The ion–ion recombination coefficient α : comparison of temperature- and pressure-dependent parameterisations for the troposphere and stratosphere
Many different atmospheric, physical, and chemical processes are affected by ions. An important sink for atmospheric ions is the reaction and mutual neutralisation of a positive and negative ion, also called ion–ion recombination. While the value for the ion–ion recombination coefficient α is well-k...
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| Published in | Atmospheric chemistry and physics Vol. 22; no. 18; pp. 12443 - 12465 |
|---|---|
| Main Authors | , , |
| Format | Journal Article |
| Language | English |
| Published |
Katlenburg-Lindau
Copernicus GmbH
22.09.2022
Copernicus Publications |
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| Online Access | Get full text |
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| Abstract | Many different atmospheric, physical, and chemical
processes are affected by ions. An important sink for atmospheric ions is
the reaction and mutual neutralisation of a positive and negative ion, also
called ion–ion recombination. While the value for the ion–ion recombination coefficient α is well-known for standard conditions (namely 1.7 × 10−6 cm3 s−1), it needs to be calculated for deviating temperature and pressure conditions, especially for applications at higher altitudes of the atmosphere. In this work, we review the history of theories and parameterisations of the ion–ion recombination coefficient, focussing on the temperature and pressure dependencies as well as the altitude range between 0 and 50 km. Commencing with theories based on J. J. Thomson's work, we describe important semi-empirical adjustments as well as
field, model, and laboratory data sets, followed by short reviews of binary
recombination theories, model simulations, and the application of
ion–aerosol theories to ion–ion recombination. We present a comparison
between theories, parameterisations, and field, model, and laboratory data sets to conclude favourable parameterisations. While many theories agree well with field data above an altitude of approximately 10 km, the nature of the recombination coefficient is still widely unknown between Earth's surface and an altitude of 10 km. According to the current state of knowledge, it appears reasonable to assume an almost constant value for the recombination coefficient for this region, while it is necessary to use values that are adjusted for pressure and temperature for altitudes above 10 km. Suitable parameterisations for different altitude ranges are presented and the need for future research, be it in the laboratory or by means of modelling, is identified. |
|---|---|
| AbstractList | Many different atmospheric, physical, and chemical processes are affected by ions. An important sink for atmospheric ions is the reaction and mutual neutralisation of a positive and negative ion, also called ion–ion recombination. While the value for the ion–ion recombination coefficient α is well-known for standard conditions (namely 1.7 × 10 −6 cm 3 s −1 ), it needs to be calculated for deviating temperature and pressure conditions, especially for applications at higher altitudes of the atmosphere. In this work, we review the history of theories and parameterisations of the ion–ion recombination coefficient, focussing on the temperature and pressure dependencies as well as the altitude range between 0 and 50 km. Commencing with theories based on J. J. Thomson's work, we describe important semi-empirical adjustments as well as field, model, and laboratory data sets, followed by short reviews of binary recombination theories, model simulations, and the application of ion–aerosol theories to ion–ion recombination. We present a comparison between theories, parameterisations, and field, model, and laboratory data sets to conclude favourable parameterisations. While many theories agree well with field data above an altitude of approximately 10 km, the nature of the recombination coefficient is still widely unknown between Earth's surface and an altitude of 10 km. According to the current state of knowledge, it appears reasonable to assume an almost constant value for the recombination coefficient for this region, while it is necessary to use values that are adjusted for pressure and temperature for altitudes above 10 km. Suitable parameterisations for different altitude ranges are presented and the need for future research, be it in the laboratory or by means of modelling, is identified. Many different atmospheric, physical, and chemical processes are affected by ions. An important sink for atmospheric ions is the reaction and mutual neutralisation of a positive and negative ion, also called ion–ion recombination. While the value for the ion–ion recombination coefficient α is well-known for standard conditions (namely 1.7 × 10−6 cm3 s−1), it needs to be calculated for deviating temperature and pressure conditions, especially for applications at higher altitudes of the atmosphere. In this work, we review the history of theories and parameterisations of the ion–ion recombination coefficient, focussing on the temperature and pressure dependencies as well as the altitude range between 0 and 50 km. Commencing with theories based on J. J. Thomson's work, we describe important semi-empirical adjustments as well as field, model, and laboratory data sets, followed by short reviews of binary recombination theories, model simulations, and the application of ion–aerosol theories to ion–ion recombination. We present a comparison between theories, parameterisations, and field, model, and laboratory data sets to conclude favourable parameterisations. While many theories agree well with field data above an altitude of approximately 10 km, the nature of the recombination coefficient is still widely unknown between Earth's surface and an altitude of 10 km. According to the current state of knowledge, it appears reasonable to assume an almost constant value for the recombination coefficient for this region, while it is necessary to use values that are adjusted for pressure and temperature for altitudes above 10 km. Suitable parameterisations for different altitude ranges are presented and the need for future research, be it in the laboratory or by means of modelling, is identified. Many different atmospheric, physical, and chemical processes are affected by ions. An important sink for atmospheric ions is the reaction and mutual neutralisation of a positive and negative ion, also called ion–ion recombination. While the value for the ion–ion recombination coefficient α is well-known for standard conditions (namely 1.7 × 10-6 cm3 s-1), it needs to be calculated for deviating temperature and pressure conditions, especially for applications at higher altitudes of the atmosphere. In this work, we review the history of theories and parameterisations of the ion–ion recombination coefficient, focussing on the temperature and pressure dependencies as well as the altitude range between 0 and 50 km. Commencing with theories based on J. J. Thomson's work, we describe important semi-empirical adjustments as well as field, model, and laboratory data sets, followed by short reviews of binary recombination theories, model simulations, and the application of ion–aerosol theories to ion–ion recombination. We present a comparison between theories, parameterisations, and field, model, and laboratory data sets to conclude favourable parameterisations. While many theories agree well with field data above an altitude of approximately 10 km, the nature of the recombination coefficient is still widely unknown between Earth's surface and an altitude of 10 km. According to the current state of knowledge, it appears reasonable to assume an almost constant value for the recombination coefficient for this region, while it is necessary to use values that are adjusted for pressure and temperature for altitudes above 10 km. Suitable parameterisations for different altitude ranges are presented and the need for future research, be it in the laboratory or by means of modelling, is identified. |
| Author | Kürten, Andreas Zauner-Wieczorek, Marcel Curtius, Joachim |
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| Cites_doi | 10.1063/1.437364 10.1016/0032-0633(77)90075-7 10.1098/rspa.1978.0043 10.1007/BF01993343 10.1103/PhysRevE.85.026410 10.1039/D0CP03989F 10.1080/14786442408634372 10.5636/jgg.35.29 10.1039/df9603000100 10.1016/0009-2614(80)80335-6 10.1016/0032-0633(84)90151-X 10.1080/02786826.2013.783684 10.1016/S0016-0032(29)91182-0 10.1080/14786449608620932 10.1103/PhysRev.53.75 10.1080/02786829008959441 10.5194/acp-11-767-2011 10.1063/1.459947 10.1063/1.5144772 10.1007/978-0-387-87664-1_10 10.1098/rspa.1913.0046 10.1525/9780520348936 10.1007/BF01341939 10.1007/978-3-642-85294-7_9 10.1029/GL009i009p01085 10.1007/BF00874674 10.1080/02786828608959073 10.1063/1.4879780 10.1063/1.4862151 10.1063/1.1712281 10.1103/PhysRevE.50.3994 10.1016/0021-8502(93)90029-9 10.1098/rspa.1938.0196 10.1063/1.4913829 10.1007/s10712-004-5439-8 10.1063/1.3520150 10.1029/JC086iC08p07406 10.1063/1.4720499 10.5194/acp-15-7203-2015 10.1063/1.456349 10.5194/acp-2021-795 10.1038/283055a0 10.1016/0032-0633(82)90101-5 10.1016/S0065-2199(08)60264-X 10.5194/acp-14-9233-2014 10.1063/1.1696317 10.1038/315307a0 |
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| Snippet | Many different atmospheric, physical, and chemical
processes are affected by ions. An important sink for atmospheric ions is
the reaction and mutual... Many different atmospheric, physical, and chemical processes are affected by ions. An important sink for atmospheric ions is the reaction and mutual... |
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| SubjectTerms | Aerosols Altitude Anions Atmosphere Chemical reactions Cosmic rays Datasets Earth surface Gases Ion recombination Ions Laboratories Measurement techniques Modelling Negative ions Pressure Pressure dependence Recombination Recombination coefficient Stratosphere Temperature Temperature dependence Theories Troposphere |
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| Title | The ion–ion recombination coefficient α : comparison of temperature- and pressure-dependent parameterisations for the troposphere and stratosphere |
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