Asteroseismology of red giants Observed by the Kepler Mission. Christina Hedges Mentors Savita Mathur Keith MacGregor Michael Thompson

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Transcription:

Asteroseismology of red giants Observed by the Kepler Mission Christina Hedges Mentors Savita Mathur Keith MacGregor Michael Thompson

Contents Introduction to Asteroseismology Aims of Summer Project Pipeline Creation Results Surface Rotation Conclusions

Red Giants

Asteroseismology What is Asteroseismology? The study of oscillations in stars Seismic activity in stars produces a Global Change in the stars surface, that is detectable. The oscillations in the stars have different modes. The oscillations are distinguished using l, m and n numbers. Low degree l modes are the easiest to identify as they produce a very obvious change to the star. l=0 modes are perceived as a breathing motion in the star. Image Credit: Birmingham Solar Oscillations Network. (BISON) Two types of modes, p modes and g modes.

What do these Modes look like? Time/Flux data is converted to Frequency/Power data by Fourier Transform. This creates a Power Spectrum where modes appear as sharp peaks in a roughly Gaussian shaped group. The spectrum is shaped and distorted by other factors from the star and satellite. Power (ppm) red giants due to their age and size have much lower frequency oscillations that solar like stars. Frequency (microhz)

Mean Large Frequency Spacing and Frequency of Maximum Power Modes are made up of thin Gaussian lines within a roughly Gaussian envelope. This structure is exhibited by all stars with oscillations. These modes are characterised mainly by two properties: The Large Spacing: The space between two modes of equal l number. The Frequency of Maximum Power: The frequency of the peak with the highest power. These characteristics are linked to properties of the star. Power (ppm) Frequency (microhz)

What can Modes tell us? Using the KIC for effective temperature it is possible to utilise the mean large frequency spacing and the frequency of the maximum power to find Mass and Radius. The KIC is not perfect and has very large errors on effective temperature. This was corrected as much as possible using the findings from Thygesen et al. 2012 Red giants have mixed g and p modes, making it possible to study the interiors of the stars.

Aims Automate this process so hundreds of red giants can be easily analysed without the need for interaction. Use these parameters to generate properties of the stars. (Mass, Radius etc) Use this data set to look into the surface rotation of the red giant stars.

Creating the Pipeline

Example of Kepler Data Image taken from star APH43664753 from Keplers Planet Hunters scheme

Initial Data Each time series has between 1 and 2 years of data in it based on how long the exposure was from the Kepler satellite. The data was initially in units of e - /s and needed to be converted to ppm. This is done using the ppm KADACS routine. (Garcia et al. 2011) Infinite points where the satellite had problems such as saturation were converted to zeros. The LNP_TEST function was used to generate the power density spectrum.

Background Removal Two methods for background removal: Fitting each individual contribution of noise from each type of granulation and white noise contribution at high frequency Fitting the background with a fitting routine using a standard polynomial. Power (ppm) Frequency (microhz)

Sliding Box After smoothing the Power Spectrum a sliding window is used to find the section with the highest power. (i.e. the envelope of modes.) The width is initially fixed but is later modified based on it s position in the spectrum. The new window is used to find a value for ν max and the FWHM of the peak is taken to be the error.

Second Power Spectrum The power spectrum of the power spectrum shows any points that are periodic in frequency. As the modes are equally spaced in frequency there is a high power at the point that corresponds to this frequency. (Known as the mean large frequency spacing or Δν) Due to the l=1 mode this had to be doubled to correspond to the actual large spacing. Frequency (microhz)

Outliers and Corrections Log(Δν) Log(ν max )

Finding Radius and Mass The equations for Mass and Radius are given below. These equations were taken from Mathur et al. 2010. Errors from Δν and ν max are propagated through. [Kjeldsen & Bedding 1995, Bedding & Kjeldsen 2003; Stello et al. 2008; Belkacen et al. 2011 ]

Comparison with KIC data 40 Radius from KIC agains Radius from Pipeline 35 30 25 R from KIC 20 15 10 5 0 0 5 10 15 20 25 30 35 40 R from Pipeline

Statistics 60 Histogram of Δν 40 Mass Histogram 50 40 35 30 25 30 20 10 Frequency 20 15 10 5 0 0.4 1.6 2.8 4 5.2 6.4 7.6 8.8 10 11.2 12.4 13.6 14.8 16 17.2 18.4 19.6 Δν 0 0 0.2 0.4 0.6 0.8 1 1.2 1.4 1.6 1.8 2 2.2 2.4 2.6 2.8 3 3.2 3.4 3.6 3.8 4 4.2 4.4 4.6 4.8 5 Mass in Solar Masses

HR Diagrams

Surface Rotation

Wavelet Analysis An iterative fitting routine where functions are fit over the time series. This produces a contour plot. Star must have some feature on its surface rotating in and out of view. Example of a Morlet Function, sv.wikipedia.org/wiki/fil:wavelet_- _Morlet.png Kepler is also a source of periodicity.

Example of the Sun Image taken from Hempelman, 2003, A&A, 399, 717

Red contour shows the rotation. Cone of Influence shows where results are discarded. (These results could not have had repeated by the minimum of 4 times) Very wide contour implies differential rotation in the star. The graph of the periodicity shows that these features are dark. Results

Data could be greatly improved with a longer time series, as the contours are very close to the cone of influence. 14/24 stars were found to have useful values of surface rotation ranging between 77 days and 137 days. Differential rotation is suggested by the width of the contour Much longer period for change in red giant stars, less detailed contours implying that the features aren t changing so rapidly. Results

What affects surface rotation detection? Inclination: If the star is rotating around an axis that is inclined to the observer the rotation won t be seen. Inactivity: Without star spots the rotation cannot be detected. Long Period Rotation: If red giants rotate with periods of more than a quarter of the observing time the findings are discounted. Satellite Effects

Conclusions We have generated a pipeline that is 80% effective We have shown the rotation of red giant stars is very slow compared with solar like stars We have shown that red giants are still active well into late evolution. Through studying surface rotation further of more evolved stars it is possible to study the transport of angular momentum.

Thank you for Watching

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