Using BiSON to detect solar internal g-modes

J. Kuszlewicz; G. R. Davies; W. J. Chaplin

doi:10.1051/epjconf/201510106041

Using BiSON to detect solar internal g-modes

J. Kuszlewicz, G. R. Davies, W. J. Chaplin

Physics and Astronomy

Research output: Contribution to journal › Conference article › peer-review

Abstract

The unambiguous detection of individual solar internal g modes continues to elude us. With the aid of new additions to calibration procedures, as well as updated methods to combine multi-site time series more effectively, the noise and signal detection threshold levels in the low-frequency domain (where the g modes are expected to be found) have been greatly improved. In the BiSON 23-year dataset these levels now rival those of GOLF, and with much greater frequency resolution available, due to the long time series, there is an opportunity to place more constraints on the upper limits of individual g mode amplitudes. Here we detail recent work dedicated to the challenges of observing low-frequency oscillations using a ground-based network, including the role of the window function as well as the effect of calibration on the low frequency domain.

Original language	English
Article number	06041
Journal	EPJ Web of Conferences
Volume	101
DOIs	https://doi.org/10.1051/epjconf/201510106041
Publication status	Published - 23 Sept 2015
Event	CoRoT Symposium 3, Kepler KASC-7 Joint Meeting on Space Photometry Revolution - Toulouse, France Duration: 6 Jul 2014 → 11 Jul 2014

Bibliographical note

Publisher Copyright:
© Owned by the authors, published by EDP Sciences, 2015.

ASJC Scopus subject areas

General Physics and Astronomy

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10.1051/epjconf/201510106041

Cite this

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title = "Using BiSON to detect solar internal g-modes",

abstract = "The unambiguous detection of individual solar internal g modes continues to elude us. With the aid of new additions to calibration procedures, as well as updated methods to combine multi-site time series more effectively, the noise and signal detection threshold levels in the low-frequency domain (where the g modes are expected to be found) have been greatly improved. In the BiSON 23-year dataset these levels now rival those of GOLF, and with much greater frequency resolution available, due to the long time series, there is an opportunity to place more constraints on the upper limits of individual g mode amplitudes. Here we detail recent work dedicated to the challenges of observing low-frequency oscillations using a ground-based network, including the role of the window function as well as the effect of calibration on the low frequency domain.",

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AU - Kuszlewicz, J.

AU - Davies, G. R.

AU - Chaplin, W. J.

PY - 2015/9/23

Y1 - 2015/9/23

N2 - The unambiguous detection of individual solar internal g modes continues to elude us. With the aid of new additions to calibration procedures, as well as updated methods to combine multi-site time series more effectively, the noise and signal detection threshold levels in the low-frequency domain (where the g modes are expected to be found) have been greatly improved. In the BiSON 23-year dataset these levels now rival those of GOLF, and with much greater frequency resolution available, due to the long time series, there is an opportunity to place more constraints on the upper limits of individual g mode amplitudes. Here we detail recent work dedicated to the challenges of observing low-frequency oscillations using a ground-based network, including the role of the window function as well as the effect of calibration on the low frequency domain.

AB - The unambiguous detection of individual solar internal g modes continues to elude us. With the aid of new additions to calibration procedures, as well as updated methods to combine multi-site time series more effectively, the noise and signal detection threshold levels in the low-frequency domain (where the g modes are expected to be found) have been greatly improved. In the BiSON 23-year dataset these levels now rival those of GOLF, and with much greater frequency resolution available, due to the long time series, there is an opportunity to place more constraints on the upper limits of individual g mode amplitudes. Here we detail recent work dedicated to the challenges of observing low-frequency oscillations using a ground-based network, including the role of the window function as well as the effect of calibration on the low frequency domain.

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Using BiSON to detect solar internal g-modes

Abstract

Bibliographical note

ASJC Scopus subject areas

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