Technical note: Update on response times, in-air measurements, and in situ drift for oxygen optodes on profiling platforms
Oxygen optode measurements on floats and gliders suffer from a slow time response and various sources of drift in the calibration coefficients. Based on two dual-O<sub>2</sub> Argo floats, we show how to post-correct for the effect of the optode's time response and give an update on...
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Copernicus Publications
2017-01-01
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| Series: | Ocean Science |
| Online Access: | http://www.ocean-sci.net/13/1/2017/os-13-1-2017.pdf |
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doaj-c92b7d1807c6497ca7c7c206fa0a10992020-11-25T01:31:54ZengCopernicus PublicationsOcean Science1812-07841812-07922017-01-0113111110.5194/os-13-1-2017Technical note: Update on response times, in-air measurements, and in situ drift for oxygen optodes on profiling platformsH. C. Bittig0A. Körtzinger1Sorbonne Universités, UPMC Université Paris 06, CNRS, UMR 7093, Laboratoire d'Océanographie de Villefranche (LOV), Villefranche-sur-Mer, FranceGEOMAR Helmholtz-Zentrum für Ozeanforschung Kiel, Kiel, GermanyOxygen optode measurements on floats and gliders suffer from a slow time response and various sources of drift in the calibration coefficients. Based on two dual-O<sub>2</sub> Argo floats, we show how to post-correct for the effect of the optode's time response and give an update on optode in situ drift stability and in-air calibration. Both floats are equipped with an unpumped Aanderaa 4330 optode and a pumped Sea-Bird SBE63 optode. Response times for the pumped SBE63 were derived following Bittig et al. (2014) and the same methods were used to correct the time response bias. Using both optodes on each float, the time response regime of the unpumped Aanderaa optode was characterized more accurately than previously possible. Response times for the pumped SBE63 on profiling floats are in the range of 25–40 s, while they are between 60 and 95 s for the unpumped 4330 optode. Our parameterization can be employed to post-correct the slow optode time response on floats and gliders. After correction, both sensors agree to within 2–3 µmol kg<sup>−1</sup> (median difference) in the strongest gradients (120 µmol kg<sup>−1</sup> change over 8 min or 20 dbar) and better elsewhere. However, time response correction is only possible if measurement times are known, i.e., provided by the platform as well as transmitted and stored with the data. The O<sub>2</sub> in-air measurements show a significant in situ optode drift of −0.40 and −0.27 % yr<sup>−1</sup> over the available 2 and 3 years of deployment, respectively. Optode in-air measurements are systematically biased high during midday surfacings compared to dusk, dawn, and nighttime. While preference can be given to nighttime surfacings to avoid this in-air calibration bias, we suggest a parameterization of the daytime effect as a function of the Sun's elevation to be able to use all data and to better constrain the result. Taking all effects into account, calibration factors have an uncertainty of 0.1 %. In addition, in-air calibration factors vary by 0.1–0.2 % when using different reanalysis models as a reference. The overall accuracy that can be achieved following the proposed correction routines is better than 1 µmol kg<sup>−1</sup>.http://www.ocean-sci.net/13/1/2017/os-13-1-2017.pdf |
| collection |
DOAJ |
| language |
English |
| format |
Article |
| sources |
DOAJ |
| author |
H. C. Bittig A. Körtzinger |
| spellingShingle |
H. C. Bittig A. Körtzinger Technical note: Update on response times, in-air measurements, and in situ drift for oxygen optodes on profiling platforms Ocean Science |
| author_facet |
H. C. Bittig A. Körtzinger |
| author_sort |
H. C. Bittig |
| title |
Technical note: Update on response times, in-air measurements, and in situ drift for oxygen optodes on profiling platforms |
| title_short |
Technical note: Update on response times, in-air measurements, and in situ drift for oxygen optodes on profiling platforms |
| title_full |
Technical note: Update on response times, in-air measurements, and in situ drift for oxygen optodes on profiling platforms |
| title_fullStr |
Technical note: Update on response times, in-air measurements, and in situ drift for oxygen optodes on profiling platforms |
| title_full_unstemmed |
Technical note: Update on response times, in-air measurements, and in situ drift for oxygen optodes on profiling platforms |
| title_sort |
technical note: update on response times, in-air measurements, and in situ drift for oxygen optodes on profiling platforms |
| publisher |
Copernicus Publications |
| series |
Ocean Science |
| issn |
1812-0784 1812-0792 |
| publishDate |
2017-01-01 |
| description |
Oxygen optode measurements on floats and gliders suffer from a
slow time response and various sources of drift in the calibration
coefficients. Based on two dual-O<sub>2</sub> Argo floats, we show how to
post-correct for the effect of the optode's time response and give an update
on optode in situ drift stability and in-air calibration. Both floats are
equipped with an unpumped Aanderaa 4330 optode and a pumped Sea-Bird SBE63
optode. Response times for the pumped SBE63 were derived following Bittig et
al. (2014) and the same methods were used to correct the time response bias.
Using both optodes on each float, the time response regime of the unpumped
Aanderaa optode was characterized more accurately than previously possible.
Response times for the pumped SBE63 on profiling floats are in the range of
25–40 s, while they are between 60 and 95 s for the unpumped
4330 optode. Our parameterization can be employed to post-correct the slow
optode time response on floats and gliders. After correction, both sensors
agree to within 2–3 µmol kg<sup>−1</sup> (median difference) in the
strongest gradients (120 µmol kg<sup>−1</sup> change over 8 min or
20 dbar) and better elsewhere. However, time response correction is
only possible if measurement times are known, i.e., provided by the platform
as well as transmitted and stored with the data. The O<sub>2</sub> in-air
measurements show a significant in situ optode drift of −0.40 and
−0.27 % yr<sup>−1</sup> over the available 2 and 3 years of
deployment, respectively. Optode in-air measurements are systematically
biased high during midday surfacings compared to dusk, dawn, and nighttime.
While preference can be given to nighttime surfacings to avoid this in-air
calibration bias, we suggest a parameterization of the daytime effect as a
function of the Sun's elevation to be able to use all data and to better
constrain the result. Taking all effects into account, calibration factors
have an uncertainty of 0.1 %. In addition, in-air calibration
factors vary by 0.1–0.2 % when using different reanalysis models as
a reference. The overall accuracy that can be achieved following the proposed
correction routines is better than 1 µmol kg<sup>−1</sup>. |
| url |
http://www.ocean-sci.net/13/1/2017/os-13-1-2017.pdf |
| work_keys_str_mv |
AT hcbittig technicalnoteupdateonresponsetimesinairmeasurementsandinsitudriftforoxygenoptodesonprofilingplatforms AT akortzinger technicalnoteupdateonresponsetimesinairmeasurementsandinsitudriftforoxygenoptodesonprofilingplatforms |
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