Improving ECC Ozonesonde Data Quality: Assessment of Current Methods and Outstanding Issues
We review the current state of knowledge of ozonesonde uncertainty and bias, with reference to recent developments in laboratory and field experiments. In the past 20 years ozonesonde precision has improved by a factor of 2, primarily through the adoption of strict standard operating procedures. The...
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| Published in | Earth and Space Science Vol. 8; no. 3 |
|---|---|
| Main Authors | , , , , , , , , , , , , |
| Format | Book Review Journal Article |
| Language | English |
| Published |
Hoboken
John Wiley & Sons, Inc
01.03.2021
American Geophysical Union (AGU) |
| Subjects | |
| Online Access | Get full text |
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| Abstract | We review the current state of knowledge of ozonesonde uncertainty and bias, with reference to recent developments in laboratory and field experiments. In the past 20 years ozonesonde precision has improved by a factor of 2, primarily through the adoption of strict standard operating procedures. The uncertainty budget for the ozone partial pressure reading has contributions from stoichiometry, cell background current, pump efficiency and temperature, sensing solution type, and volume. Corrections to historical data for known issues may reduce biases but simultaneously introduce additional uncertainties. This paper describes a systematic approach to quantifying these uncertainties by considering the physical and chemical processes involved and attempts to place our estimates on a firm theoretical or empirical footing. New equations or tables for ozone/iodine conversion efficiency, humidity and temperature corrections to pump flow rate, and altitude‐dependent pump flow corrections are presented, as well as detailed discussion of stoichiometry and conversion efficiencies. The nature of the so‐called “background current” is considered in detail. Two other factors particularly affecting past measurements, uncertainties and biases in the pressure measurement, and the comparison of sonde profiles to spectrophotometric measurements of total column ozone, are also discussed. Several quality assurance issues remain, but are tractable problems that can be addressed with further research. This will be required if the present goal of better than 5% overall uncertainty throughout the global ozonesonde network is to be achieved.
Plain Language Summary
Ozonesondes are a stable reference for the global ozone observing network, making relatively inexpensive, accurate measurements of ozone from the ground to 30 km, with high vertical resolution, for more than 50 years. Ozonesonde data are used extensively for validation of satellite ozone measurements, models, and for trend analyses. The current state of knowledge of ozonesonde uncertainty and bias is reviewed, and a systematic approach to quantifying these uncertainties by considering the physical and chemical processes involved is presented. While ozonesonde precision has improved through the adoption of strict standard operating procedures, further improvement is possible with further research, toward a goal of less than 5% overall uncertainty throughout the global network.
Key Points
Review of the current state of knowledge of ozonesonde uncertainty and bias
A systematic approach to quantifying these uncertainties by considering the physical and chemical processes involved
Uncertainties related to stoichiometry and sensor response may be reduced with further research, toward a goal of less than 5% uncertainty in the global network |
|---|---|
| AbstractList | We review the current state of knowledge of ozonesonde uncertainty and bias, with reference to recent developments in laboratory and field experiments. In the past 20 years ozonesonde precision has improved by a factor of 2, primarily through the adoption of strict standard operating procedures. The uncertainty budget for the ozone partial pressure reading has contributions from stoichiometry, cell background current, pump efficiency and temperature, sensing solution type, and volume. Corrections to historical data for known issues may reduce biases but simultaneously introduce additional uncertainties. This paper describes a systematic approach to quantifying these uncertainties by considering the physical and chemical processes involved and attempts to place our estimates on a firm theoretical or empirical footing. New equations or tables for ozone/iodine conversion efficiency, humidity and temperature corrections to pump flow rate, and altitude‐dependent pump flow corrections are presented, as well as detailed discussion of stoichiometry and conversion efficiencies. The nature of the so‐called “background current” is considered in detail. Two other factors particularly affecting past measurements, uncertainties and biases in the pressure measurement, and the comparison of sonde profiles to spectrophotometric measurements of total column ozone, are also discussed. Several quality assurance issues remain, but are tractable problems that can be addressed with further research. This will be required if the present goal of better than 5% overall uncertainty throughout the global ozonesonde network is to be achieved. We review the current state of knowledge of ozonesonde uncertainty and bias, with reference to recent developments in laboratory and field experiments. In the past 20 years ozonesonde precision has improved by a factor of 2, primarily through the adoption of strict standard operating procedures. The uncertainty budget for the ozone partial pressure reading has contributions from stoichiometry, cell background current, pump efficiency and temperature, sensing solution type, and volume. Corrections to historical data for known issues may reduce biases but simultaneously introduce additional uncertainties. This paper describes a systematic approach to quantifying these uncertainties by considering the physical and chemical processes involved and attempts to place our estimates on a firm theoretical or empirical footing. New equations or tables for ozone/iodine conversion efficiency, humidity and temperature corrections to pump flow rate, and altitude‐dependent pump flow corrections are presented, as well as detailed discussion of stoichiometry and conversion efficiencies. The nature of the so‐called “background current” is considered in detail. Two other factors particularly affecting past measurements, uncertainties and biases in the pressure measurement, and the comparison of sonde profiles to spectrophotometric measurements of total column ozone, are also discussed. Several quality assurance issues remain, but are tractable problems that can be addressed with further research. This will be required if the present goal of better than 5% overall uncertainty throughout the global ozonesonde network is to be achieved. Plain Language Summary Ozonesondes are a stable reference for the global ozone observing network, making relatively inexpensive, accurate measurements of ozone from the ground to 30 km, with high vertical resolution, for more than 50 years. Ozonesonde data are used extensively for validation of satellite ozone measurements, models, and for trend analyses. The current state of knowledge of ozonesonde uncertainty and bias is reviewed, and a systematic approach to quantifying these uncertainties by considering the physical and chemical processes involved is presented. While ozonesonde precision has improved through the adoption of strict standard operating procedures, further improvement is possible with further research, toward a goal of less than 5% overall uncertainty throughout the global network. Key Points Review of the current state of knowledge of ozonesonde uncertainty and bias A systematic approach to quantifying these uncertainties by considering the physical and chemical processes involved Uncertainties related to stoichiometry and sensor response may be reduced with further research, toward a goal of less than 5% uncertainty in the global network Abstract We review the current state of knowledge of ozonesonde uncertainty and bias, with reference to recent developments in laboratory and field experiments. In the past 20 years ozonesonde precision has improved by a factor of 2, primarily through the adoption of strict standard operating procedures. The uncertainty budget for the ozone partial pressure reading has contributions from stoichiometry, cell background current, pump efficiency and temperature, sensing solution type, and volume. Corrections to historical data for known issues may reduce biases but simultaneously introduce additional uncertainties. This paper describes a systematic approach to quantifying these uncertainties by considering the physical and chemical processes involved and attempts to place our estimates on a firm theoretical or empirical footing. New equations or tables for ozone/iodine conversion efficiency, humidity and temperature corrections to pump flow rate, and altitude‐dependent pump flow corrections are presented, as well as detailed discussion of stoichiometry and conversion efficiencies. The nature of the so‐called “background current” is considered in detail. Two other factors particularly affecting past measurements, uncertainties and biases in the pressure measurement, and the comparison of sonde profiles to spectrophotometric measurements of total column ozone, are also discussed. Several quality assurance issues remain, but are tractable problems that can be addressed with further research. This will be required if the present goal of better than 5% overall uncertainty throughout the global ozonesonde network is to be achieved. Abstract We review the current state of knowledge of ozonesonde uncertainty and bias, with reference to recent developments in laboratory and field experiments. In the past 20 years ozonesonde precision has improved by a factor of 2, primarily through the adoption of strict standard operating procedures. The uncertainty budget for the ozone partial pressure reading has contributions from stoichiometry, cell background current, pump efficiency and temperature, sensing solution type, and volume. Corrections to historical data for known issues may reduce biases but simultaneously introduce additional uncertainties. This paper describes a systematic approach to quantifying these uncertainties by considering the physical and chemical processes involved and attempts to place our estimates on a firm theoretical or empirical footing. New equations or tables for ozone/iodine conversion efficiency, humidity and temperature corrections to pump flow rate, and altitude‐dependent pump flow corrections are presented, as well as detailed discussion of stoichiometry and conversion efficiencies. The nature of the so‐called “background current” is considered in detail. Two other factors particularly affecting past measurements, uncertainties and biases in the pressure measurement, and the comparison of sonde profiles to spectrophotometric measurements of total column ozone, are also discussed. Several quality assurance issues remain, but are tractable problems that can be addressed with further research. This will be required if the present goal of better than 5% overall uncertainty throughout the global ozonesonde network is to be achieved. Plain Language Summary Ozonesondes are a stable reference for the global ozone observing network, making relatively inexpensive, accurate measurements of ozone from the ground to 30 km, with high vertical resolution, for more than 50 years. Ozonesonde data are used extensively for validation of satellite ozone measurements, models, and for trend analyses. The current state of knowledge of ozonesonde uncertainty and bias is reviewed, and a systematic approach to quantifying these uncertainties by considering the physical and chemical processes involved is presented. While ozonesonde precision has improved through the adoption of strict standard operating procedures, further improvement is possible with further research, toward a goal of less than 5% overall uncertainty throughout the global network. Key Points Review of the current state of knowledge of ozonesonde uncertainty and bias A systematic approach to quantifying these uncertainties by considering the physical and chemical processes involved Uncertainties related to stoichiometry and sensor response may be reduced with further research, toward a goal of less than 5% uncertainty in the global network |
| Author | Nakano, Tatsumi Van Malderen, Roeland Witte, Jacquelyn C. Oltmans, Samuel J. Stübi, Rene Davies, Jonathan Thompson, Anne M. Vömel, Holger Stauffer, Ryan M. Tarasick, David W. Smit, Herman G. J. Morris, Gary A. Johnson, Bryan J. |
| Author_xml | – sequence: 1 givenname: David W. orcidid: 0000-0001-9869-0692 surname: Tarasick fullname: Tarasick, David W. email: david.tarasick@canada.ca organization: Environment and Climate Change Canada – sequence: 2 givenname: Herman G. J. surname: Smit fullname: Smit, Herman G. J. organization: Research Centre Juelich (FZJ) – sequence: 3 givenname: Anne M. orcidid: 0000-0002-7829-0920 surname: Thompson fullname: Thompson, Anne M. organization: NASA Goddard Space Flight Center – sequence: 4 givenname: Gary A. surname: Morris fullname: Morris, Gary A. organization: St. Edward's University – sequence: 5 givenname: Jacquelyn C. orcidid: 0000-0002-4110-5277 surname: Witte fullname: Witte, Jacquelyn C. organization: National Center for Atmospheric Research – sequence: 6 givenname: Jonathan surname: Davies fullname: Davies, Jonathan organization: Environment and Climate Change Canada – sequence: 7 givenname: Tatsumi surname: Nakano fullname: Nakano, Tatsumi organization: Japan Meteorological Agency – sequence: 8 givenname: Roeland orcidid: 0000-0002-1369-8853 surname: Van Malderen fullname: Van Malderen, Roeland organization: Royal Meteorological Institute of Belgium – sequence: 9 givenname: Ryan M. orcidid: 0000-0002-8583-7795 surname: Stauffer fullname: Stauffer, Ryan M. organization: NASA Goddard Space Flight Center and University of Maryland Earth System Science Interdisciplinary Center – sequence: 10 givenname: Bryan J. orcidid: 0000-0002-7268-9957 surname: Johnson fullname: Johnson, Bryan J. organization: NOAA/ESRL Global Monitoring Division – sequence: 11 givenname: Rene surname: Stübi fullname: Stübi, Rene organization: Federal Office of Meteorology and Climatology MeteoSwiss – sequence: 12 givenname: Samuel J. orcidid: 0000-0002-7390-2553 surname: Oltmans fullname: Oltmans, Samuel J. organization: NOAA/ESRL Global Monitoring Division – sequence: 13 givenname: Holger orcidid: 0000-0003-1223-3429 surname: Vömel fullname: Vömel, Holger organization: National Center for Atmospheric Research |
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| Copyright | 2021 Her Majesty the Queen in Right of Canada. Reproduced with the permission of the Minister of Environment and Climate Change Canada. This article has been contributed to by US Government employees and their work is in the public domain in the USA. 2021. This work is published under http://creativecommons.org/licenses/by-nc/4.0/ (the “License”). Notwithstanding the ProQuest Terms and Conditions, you may use this content in accordance with the terms of the License. |
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| Publisher | John Wiley & Sons, Inc American Geophysical Union (AGU) |
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| Score | 2.3282123 |
| Snippet | We review the current state of knowledge of ozonesonde uncertainty and bias, with reference to recent developments in laboratory and field experiments. In the... Abstract We review the current state of knowledge of ozonesonde uncertainty and bias, with reference to recent developments in laboratory and field... Abstract We review the current state of knowledge of ozonesonde uncertainty and bias, with reference to recent developments in laboratory and field... |
| SourceID | doaj proquest crossref wiley |
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| SubjectTerms | Aircraft Archives & records data quality Datasets Emission measurements Field tests Flow rates Historical account Iodine Ozone ozonesonde Pressure measurement Quality assurance Satellites Sensors Stratosphere Temperature Trends uncertainty validation |
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| Title | Improving ECC Ozonesonde Data Quality: Assessment of Current Methods and Outstanding Issues |
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