. A data set of temperature fluctuations attributable to mountain waves as computed by the Mountain Wave Forecast Model (MWFM-2) has been used for the study. The PSC model has variable microphysics, enabling different nucleation mechanisms for nitric acid trihydrate, NAT, to be employed. In particular, the difference between the formation of NAT and ice particles in a scenario where NAT formation is not dependent on preexisting ice particles, allowing NAT to form at temperatures above the ice frost point, T(sub ice), and a scenario where NAT nucleation is dependent on preexisting ice particles, is examined. The performance of the microphysical model in the different microphysical scenarios and a number of temperature scenarios with and without the influence of mountain waves is tested through comparisons with lidar measurements of PSCs made from the NASA DC-8 on 23 and 25 January during the SOLVE/THESEO 2000 campaign in the 1999-2000 winter and the effect of mountain waves on local PSC production is evaluated in the different microphysical scenarios. Mountain waves are seen to have a pronounced effect on the amount of ice particles formed in the simulations. Quantitative comparisons of the amount of solids seen in the observations and the amount of solids produced in the simulations show the best correspondence when NAT formation is allowed to take place at temperatures above T(sub ice). Mountain wave-induced temperature fluctuations are introduced in vortex-covering model runs, extending the full 1999-2000 winter season, and the effect of mountain waves on large-scale PSC production is estimated in the different microphysical scenarios. Regardless of the choice of microphysics, the inclusion of mountain waves increases the amount of NAT particles by as much as 10%. Published in the Journal of Atmospheric Chemistry and Physics, v5 p739-753, 2005.
author2 NAVAL RESEARCH LAB WASHINGTON DC
format Text
author Svendsen, S. H.
Larsen, N.
Knudsen, B.
Eckermann, S. D.
Browell, E. V.
author_facet Svendsen, S. H.
Larsen, N.
Knudsen, B.
Eckermann, S. D.
Browell, E. V.
author_sort Svendsen, S. H.
title Influence of Mountain Waves and NAT Nucleation Mechanisms on Polar Stratospheric Cloud Formation at Local and Synoptic Scales during the 1999-2000 Arctic Winter
title_short Influence of Mountain Waves and NAT Nucleation Mechanisms on Polar Stratospheric Cloud Formation at Local and Synoptic Scales during the 1999-2000 Arctic Winter
title_full Influence of Mountain Waves and NAT Nucleation Mechanisms on Polar Stratospheric Cloud Formation at Local and Synoptic Scales during the 1999-2000 Arctic Winter
title_fullStr Influence of Mountain Waves and NAT Nucleation Mechanisms on Polar Stratospheric Cloud Formation at Local and Synoptic Scales during the 1999-2000 Arctic Winter
title_full_unstemmed Influence of Mountain Waves and NAT Nucleation Mechanisms on Polar Stratospheric Cloud Formation at Local and Synoptic Scales during the 1999-2000 Arctic Winter
title_sort influence of mountain waves and nat nucleation mechanisms on polar stratospheric cloud formation at local and synoptic scales during the 1999-2000 arctic winter
publishDate 2005
url http://www.dtic.mil/docs/citations/ADA526730
http://oai.dtic.mil/oai/oai?&verb=getRecord&metadataPrefix=html&identifier=ADA526730
geographic Arctic
geographic_facet Arctic
genre Arctic
genre_facet Arctic
op_source DTIC
op_relation http://www.dtic.mil/docs/citations/ADA526730
op_rights Approved for public release; distribution is unlimited.
_version_ 1766336591908831232

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