A Stochastic Representation of Temperature Fluctuations Induced by Mesoscale Gravity Waves

Ubiquitous mesoscale gravity waves generate high cooling rates important for cirrus formation. We make use of long‐duration balloon observations to devise a probabilistic model describing mesoscale temperature uctuations (MTF) away from strong wave sources. We define background conditions based on o...

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Veröffentlicht in:	Journal of geophysical research. Atmospheres 2019-11, Vol.124 (21), p.11506-11529
Hauptverfasser:	Kärcher, B., Podglajen, A.
Format:	Artikel
Sprache:	eng
Schlagworte:	Aerosols Air parcels Atmospheric models Balloon measurements Balloon observations Balloons Cirrus clouds Climate models Computer simulation Confidence Cooling Cooling rate Coriolis force Damping Duration Equatorial regions Fluctuations Geophysics Gravitational waves Gravity Gravity waves Ice Ice clouds Ice crystal formation Ice crystals Ice formation Measurement methods Mesoscale gravity waves Mesoscale phenomena Meteorological balloons Nucleation Physics Probabilistic models Probability theory Properties Saturation Sciences of the Universe Statistical analysis Statistical methods Stratification Temperature Temperature fluctuations Uncertainty Updraft Vertical wind velocities Wind Wind speed
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container_end_page	11529
container_issue	21
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container_title	Journal of geophysical research. Atmospheres
container_volume	124
creator	Kärcher, B. Podglajen, A.
description	Ubiquitous mesoscale gravity waves generate high cooling rates important for cirrus formation. We make use of long‐duration balloon observations to devise a probabilistic model describing mesoscale temperature uctuations (MTF) away from strong wave sources. We define background conditions based on observed probability distributions of temperature and underlying vertical wind speed fluctuations. We show theoretically that MTF are subject to damping at a rate near the Coriolis frequency when the vertical wind speed fluctuations are autocorrelated over a fraction of a Brunt‐Väisälä period. We find that for background wave activity, a decrease in temperature of 1K translates into cooling rate standard deviations and mean updraft speeds of 4–8Kh−1 and ≈ 10–20 cms−1, respectively, depending on latitude and stratification. We introduce an effective Coriolis frequency to generate cooling rates in equatorial regions consistent with balloon data. Above ice saturation, MTF are large enough to affect ice crystal nucleation. Our results help constrain uncertainty in aerosol‐cirrus interactions, provide insights to better meet challenges in comparing measurement data with model simulations, and support the development of cutting‐edge ice cloud schemes in global models. Plain Language Summary: The limited scientific understanding of pure ice clouds (cirrus)—and therefore the difficulty to account for them in models—causes substantial uncertainty in climate projections. Two research issues important for cirrus formation continue to form a roadblock on the path of scientific progress: the dynamical forcing driving cirrus ice crystal formation and the ice‐forming properties of solid atmospheric particles. Long‐duration balloons floating in the high atmosphere have quantified key properties of gravity waves that generate vertical air motions (cooling rates) crucial for ice formation in cirrus. Only when occurrence and magnitude of cooling rates are well understood can effects of different solid and liquid ice‐forming particles during cirrus formation be predicted with confidence. Blending insights obtained from the research balloon measurements with theoretical methods developed in statistical physics, our study elaborates on the dynamical forcing issue by devising a model that represents air parcel cooling rates on a probabilistic basis. We thereby hope to contribute significantly to a comprehensive process understanding and, ultimately, to removing one of the roadblocks in
doi_str_mv	10.1029/2019JD030680
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We make use of long‐duration balloon observations to devise a probabilistic model describing mesoscale temperature uctuations (MTF) away from strong wave sources. We define background conditions based on observed probability distributions of temperature and underlying vertical wind speed fluctuations. We show theoretically that MTF are subject to damping at a rate near the Coriolis frequency when the vertical wind speed fluctuations are autocorrelated over a fraction of a Brunt‐Väisälä period. We find that for background wave activity, a decrease in temperature of 1K translates into cooling rate standard deviations and mean updraft speeds of 4–8Kh−1 and ≈ 10–20 cms−1, respectively, depending on latitude and stratification. We introduce an effective Coriolis frequency to generate cooling rates in equatorial regions consistent with balloon data. Above ice saturation, MTF are large enough to affect ice crystal nucleation. Our results help constrain uncertainty in aerosol‐cirrus interactions, provide insights to better meet challenges in comparing measurement data with model simulations, and support the development of cutting‐edge ice cloud schemes in global models. Plain Language Summary: The limited scientific understanding of pure ice clouds (cirrus)—and therefore the difficulty to account for them in models—causes substantial uncertainty in climate projections. Two research issues important for cirrus formation continue to form a roadblock on the path of scientific progress: the dynamical forcing driving cirrus ice crystal formation and the ice‐forming properties of solid atmospheric particles. Long‐duration balloons floating in the high atmosphere have quantified key properties of gravity waves that generate vertical air motions (cooling rates) crucial for ice formation in cirrus. Only when occurrence and magnitude of cooling rates are well understood can effects of different solid and liquid ice‐forming particles during cirrus formation be predicted with confidence. Blending insights obtained from the research balloon measurements with theoretical methods developed in statistical physics, our study elaborates on the dynamical forcing issue by devising a model that represents air parcel cooling rates on a probabilistic basis. We thereby hope to contribute significantly to a comprehensive process understanding and, ultimately, to removing one of the roadblocks in cloud research. Key Points A probabilistic model for gravity wave‐induced mesoscale temperature fluctuations is developed based on observations A relationship between wave‐induced temperature and associated cooling/heating rate fluctuation amplitudes is derived It is shown how wave effects can be included in microphysical simulation models and global model parameterizations</description><identifier>ISSN: 2169-897X</identifier><identifier>EISSN: 2169-8996</identifier><identifier>DOI: 10.1029/2019JD030680</identifier><language>eng</language><publisher>Washington: Blackwell Publishing Ltd</publisher><subject>Aerosols ; Air parcels ; Atmospheric models ; Balloon measurements ; Balloon observations ; Balloons ; Cirrus clouds ; Climate models ; Computer simulation ; Confidence ; Cooling ; Cooling rate ; Coriolis force ; Damping ; Duration ; Equatorial regions ; Fluctuations ; Geophysics ; Gravitational waves ; Gravity ; Gravity waves ; Ice ; Ice clouds ; Ice crystal formation ; Ice crystals ; Ice formation ; Measurement methods ; Mesoscale gravity waves ; Mesoscale phenomena ; Meteorological balloons ; Nucleation ; Physics ; Probabilistic models ; Probability theory ; Properties ; Saturation ; Sciences of the Universe ; Statistical analysis ; Statistical methods ; Stratification ; Temperature ; Temperature fluctuations ; Uncertainty ; Updraft ; Vertical wind velocities ; Wind ; Wind speed</subject><ispartof>Journal of geophysical research. Atmospheres, 2019-11, Vol.124 (21), p.11506-11529</ispartof><rights>2019. American Geophysical Union. 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Atmospheres</title><description>Ubiquitous mesoscale gravity waves generate high cooling rates important for cirrus formation. We make use of long‐duration balloon observations to devise a probabilistic model describing mesoscale temperature uctuations (MTF) away from strong wave sources. We define background conditions based on observed probability distributions of temperature and underlying vertical wind speed fluctuations. We show theoretically that MTF are subject to damping at a rate near the Coriolis frequency when the vertical wind speed fluctuations are autocorrelated over a fraction of a Brunt‐Väisälä period. We find that for background wave activity, a decrease in temperature of 1K translates into cooling rate standard deviations and mean updraft speeds of 4–8Kh−1 and ≈ 10–20 cms−1, respectively, depending on latitude and stratification. We introduce an effective Coriolis frequency to generate cooling rates in equatorial regions consistent with balloon data. Above ice saturation, MTF are large enough to affect ice crystal nucleation. Our results help constrain uncertainty in aerosol‐cirrus interactions, provide insights to better meet challenges in comparing measurement data with model simulations, and support the development of cutting‐edge ice cloud schemes in global models. Plain Language Summary: The limited scientific understanding of pure ice clouds (cirrus)—and therefore the difficulty to account for them in models—causes substantial uncertainty in climate projections. Two research issues important for cirrus formation continue to form a roadblock on the path of scientific progress: the dynamical forcing driving cirrus ice crystal formation and the ice‐forming properties of solid atmospheric particles. Long‐duration balloons floating in the high atmosphere have quantified key properties of gravity waves that generate vertical air motions (cooling rates) crucial for ice formation in cirrus. Only when occurrence and magnitude of cooling rates are well understood can effects of different solid and liquid ice‐forming particles during cirrus formation be predicted with confidence. Blending insights obtained from the research balloon measurements with theoretical methods developed in statistical physics, our study elaborates on the dynamical forcing issue by devising a model that represents air parcel cooling rates on a probabilistic basis. We thereby hope to contribute significantly to a comprehensive process understanding and, ultimately, to removing one of the roadblocks in cloud research. Key Points A probabilistic model for gravity wave‐induced mesoscale temperature fluctuations is developed based on observations A relationship between wave‐induced temperature and associated cooling/heating rate fluctuation amplitudes is derived It is shown how wave effects can be included in microphysical simulation models and global model parameterizations</description><subject>Aerosols</subject><subject>Air parcels</subject><subject>Atmospheric models</subject><subject>Balloon measurements</subject><subject>Balloon observations</subject><subject>Balloons</subject><subject>Cirrus clouds</subject><subject>Climate models</subject><subject>Computer simulation</subject><subject>Confidence</subject><subject>Cooling</subject><subject>Cooling rate</subject><subject>Coriolis force</subject><subject>Damping</subject><subject>Duration</subject><subject>Equatorial regions</subject><subject>Fluctuations</subject><subject>Geophysics</subject><subject>Gravitational waves</subject><subject>Gravity</subject><subject>Gravity waves</subject><subject>Ice</subject><subject>Ice clouds</subject><subject>Ice crystal formation</subject><subject>Ice crystals</subject><subject>Ice formation</subject><subject>Measurement methods</subject><subject>Mesoscale gravity waves</subject><subject>Mesoscale phenomena</subject><subject>Meteorological balloons</subject><subject>Nucleation</subject><subject>Physics</subject><subject>Probabilistic models</subject><subject>Probability theory</subject><subject>Properties</subject><subject>Saturation</subject><subject>Sciences of the Universe</subject><subject>Statistical analysis</subject><subject>Statistical methods</subject><subject>Stratification</subject><subject>Temperature</subject><subject>Temperature fluctuations</subject><subject>Uncertainty</subject><subject>Updraft</subject><subject>Vertical wind velocities</subject><subject>Wind</subject><subject>Wind speed</subject><issn>2169-897X</issn><issn>2169-8996</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2019</creationdate><recordtype>article</recordtype><sourceid>24P</sourceid><sourceid>WIN</sourceid><recordid>eNp9kE1Lw0AQhoMoWLQ3f8CCN7E6-5Fuciyt_aIi1IriZdlsJjQlTeJuUsm_NxopnpzDzMA8vLzzet4VhTsKLLxnQMPlBDgMAzjxeowOw0EQhsPT4y7fzr2-cztoKwAufNHz3kfkuSrMVrsqNWSNpUWHeaWrtMhJkZAN7ku0uqotkmlWm6r-OTmyyOPaYEyihjyiK5zRGZKZ1Ye0asirPqC79M4SnTns_84L72X6sBnPB6un2WI8Wg0MD4ANooQKE5uQRX7bTCi0j0YA5xS05iyQIqI6Zpqjz6UJdBCzyFAeGcFNDBL5hXfT6W51pkqb7rVtVKFTNR-tVJq7WgGXTLY_H2gLX3dwaYuPGl2ldkVt89afYpyGAFKCaKnbjjK2cM5ictSloL7TVn_TbnHe4Z9phs2_rFrO1hPfl4LxL0tdgDM</recordid><startdate>20191116</startdate><enddate>20191116</enddate><creator>Kärcher, B.</creator><creator>Podglajen, A.</creator><general>Blackwell Publishing Ltd</general><general>American Geophysical Union</general><scope>24P</scope><scope>WIN</scope><scope>AAYXX</scope><scope>CITATION</scope><scope>7TG</scope><scope>7UA</scope><scope>8FD</scope><scope>C1K</scope><scope>F1W</scope><scope>FR3</scope><scope>H8D</scope><scope>H96</scope><scope>KL.</scope><scope>KR7</scope><scope>L.G</scope><scope>L7M</scope><scope>1XC</scope><scope>VOOES</scope><orcidid>https://orcid.org/0000-0003-0278-4980</orcidid></search><sort><creationdate>20191116</creationdate><title>A Stochastic Representation of Temperature Fluctuations Induced by Mesoscale Gravity Waves</title><author>Kärcher, B. ; 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Atmospheres</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Kärcher, B.</au><au>Podglajen, A.</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>A Stochastic Representation of Temperature Fluctuations Induced by Mesoscale Gravity Waves</atitle><jtitle>Journal of geophysical research. Atmospheres</jtitle><date>2019-11-16</date><risdate>2019</risdate><volume>124</volume><issue>21</issue><spage>11506</spage><epage>11529</epage><pages>11506-11529</pages><issn>2169-897X</issn><eissn>2169-8996</eissn><abstract>Ubiquitous mesoscale gravity waves generate high cooling rates important for cirrus formation. We make use of long‐duration balloon observations to devise a probabilistic model describing mesoscale temperature uctuations (MTF) away from strong wave sources. We define background conditions based on observed probability distributions of temperature and underlying vertical wind speed fluctuations. We show theoretically that MTF are subject to damping at a rate near the Coriolis frequency when the vertical wind speed fluctuations are autocorrelated over a fraction of a Brunt‐Väisälä period. We find that for background wave activity, a decrease in temperature of 1K translates into cooling rate standard deviations and mean updraft speeds of 4–8Kh−1 and ≈ 10–20 cms−1, respectively, depending on latitude and stratification. We introduce an effective Coriolis frequency to generate cooling rates in equatorial regions consistent with balloon data. Above ice saturation, MTF are large enough to affect ice crystal nucleation. Our results help constrain uncertainty in aerosol‐cirrus interactions, provide insights to better meet challenges in comparing measurement data with model simulations, and support the development of cutting‐edge ice cloud schemes in global models. Plain Language Summary: The limited scientific understanding of pure ice clouds (cirrus)—and therefore the difficulty to account for them in models—causes substantial uncertainty in climate projections. Two research issues important for cirrus formation continue to form a roadblock on the path of scientific progress: the dynamical forcing driving cirrus ice crystal formation and the ice‐forming properties of solid atmospheric particles. Long‐duration balloons floating in the high atmosphere have quantified key properties of gravity waves that generate vertical air motions (cooling rates) crucial for ice formation in cirrus. Only when occurrence and magnitude of cooling rates are well understood can effects of different solid and liquid ice‐forming particles during cirrus formation be predicted with confidence. Blending insights obtained from the research balloon measurements with theoretical methods developed in statistical physics, our study elaborates on the dynamical forcing issue by devising a model that represents air parcel cooling rates on a probabilistic basis. We thereby hope to contribute significantly to a comprehensive process understanding and, ultimately, to removing one of the roadblocks in cloud research. Key Points A probabilistic model for gravity wave‐induced mesoscale temperature fluctuations is developed based on observations A relationship between wave‐induced temperature and associated cooling/heating rate fluctuation amplitudes is derived It is shown how wave effects can be included in microphysical simulation models and global model parameterizations</abstract><cop>Washington</cop><pub>Blackwell Publishing Ltd</pub><doi>10.1029/2019JD030680</doi><tpages>24</tpages><orcidid>https://orcid.org/0000-0003-0278-4980</orcidid><oa>free_for_read</oa></addata></record>
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subjects	Aerosols Air parcels Atmospheric models Balloon measurements Balloon observations Balloons Cirrus clouds Climate models Computer simulation Confidence Cooling Cooling rate Coriolis force Damping Duration Equatorial regions Fluctuations Geophysics Gravitational waves Gravity Gravity waves Ice Ice clouds Ice crystal formation Ice crystals Ice formation Measurement methods Mesoscale gravity waves Mesoscale phenomena Meteorological balloons Nucleation Physics Probabilistic models Probability theory Properties Saturation Sciences of the Universe Statistical analysis Statistical methods Stratification Temperature Temperature fluctuations Uncertainty Updraft Vertical wind velocities Wind Wind speed
title	A Stochastic Representation of Temperature Fluctuations Induced by Mesoscale Gravity Waves
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