Deconvolution-based resolution enhancement of chemical ice core records obtained by continuous flow analysis

Sune Olander Rasmussen; Katrine K. Andersen; Sigfus Johann Johnsen; Matthias Bigler; T. McCormack

Deconvolution-based resolution enhancement of chemical ice core records obtained by continuous flow analysis

Sune Olander Rasmussen, Katrine K. Andersen, Sigfus Johann Johnsen, Matthias Bigler, T. McCormack

13 Citations (Scopus)

805 Downloads (Pure)

Abstract

Continuous flow analysis (CFA) has become a popular measuring technique for obtaining high-resolution chemical ice core records due to an attractive combination of measuring speed and resolution. However, when analyzing the deeper sections of ice cores or cores from low-accumulation areas, there is still need for further improvement of the resolution. Here a method for resolution enhancement of CFA data is presented. It is demonstrated that it is possible to improve the resolution of CFA data by restoring some of the detail that was lost in the measuring process, thus improving the usefulness of the data for high-resolution studies such as annual layer counting. The presented method
uses deconvolution techniques and is robust to the presence of noise in the measurements. If integrated into the data processing, it requires no additional data collection. The method is applied to selected ice core data sequences from Greenland and Antarctica, and the results demonstrate that the data quality can be significantly improved.

Original language	English
Journal	Journal of Geophysical Research - Oceans
Volume	110
Issue number	D17304
Pages (from-to)	D17304
ISSN	2169-9003
Publication status	Published - 2005

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title = "Deconvolution-based resolution enhancement of chemical ice core records obtained by continuous flow analysis",

abstract = "Continuous flow analysis (CFA) has become a popular measuring technique for obtaining high-resolution chemical ice core records due to an attractive combination of measuring speed and resolution. However, when analyzing the deeper sections of ice cores or cores from low-accumulation areas, there is still need for further improvement of the resolution. Here a method for resolution enhancement of CFA data is presented. It is demonstrated that it is possible to improve the resolution of CFA data by restoring some of the detail that was lost in the measuring process, thus improving the usefulness of the data for high-resolution studies such as annual layer counting. The presented methoduses deconvolution techniques and is robust to the presence of noise in the measurements. If integrated into the data processing, it requires no additional data collection. The method is applied to selected ice core data sequences from Greenland and Antarctica, and the results demonstrate that the data quality can be significantly improved.",

author = "Rasmussen, {Sune Olander} and Andersen, {Katrine K.} and Johnsen, {Sigfus Johann} and Matthias Bigler and T. McCormack",

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TY - JOUR

T1 - Deconvolution-based resolution enhancement of chemical ice core records obtained by continuous flow analysis

AU - Rasmussen, Sune Olander

AU - Andersen, Katrine K.

AU - Johnsen, Sigfus Johann

AU - Bigler, Matthias

AU - McCormack, T.

N1 - Paper id:: doi:10.1029/2004JD005717

PY - 2005

Y1 - 2005

N2 - Continuous flow analysis (CFA) has become a popular measuring technique for obtaining high-resolution chemical ice core records due to an attractive combination of measuring speed and resolution. However, when analyzing the deeper sections of ice cores or cores from low-accumulation areas, there is still need for further improvement of the resolution. Here a method for resolution enhancement of CFA data is presented. It is demonstrated that it is possible to improve the resolution of CFA data by restoring some of the detail that was lost in the measuring process, thus improving the usefulness of the data for high-resolution studies such as annual layer counting. The presented methoduses deconvolution techniques and is robust to the presence of noise in the measurements. If integrated into the data processing, it requires no additional data collection. The method is applied to selected ice core data sequences from Greenland and Antarctica, and the results demonstrate that the data quality can be significantly improved.

AB - Continuous flow analysis (CFA) has become a popular measuring technique for obtaining high-resolution chemical ice core records due to an attractive combination of measuring speed and resolution. However, when analyzing the deeper sections of ice cores or cores from low-accumulation areas, there is still need for further improvement of the resolution. Here a method for resolution enhancement of CFA data is presented. It is demonstrated that it is possible to improve the resolution of CFA data by restoring some of the detail that was lost in the measuring process, thus improving the usefulness of the data for high-resolution studies such as annual layer counting. The presented methoduses deconvolution techniques and is robust to the presence of noise in the measurements. If integrated into the data processing, it requires no additional data collection. The method is applied to selected ice core data sequences from Greenland and Antarctica, and the results demonstrate that the data quality can be significantly improved.

M3 - Journal article

SN - 2169-9003

VL - 110

SP - D17304

JO - Journal of Geophysical Research - Oceans

JF - Journal of Geophysical Research - Oceans

IS - D17304

ER -

Deconvolution-based resolution enhancement of chemical ice core records obtained by continuous flow analysis

Abstract

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