Cloud chemistry measurements and estimates of acidic deposition on an above cloudbase coniferous forest

V. K. Saxena; N. H. Lin

doi:10.1016/0960-1686(90)90113-2

Cloud chemistry measurements and estimates of acidic deposition on an above cloudbase coniferous forest

V. K. Saxena, N. H. Lin

大氣科學學系

研究成果: 雜誌貢獻 › 期刊論文 › 同行評審

90 引文斯高帕斯（Scopus）

摘要

The wet, dry and cloud water deposition of acidic substances on the forest canopy are considered as major mechanisms for pollutant induced forest decline at high elevations. Direct cloud capture plays a predominant role of intercepting acidic substances in above cloud-base forests. We conducted a field study at Mt. Mitchell, North Carolina (35°44′05″N, 82°17′15″W; 2038 m MSL)-the highest peak in the eastern U.S.-during May-September 1986 and 1987 in order to analyze the chemistry of clouds in which the red spruce and Fraser fir stands stay immersed. It was found that Mt. Mitchell was exposed to cloud episodes 71% of summer days, the cloud immersion time being 28% for 1986 (a record drought summer in southeastern U.S.) and 41% for 1987. Sulfate, NO₃^-, NH₄⁺ and H⁺ ions were found to be the major constituents of the cloud water, which was collected atop a 16.5 m tall meteorological tower situated among 6-7 m tall Fraser fir trees. The initiation of precipitation in clouds invariably diluted the cloud water acidity. The cloud water pH during short episodes (8 h duration or less), which resulted from the orographic lifting mechanisms, was substantially lower than that during long episodes, which were associated with meso-scale and synoptic-scale disturbances. Sulfate accounted for 65% acidity in cloud water, on the average, and contributed 2-3 times more than the NO₃^-. Inferential micrometeorological models were used to determine deposition of SO₄^2- and NO₃^- on the forest canopy and the hydrological input due to direct cloud capture mechanism. The cloud water deposition ranged between 32 and 55 cm a^-1 in contrast to the bulk precipitation which was about 130 cm a^-1 as measured by an on-site NADP (National Atmospheric Deposition Program) collector. For S compounds, wet, dry and cloud water deposition accounted for 19%, 11% and 70%, respectively for 1986, and 16%, 8% and 76%, respectively for 1987. For N compounds, dry deposition contributed 35% and 23% for 1986 and 1987, respectively, whereas, cloud water deposition contributed 50% and 65% for 1986 and 1987, respectively. Our estimates are compared with the reported literature values for the other sites.

原文	???core.languages.en_GB???
頁（從 - 到）	329-352
頁數	24
期刊	Atmospheric Environment Part A, General Topics
卷	24
發行號	2
DOIs	https://doi.org/10.1016/0960-1686(90)90113-2
出版狀態	已出版 - 1990

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10.1016/0960-1686(90)90113-2

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@article{ed4dbc27ccd0474ebcb5218bfe58832f,

title = "Cloud chemistry measurements and estimates of acidic deposition on an above cloudbase coniferous forest",

abstract = "The wet, dry and cloud water deposition of acidic substances on the forest canopy are considered as major mechanisms for pollutant induced forest decline at high elevations. Direct cloud capture plays a predominant role of intercepting acidic substances in above cloud-base forests. We conducted a field study at Mt. Mitchell, North Carolina (35°44′05″N, 82°17′15″W; 2038 m MSL)-the highest peak in the eastern U.S.-during May-September 1986 and 1987 in order to analyze the chemistry of clouds in which the red spruce and Fraser fir stands stay immersed. It was found that Mt. Mitchell was exposed to cloud episodes 71% of summer days, the cloud immersion time being 28% for 1986 (a record drought summer in southeastern U.S.) and 41% for 1987. Sulfate, NO3-, NH4+ and H+ ions were found to be the major constituents of the cloud water, which was collected atop a 16.5 m tall meteorological tower situated among 6-7 m tall Fraser fir trees. The initiation of precipitation in clouds invariably diluted the cloud water acidity. The cloud water pH during short episodes (8 h duration or less), which resulted from the orographic lifting mechanisms, was substantially lower than that during long episodes, which were associated with meso-scale and synoptic-scale disturbances. Sulfate accounted for 65% acidity in cloud water, on the average, and contributed 2-3 times more than the NO3-. Inferential micrometeorological models were used to determine deposition of SO42- and NO3- on the forest canopy and the hydrological input due to direct cloud capture mechanism. The cloud water deposition ranged between 32 and 55 cm a-1 in contrast to the bulk precipitation which was about 130 cm a-1 as measured by an on-site NADP (National Atmospheric Deposition Program) collector. For S compounds, wet, dry and cloud water deposition accounted for 19%, 11% and 70%, respectively for 1986, and 16%, 8% and 76%, respectively for 1987. For N compounds, dry deposition contributed 35% and 23% for 1986 and 1987, respectively, whereas, cloud water deposition contributed 50% and 65% for 1986 and 1987, respectively. Our estimates are compared with the reported literature values for the other sites.",

keywords = "cloud capture mechanism, cloud chemistry, cloud water acidity, coniferous forest, dry deposition, Wet deposition",

author = "Saxena, {V. K.} and Lin, {N. H.}",

note = "Funding Information: Acknowledgements--This study has been funded through cooperative agreements with the United States Environmental Protection Agency (agreement No. ESRL-CA-01 and contracts CRS 812444-01-0,-02-0, and -03-0 with the North Carolina State University). The contents of this paper do not necessarily reflect the views and the policies of the EPA, nor the views of all members of the Mountain Cloud Chemistry Project (MCCP) consortia, nor does the mention of trade names or commercial or non-commercial products constitute endorsement or recommendation for use. Professor Volker Mohnen is the Principal Investigator of the MCCP and the EPA project officer is Mr Ralph Baumgardner. In this study, Dr V. Aneja handled the logistics of making measurements during 1987 field season. Dr W. Robarge was responsible for the chemical analysis of the cloud water samples and for QA/QC of the data. The cloud deposition model codes were provided by Dr S. Mueller. Dr S. P. S. Arya reviewed parts of this paper. Professor Henry Brown was very helpful in straightening out the logistical support for the measurements and provided extremely helpful discussions. The authors also appreciate the help of Ms K. Joyner and Ms C. Saucer who provided the NADP precipitation data. The paper has not been subject to EPA policy review and the authors are solely responsible for its contents. The authors are also grateful to two anonymous reviewers for providing insightful comments that led to substantial strengthening the contents of this paper.",

year = "1990",

doi = "10.1016/0960-1686(90)90113-2",

language = "???core.languages.en_GB???",

volume = "24",

pages = "329--352",

journal = "Atmospheric Environment Part A, General Topics",

issn = "0960-1686",

number = "2",

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TY - JOUR

T1 - Cloud chemistry measurements and estimates of acidic deposition on an above cloudbase coniferous forest

AU - Saxena, V. K.

AU - Lin, N. H.

N1 - Funding Information: Acknowledgements--This study has been funded through cooperative agreements with the United States Environmental Protection Agency (agreement No. ESRL-CA-01 and contracts CRS 812444-01-0,-02-0, and -03-0 with the North Carolina State University). The contents of this paper do not necessarily reflect the views and the policies of the EPA, nor the views of all members of the Mountain Cloud Chemistry Project (MCCP) consortia, nor does the mention of trade names or commercial or non-commercial products constitute endorsement or recommendation for use. Professor Volker Mohnen is the Principal Investigator of the MCCP and the EPA project officer is Mr Ralph Baumgardner. In this study, Dr V. Aneja handled the logistics of making measurements during 1987 field season. Dr W. Robarge was responsible for the chemical analysis of the cloud water samples and for QA/QC of the data. The cloud deposition model codes were provided by Dr S. Mueller. Dr S. P. S. Arya reviewed parts of this paper. Professor Henry Brown was very helpful in straightening out the logistical support for the measurements and provided extremely helpful discussions. The authors also appreciate the help of Ms K. Joyner and Ms C. Saucer who provided the NADP precipitation data. The paper has not been subject to EPA policy review and the authors are solely responsible for its contents. The authors are also grateful to two anonymous reviewers for providing insightful comments that led to substantial strengthening the contents of this paper.

PY - 1990

Y1 - 1990

N2 - The wet, dry and cloud water deposition of acidic substances on the forest canopy are considered as major mechanisms for pollutant induced forest decline at high elevations. Direct cloud capture plays a predominant role of intercepting acidic substances in above cloud-base forests. We conducted a field study at Mt. Mitchell, North Carolina (35°44′05″N, 82°17′15″W; 2038 m MSL)-the highest peak in the eastern U.S.-during May-September 1986 and 1987 in order to analyze the chemistry of clouds in which the red spruce and Fraser fir stands stay immersed. It was found that Mt. Mitchell was exposed to cloud episodes 71% of summer days, the cloud immersion time being 28% for 1986 (a record drought summer in southeastern U.S.) and 41% for 1987. Sulfate, NO3-, NH4+ and H+ ions were found to be the major constituents of the cloud water, which was collected atop a 16.5 m tall meteorological tower situated among 6-7 m tall Fraser fir trees. The initiation of precipitation in clouds invariably diluted the cloud water acidity. The cloud water pH during short episodes (8 h duration or less), which resulted from the orographic lifting mechanisms, was substantially lower than that during long episodes, which were associated with meso-scale and synoptic-scale disturbances. Sulfate accounted for 65% acidity in cloud water, on the average, and contributed 2-3 times more than the NO3-. Inferential micrometeorological models were used to determine deposition of SO42- and NO3- on the forest canopy and the hydrological input due to direct cloud capture mechanism. The cloud water deposition ranged between 32 and 55 cm a-1 in contrast to the bulk precipitation which was about 130 cm a-1 as measured by an on-site NADP (National Atmospheric Deposition Program) collector. For S compounds, wet, dry and cloud water deposition accounted for 19%, 11% and 70%, respectively for 1986, and 16%, 8% and 76%, respectively for 1987. For N compounds, dry deposition contributed 35% and 23% for 1986 and 1987, respectively, whereas, cloud water deposition contributed 50% and 65% for 1986 and 1987, respectively. Our estimates are compared with the reported literature values for the other sites.

AB - The wet, dry and cloud water deposition of acidic substances on the forest canopy are considered as major mechanisms for pollutant induced forest decline at high elevations. Direct cloud capture plays a predominant role of intercepting acidic substances in above cloud-base forests. We conducted a field study at Mt. Mitchell, North Carolina (35°44′05″N, 82°17′15″W; 2038 m MSL)-the highest peak in the eastern U.S.-during May-September 1986 and 1987 in order to analyze the chemistry of clouds in which the red spruce and Fraser fir stands stay immersed. It was found that Mt. Mitchell was exposed to cloud episodes 71% of summer days, the cloud immersion time being 28% for 1986 (a record drought summer in southeastern U.S.) and 41% for 1987. Sulfate, NO3-, NH4+ and H+ ions were found to be the major constituents of the cloud water, which was collected atop a 16.5 m tall meteorological tower situated among 6-7 m tall Fraser fir trees. The initiation of precipitation in clouds invariably diluted the cloud water acidity. The cloud water pH during short episodes (8 h duration or less), which resulted from the orographic lifting mechanisms, was substantially lower than that during long episodes, which were associated with meso-scale and synoptic-scale disturbances. Sulfate accounted for 65% acidity in cloud water, on the average, and contributed 2-3 times more than the NO3-. Inferential micrometeorological models were used to determine deposition of SO42- and NO3- on the forest canopy and the hydrological input due to direct cloud capture mechanism. The cloud water deposition ranged between 32 and 55 cm a-1 in contrast to the bulk precipitation which was about 130 cm a-1 as measured by an on-site NADP (National Atmospheric Deposition Program) collector. For S compounds, wet, dry and cloud water deposition accounted for 19%, 11% and 70%, respectively for 1986, and 16%, 8% and 76%, respectively for 1987. For N compounds, dry deposition contributed 35% and 23% for 1986 and 1987, respectively, whereas, cloud water deposition contributed 50% and 65% for 1986 and 1987, respectively. Our estimates are compared with the reported literature values for the other sites.

KW - cloud capture mechanism

KW - cloud chemistry

KW - cloud water acidity

KW - coniferous forest

KW - dry deposition

KW - Wet deposition

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U2 - 10.1016/0960-1686(90)90113-2

DO - 10.1016/0960-1686(90)90113-2

M3 - 期刊論文

AN - SCOPUS:0025596387

VL - 24

SP - 329

EP - 352

JO - Atmospheric Environment Part A, General Topics

JF - Atmospheric Environment Part A, General Topics

SN - 0960-1686

IS - 2

ER -

Cloud chemistry measurements and estimates of acidic deposition on an above cloudbase coniferous forest

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