Hostname: page-component-586b7cd67f-g8jcs Total loading time: 0 Render date: 2024-11-28T10:41:05.240Z Has data issue: false hasContentIssue false

Large-scale asymmetry in galaxy spin directions: evidence from the Southern hemisphere

Published online by Cambridge University Press:  09 August 2021

Lior Shamir*
Affiliation:
Kansas State University, Manhattan, KS 66506, USA
*
Author for correspondence: Lior Shamir, E-mail: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Recent observations using several different telescopes and sky surveys showed patterns of asymmetry in the distribution of galaxies by their spin directions as observed from Earth. These studies were done with data imaged from the Northern hemisphere, showing excellent agreement between different telescopes and different analysis methods. Here, data from the DESI Legacy Survey was used. The initial dataset contains $\sim\!2.2\times 10^7$ galaxy images, reduced to $\sim\!8.1\times 10^5$ galaxies annotated by their spin direction using a symmetric algorithm. That makes it not just the first analysis of its kind in which the majority of the galaxies are in the Southern hemisphere, but also by far the largest dataset used for this purpose to date. The results show strong agreement between opposite parts of the sky, such that the asymmetry in one part of the sky is similar to the inverse asymmetry in the corresponding part of the sky in the opposite hemisphere. Fitting the distribution of galaxy spin directions to cosine dependence shows a dipole axis with probability of 4.66 $\sigma$ . Interestingly, the location of the most likely axis is within close proximity to the CMB Cold Spot. The profile of the distribution is nearly identical to the asymmetry profile of the distribution identified in Pan-STARRS, and it is within 1 $\sigma$ difference from the distribution profile in SDSS and HST. All four telescopes show similar large-scale profile of asymmetry.

Type
Research Article
Copyright
© The Author(s), 2021. Published by Cambridge University Press on behalf of the Astronomical Society of Australia

1. Introduction

Autonomous digital sky surveys that collect very large astronomical databases have allowed to address research questions that their studying was not possible in the pre-information era. One of these questions is the large-scale distribution of galaxy spin directions as observed from Earth. While the initial assumption would be that the spin directions of galaxies are randomly distributed at a large scale, there is no valid proof to that assumption. In fact, multiple experiments have shown that the distribution as seen from Earth might not be random (Longo Reference Longo2007, Reference Longo2011; Shamir Reference Shamir2012, Reference Shamir2019, Reference Shamir2020a,b,c, Reference Shamir2021; Lee et al. Reference Lee, Pak, Lee and Song2019a,b), and the profile of the distribution could exhibit a large-scale dipole axis (Shamir Reference Shamir2020a,b, Reference Shamir2021). When normalised for the redshift distribution, different telescopes show very similar profiles of asymmetry, and the directions of the most likely axes agree within statistical error (Shamir Reference Shamir2020a,b).

The observation of a large-scale axis around which the universe is oriented has been proposed in the past through observations of cosmic microwave background (CMB), with consistent data from the Cosmic Background Explorer (COBE), Wilkinson Microwave Anisotropy Probe (WMAP), and Planck (Mariano & Perivolaropoulos Reference Mariano and Perivolaropoulos2013; Land & Magueijo Reference Land and Magueijo2005; Ade et al. Reference Ade2014; Santos et al. Reference Santos, Cabella, Villela and Zhao2015).

Early attempts to study the distribution of spin directions of spiral galaxies were based primarily by manual annotating a large number of galaxy images (Sugai & Iye Reference Sugai and Iye1995; Land et al. Reference Land2008; Longo Reference Longo2011). Since human annotation is too slow to analyse large datasets and can also be affected by the bias of the human perception (Hayes, Davis, & Silva Reference Hayes, Davis and Silva2017), handling larger datasets in a systematic manner requires automatic analysis of the galaxies (Shamir Reference Shamir2012, Reference Shamir2013, Reference Shamir2016, Reference Shamir2019, Reference Shamir2020a,b). The application of the automatic analysis methods to different datasets acquired by different telescopes showed very similar profiles of distribution in data from Sloan Digital Sky Survey (SDSS), the Panoramic Survey Telescope and Rapid Response System (Pan-STARRS), and the Hubble Space Telescope (HST) (Shamir Reference Shamir2020a,b).

Non-random distribution of spin directions of galaxies has been also observed in cosmic filaments (Tempel, Stoica, & Saar Reference Tempel, Stoica and Saar2013; Tempel & Libeskind Reference Tempel and Libeskind2013). Alignment in spin directions associated with the large-scale structure was also observed with quasars (Hutsemékers et al. Reference Hutsemékers, Braibant, Pelgrims and Sluse2014) and smaller sets of spiral galaxies (Lee et al. Reference Lee, Pak, Song, Lee, Kim and Jeong2019b). In addition to the observational studies, dark matter simulations have also shown links between spin direction and the large-scale structure (Zhang et al. Reference Zhang, Yang, Faltenbacher, Springel, Lin and Wang2009; Libeskind et al. Reference Libeskind, Hoffman, Forero-Romero, Gottlöber, Knebe, Steinmetz and Klypin2013, Reference Libeskind, Knebe, Hoffman and Gottlöber2014). The strength of the correlation has been associated with stellar mass and the colour of the galaxies (Wang et al. Reference Wang, Guo, Kang and Libeskind2018). These links were associated with halo formation (Wang & Kang Reference Wang and Kang2017), leading to the contention that the spin in the halo progenitors is linked to the large-scale structure of the early universe (Wang & Kang Reference Wang and Kang2018). The numerous studies with different approaches, messengers, telescopes, and datasets that suggest links between the large-scale structure and the direction in which extra-galactic objects spin reinforce the studying of this question using larger datasets. Here, the distribution of spin directions of spiral galaxies is studied using a very large number of galaxies from the Southern hemisphere.

2. Data

The dataset of spiral galaxies was taken from the DESI Legacy Survey (Dey et al. Reference Dey2019), which is a combination of data collected by the Dark Energy Camera (DECam), the Beijing-Arizona Sky Survey (BASS), and the Mayall z-band Legacy Survey (MzLS). The imaging is calibrated to provide a dataset of nearly uniform depth (Dey et al. Reference Dey2019).

The list of objects was determined by using all ‘south’ bricks of Data Release (DR) 8 of the DESI Legacy Survey. Objects with g magnitude smaller than 19.5 and identified as exponential discs (‘EXP’), de Vaucouleurs ${r}^{1/4}$ profiles (‘DEV’), or round exponential galaxies (‘REX’) in DESI Legacy Survey DR8 were selected. That selection provided a list of objects identified as extended objects but excluded objects that may be embedded in other extended objects. Objects identified as galaxies but are part of other extended objects such as H II regions can still exist in the dataset, and it is virtually impossible to inspect the entire dataset by eye and remove such potential objects. If such object is located on the arm of a galaxy, it might be wrongly identified as the centre of that galaxy and can lead to incorrect annotation. As will be explained in Section 4, if such error indeed exists, it is expected to impact clockwise and counterclockwise similarly and therefore cannot lead to asymmetry in the dataset.

The images were retrieved through the cutout application programming interface (API) of the DESI Legacy Survey server. The images were downloaded as 256 $\times$ 256 JPEG images, scaled by the Petrosian radius to ensure the galaxy fits in the frame. The total number of images retrieved from the Legacy Survey server is 22 987 246. Downloading such a high number of images required a substantial amount of time. The first image was retrieved on 2020 June 4, and the process continued consistently until 2021 March 4, with just short breaks due to power outages or system updates of the computer that was used to download the images. All images were downloaded by using the same server located at Kansas State University campus to avoid any possible differences between the way different computers download and store images.

Annotation of the spin directions of such a large number of galaxies is highly impractical to perform manually due to the labour involved in such process. Therefore, the annotation of the galaxies requires automation. A valid automatic process for this task should be mathematically symmetric, to avoid any possible systematic bias. Machine learning is commonly used to annotate images, also in the astronomy domain. However, machine learning and especially convolutional neural networks are normally based on complex non-intuitive data-driven rules and almost always have a small but non-negligible error. Because these rules are determined automatically during the training process, there is no guarantee that these rules are symmetric. To eliminate the possibility that such bias affects the results, the algorithm needs to be deterministic and mathematically symmetric.

Figure 1. Examples of the peaks of the radial intensity plots of different galaxy images. The direction of the lines generated by the peaks identifies the curves of the galaxy arms and therefore can be used to determine the spin directions. The algorithm is fully symmetric and is not based on complex non-intuitive data-driven rules commonly used in machine learning.

To avoid the possibility of systematic bias, the fully symmetric model-driven Ganalyzer algorithm was used (Shamir Reference Shamir2011). The Ganalyzer algorithm first converts each galaxy image into its radial intensity plot. The radial intensity plot is the transformation of the original galaxy image, such that the value of the pixel (x,y) in the radial intensity plot is the median value of the 5 $\times$ 5 pixels around $(O_x+\sin(\theta) \cdot r,O_y-\cos(\theta)\cdot r)$ in the original image, where r is the radial distance, $\theta$ is the polar angle, and $O_x$ , $O_y$ are the X and Y pixel coordinates of the centre of the galaxy.

After the galaxy image is converted into its radial intensity plot, a peak detection algorithm (Morháč et al. Reference Morháč, Kliman, Matoušek, Veselsky and Turzo2000) is applied to the horizontal lines of the radial intensity plot to identify the peaks in each row. Because the arms of the galaxy have brighter pixels than other pixels at the same distance from the galaxy centre, the peaks in the radial intensity plot are the galaxy arms in the original image. Since the arm of a spiral galaxy is curved, the peaks are expected to form a line towards the direction in which the arm spins. When applying a linear regression to that line, the sign of the regression determines the direction towards which the arm is curved, and consequently the direction towards which the galaxy spins (Shamir Reference Shamir2011; Reference Shamir2017a,b,c, Reference Shamir2019, Reference Shamir2020b).

Figure 1 shows examples of galaxy images and the peaks of the radial intensity plot transformation of each galaxy. The first two images show a simple galaxy structure with two arms, and therefore the peaks of the radial intensity plots have two lines. Each line corresponds to an arm of a galaxy. The direction of the lines reflects the spin direction of the galaxies. Galaxies 3 and 4 are galaxies with three arms, as reflected by the lines created by the peaks of the radial intensity plots. Galaxies 5 and 6 have more complex morphology but still can be identified by a higher number of peaks that drift towards the direction that allows to identify the spin direction of the galaxy.

It is clear that not all galaxies in the initial dataset are spiral, and not all spiral galaxies provide clear details that can allow to identify their spin direction. To remove galaxies that their spin direction cannot be identified with high certainty, only galaxies that have at least 30 identified peaks aligned in lines are considered as galaxies with identifiable spin directions. Additionally, the number of peaks that shift in one direction should be at least three times the number of peaks shifting towards the opposite direction (Shamir Reference Shamir2020b). If that condition is not satisfied, the galaxy is not annotated and being rejected from the analysis.

The requirement for the peaks of the radial intensity plot to shift to one direction at least three times more than the other direction can handle situations in which the arms are tilted in a non-uniform manner. Galaxy 6 in Figure 1 is an example of a galaxy with arms tilted in non-uniform directions. The number of peaks shifting to the right (counterclockwise) is 55, while the number of peaks shifting to the left is 18. That reflects the stronger counterclockwise winding as seen in the image. If the number of peaks shifting to the left was higher, the galaxy would not be annotated at all, would be assumed inconclusive, and consequently rejected from the analysis. It is reasonable to assume that many galaxies with identifiable spin directions are rejected from the analysis, reducing the size of the usable data. However, the key requirement of the algorithm is that the rejection of galaxies is done in a symmetric manner, and with no preference to galaxies of a certain spin direction. As discussed in Section 4 and shown theoretically and empirically in Shamir (Reference Shamir2021), Ganalzyer is mathematically symmetric. Also, experiments that were done by adding a large number of artificial incorrectly classified galaxies showed minor impact on the results of the analysis when they were distributed evenly, while even 1% artificial systematic error led to very strong signal that peaked at the celestial pole (Shamir Reference Shamir2021). Additional discussion about the impact of different types of possible errors can be found in Section 4. More detailed information about the annotation algorithm can be found in Shamir (Reference Shamir2011, Reference Shamir2012, Reference Shamir2020a,b, Reference Shamir2021), Hoehn & Shamir (Reference Hoehn and Shamir2014), and Dojcsak & Shamir (Reference Dojcsak and Shamir2014).

After applying the algorithm, 836 451 galaxies were assigned with identifiable spin directions. In some cases, digital sky survey can identify objects that are part of the same galaxy as separate galaxies. To avoid having the same galaxy more than once in the dataset, objects that have another object within less than 0.01 $^\circ$ were removed. After removing these objects, 807 898 galaxies were left in the dataset. To test the consistency of the classification, 200 galaxies annotated as spinning clockwise and 200 galaxies annotated as spinning counterclockwise were inspected manually. None of the galaxies determined by the algorithm to be spinning clockwise was visually spinning counterclockwise, and none of the galaxies that according to the algorithm were spinning counterclockwise was by manual inspection spinning clockwise.

To ensure that the process of annotation is consistent, all galaxy images were analysed by the exact same algorithm, exact same code, exact same computer, and exact same processor. That was done to avoid a situation in which different computers or even different processors analyse different galaxies and could lead to differences in the way each galaxy is analysed. Annotation of the initial dataset of over 2.2 $\times10^7$ galaxies required 107 d using a single Intel Xeon processor at 2.8 Ghz. To reduce the response time of the experiment, the process of galaxy annotation started before all galaxies were fully downloaded from the Legacy Survey server.

Like many other digital sky surveys, galaxies in the Legacy Surveys are not distributed uniformly across all right ascension and declination ranges. Tables 1 and 2 show the number of galaxies in different right ascension and declination ranges, respectively. As Table 2 shows, the dataset also includes bricks with positive declination. All galaxies in Table 2 were used, and therefore the dataset was not limited to merely galaxies with negative declination. While the dataset is not made of purely galaxies from the Southern hemisphere, most galaxies have far lower declination compared to data collected by telescopes located in the Northern hemisphere such as Pan-STARRS or SDSS. Pan-STARRS and SDSS also cover some of the Southern sky but do not go below the declination of $-30^\circ$ , and most of their footprint is in positive declination. Table 3 shows the redshift distribution of the galaxies. The Legacy Survey galaxies do not have redshift, and therefore the distribution of the redshift was measured by using a subset of 17 027 galaxies that had redshift in the 2dF redshift survey (Cole et al. Reference Cole2005).

Table 1. The number of galaxies in different right ascension ranges.

Table 2. The number of galaxies in different declination ranges.

Table 3. The number of galaxies in different z ranges. The distribution is determined by a subset of 17 027 galaxies that had redshift in the 2dF redshift survey.

3. Results

As a simple analysis, the asymmetry in each part of the sky was determined as $\frac{cw-ccw}{cw+ccw}$ , where cw is the number of galaxies rotating clockwise, and ccw is the number of galaxies rotating counterclockwise in that part of the sky. The normal distribution standard error is $\frac{1}{\sqrt{N}}$ , where N is the total number of galaxies in that sky section. Figure 2 shows the asymmetry in different $30^{\circ}$ right ascension (RA) slices.

Figure 2. Asymmetry in the distribution of the galaxies in different RA ranges. The graph shows inverse asymmetry in corresponding sky regions in opposite hemispheres.

As the figure shows, the asymmetry in each RA slice agrees with the inverse asymmetry in the corresponding RA slice in the opposite hemisphere. For instance, the strongest asymmetry of 0.011 is observed in the RA range $(30^\circ$ $60^\circ)$ . The uncorrected binomial probability to have such distribution by chance is $2\times 10^{-5}$ , and the Bonferroni corrected probability is $3\times 10^{-4}$ . That asymmetry corresponds to the strongest inverse asymmetry of $-0.007$ , observed in the corresponding RA range in the opposite hemisphere $(210^\circ$ $240^\circ)$ . The lowest asymmetry is observed in the RA range of $(120^\circ$ $150^\circ)$ and matches the low asymmetry in the corresponding sky region in the opposite hemisphere $(300^\circ$ $330^\circ)$ . The same can be observed with all other sky regions, where the magnitude of the asymmetry in each sky region corresponds to the magnitude of the inverse asymmetry in the opposite sky region. The only exception is the RA range $(90^\circ$ $120^\circ)$ , and the corresponding RA range $(270^\circ$ $300^\circ)$ . But these RA ranges have by far the lowest number of galaxies 21 086 and 2 602, respectively, and therefore the error in these RA ranges is far larger compared to the other RA slices.

The symmetricity of the algorithm was verified by comparing the annotations of a certain set of galaxies to the annotations of the same set of galaxies such that the images are mirrored. Previous experiments with other telescopes showed that the annotation of the mirrored galaxy images are exactly the opposite compared to the original galaxy images (Shamir Reference Shamir2017a,c, Reference Shamir2020b, Reference Shamir2021). The fact that mirroring the galaxies provided inverse results is an empirical evidence that any error in the annotation algorithm affects both clockwise and counterclockwise galaxies in a similar fashion.

As Figure 2 shows, the RA range $(150^\circ-330^\circ)$ shows higher population of counterclockwise galaxies, while the RA range $(0^\circ-150^\circ \cup 330^\circ-360^\circ)$ shows a higher number of galaxies that spin clockwise. The only exceptions are the RA slices with low population of galaxies. To verify the symmetricity of the analysis, the analysis was repeated such that each image was mirrored by converting the images to lossless TIFF format, and then using the ‘flip’ command of ImageMagick. As expected, the results were exactly inverse to the results with the original non-mirrored images.

Table 4 shows the number of galaxies spinning in each direction in each hemisphere. As the table shows, the sky imaged by DESI Legacy Survey can be separated into two hemispheres such that one hemisphere has a higher number of galaxies that spin clockwise, and the opposite hemisphere has an excessive number of galaxies that spin counterclockwise. In both cases, the asymmetry is statistically significant.

Table 4. Number of clockwise and counterclockwise galaxies in opposite hemispheres. The P is the binomial distribution probability to have such difference or stronger by chance when assuming 0.5 probability for a galaxy to spin clockwise or counterclockwise.

The fact that the sky covered by the DESI Legacy Survey can be separated into two opposite parts such that one has a higher number of clockwise galaxies and the other has a higher number of counterclockwise galaxies indicates that the distribution of the spin directions of spiral galaxies as observed from Earth can form a large-scale axis. To examine the probability that the distribution of the spin directions of the galaxies exhibits a dipole axis, the same method used in Shamir (Reference Shamir2012, Reference Shamir2019, Reference Shamir2020a,b, Reference Shamir2021) was applied.

In summary, all galaxies in the dataset that spin clockwise were assigned with the value 1, and all galaxies that spin counterclockwise were assigned with the value $-1$ . Then, for each possible integer $(\alpha,\delta)$ combination, the angular distance $\phi$ between each galaxy in the dataset and $(\alpha,\delta)$ was computed. The $\cos(\phi)$ of the galaxies were then fitted with $\chi^2$ statistics into $d\cdot|\cos(\phi)|$ , where d is the spin direction of the galaxy (d can be either 1 or $-1$ ). The $\chi^2$ was computed 1 000 times for each integer $(\alpha,\delta)$ combination such that in each time the galaxies were assigned with random spin directions,. The mean and standard deviation of the 1 000 runs were computed for each possible integer $(\alpha,\delta)$ . Then, the $\chi^2$ computed when d was assigned the actual spin directions was compared to the mean and standard deviation of the $\chi^2$ computed with the random spin directions. The standard deviation was used to determine the $\sigma$ difference between the mean $\chi^2$ computed with the random galaxy spin directions and the $\chi^2$ computed with the actual spin directions. After computing the $\sigma$ difference of all $(\alpha,\delta)$ combinations, the location $(\alpha,\delta)$ of the most likely dipole axis can be determined by the $(\alpha,\delta)$ that has the highest $\sigma$ difference between the $\chi^2$ computed with the actual spin directions and the mean $\chi^2$ computed with the random spins. Detailed information about the analysis can be found in Shamir (Reference Shamir2012, Reference Shamir2019, Reference Shamir2020a,b, Reference Shamir2021).

Figure 3 shows the likelihood of a dipole axis in all $(\alpha,\delta)$ combinations. The most likely dipole axis was identified at $(\alpha=57^\circ,\delta=-10^\circ)$ . The likelihood of the axis to be formed by chance is $4.66\sigma$ . The 1 $\sigma$ error for that axis is $(22^\circ,92^\circ)$ for the right ascension, and $({-}39^\circ,56^\circ)$ for the declination. Interestingly, the CMB Cold Spot is at $(\alpha=49,\delta=-19^\circ)$ , very close to the direction of the most probable dipole axis.

Figure 3. The probability of a dipole axis in galaxy spin directions from every possible integer $(\alpha,\delta)$ combination.

Figure 4. The probability of a dipole axis in the galaxy spin directions when the galaxies are assigned with random spin directions.

Assigning the galaxies with random spin directions provides a maximum likelihood of a dipole of 0.91 $\sigma$ . The likelihood of a dipole axis formed by the spin directions of the galaxies in all integer $(\alpha,\delta)$ combinations is shown in Figure 4. As expected, galaxies with random spin directions do not form a statistically significant pattern.

The results observed with the DESI Legacy Survey, in which most galaxies are in the Southern hemisphere, can be compared to previous results using galaxies mostly from the Northern hemisphere, namely Pan-STARRS, SDSS, and HST. Figure 5 shows the results of a previous experiment (Shamir Reference Shamir2020b) of fitting the spin directions of 3.3 $\times 10^3$ Pan-STARRS galaxies into cosine dependence from all possible integer $(\alpha,\delta)$ combinations. The specific details of the experiment are described in Shamir (Reference Shamir2020b). The most likely dipole axis in Pan-STARRS galaxies is identified at $(\alpha=47^\circ,\delta=-1^\circ)$ , with statistical significance of 1.87 $\sigma$ (Shamir Reference Shamir2020b). That location is nearly identical to the most probable axis identified in the DESI Legacy Survey galaxies as shown in Figure 3.

The previous analysis of the distribution of the spin directions of the galaxies imaged by Pan-STARRS was compared to the previous analysis of 38 998 SDSS galaxies with spectra that their redshifts distribute in a similar manner to the redshift distribution of the Pan-STARRS galaxies. Full details about that experiment are described in Shamir (Reference Shamir2020b). Figure 6 shows the probability of a dipole axis in the distribution of spin directions of the SDSS DR14 spiral galaxies (Shamir Reference Shamir2020b). The results show a most likely dipole axis at $(\alpha=49^\circ, \delta=21^\circ)$ , with statistical signal of 2.05 $\sigma$ (Shamir Reference Shamir2020b). That position is also well within the 1 $\sigma$ error from the most likely dipole axis identified in the DESI Legacy Survey. The difference in the RA of the two axes is just 7 $^\circ$ .

Figure 5. The probability of a dipole axis formed by the galaxy spin directions of $\sim\!3.3\times10^4$ Pan-STARRS galaxies (Shamir Reference Shamir2020b). The profile is very similar to the profile formed by the galaxy spin directions of the galaxies imaged by the DESI Legacy Survey as shown in Figure 3.

Figure 6. The probability of a dipole axis in different $(\alpha,\delta)$ when using $\sim\!3.3\times 10^4$ SDSS galaxies (Shamir Reference Shamir2020b).

Figure 7. The profile of probabilities of a dipole axis in the spin directions of HST galaxies (Shamir Reference Shamir2020a).

The results can also be compared to the previous analysis of using $\sim\!8.7\times 10^3$ HST galaxies classified manually by their spin directions (Shamir Reference Shamir2020a). Figure 7 shows the probability of a dipole axis in all possible integer $(\alpha,\delta)$ combinations. The most likely dipole axis exhibited by the HST galaxies was identified at $(\alpha=78^\circ, \delta=47^\circ)$ , with statistical significance of 2.8 $\sigma$ as described in Shamir (Reference Shamir2020a). The 1 $\sigma$ error for that axis is $(58^\circ, 184^\circ)$ for the right ascension, and $(6^\circ, 73^\circ)$ for the declination. While that axis is not as close to the axis of the DESI Legacy Survey data as the axes observed in Pan-STARRS and SDSS data, the right ascension is still relatively close, and the 1 $\sigma$ error of that axis is still within the 1 $\sigma$ error of the most probable dipole axis computed from the DESI Legacy Survey. It should also be noted that HST has a lower number of galaxies compared to the three other telescopes, and the mean redshift of the HST galaxies of 0.58 is far higher than all other sky surveys.

In addition to a dipole axis, an attempt was also made to fit the galaxy spin directions to quadrupole alignment. That was done by $\chi^2$ fitting of the $\cos(2\phi)$ into $d\cdot|\cos(2\phi)|$ (Shamir Reference Shamir2019, Reference Shamir2020b). Figure 8 shows the likelihood of a quadrupole axis from different combinations of $(\alpha,\delta)$ . The most probable quadrupole axis show one axis at $(\alpha=312^\circ, \delta=1^\circ)$ and another axis at $(\alpha=27^\circ, \delta=-32^\circ)$ , with statistical significance of 3.069 $\sigma$ and $1.87\sigma$ , respectively. The statistical significance of the quadrupole alignment is, therefore, lower than the statistical significance of the dipole alignment.

Figure 8. The profile of probabilities of a quadrupole axis in the spin directions of DESI Legacy Survey galaxies.

Figure 9. The profile of a quadrupole in Pan-STARRS (Shamir Reference Shamir2020b).

Figure 10. The profile of a quadrupole in SDSS (Shamir Reference Shamir2020b).

These axes can be compared to the quadrupole alignment of the Pan-STARRS and SDSS galaxies, as shown in Figures 9 and 10, respectively. The most probable axes are $(\alpha=17^\circ, \delta=-2^\circ)$ in Pan-STARRS and $(\alpha=7^\circ, \delta=4^\circ)$ in SDSS (Shamir Reference Shamir2020b). Fitting the galaxies into quadrupole alignment shows somewhat larger differences between the different telescopes compared to the strong agreement between the dipole axes. However, the difference in the RA is still relatively small, and is 10 $^\circ$ difference in Pan-STARRS and 20 $^\circ$ in SDSS.

4. Conclusion

Several previous observations have shown the possibility of certain asymmetry between galaxies with opposite spin directions, and large-scale patterns that the asymmetry might exhibit as observed from Earth (Longo Reference Longo2011; Shamir Reference Shamir2012, Reference Shamir2013, Reference Shamir2016, Reference Shamir2019, Reference Shamir2020a,b, Reference Shamir2021; Lee et al. Reference Lee, Pak, Lee and Song2019a,b). While these observations show good agreement between telescopes, previous experiments were based on galaxies imaged mostly in the Northern hemisphere. The analysis shown in this paper is based on a dataset in which the majority of the galaxies are from the Southern hemisphere, which is also far larger than any previous dataset used for this purpose before.

Simple analysis of asymmetry in different RA slices shows good agreement between the asymmetry in corresponding RA slices in opposite hemispheres, such that a higher number of clockwise galaxies in one part of the sky corresponds to a similarly higher number of counterclockwise galaxies in the corresponding part of the sky in the opposite hemisphere. Analysis of a dipole axis shows good agreement with previous data from Pan-STARRS, SDSS, and HST. The data are available in http://people.cs.ksu.edu/ lshamir/data/assym_desi/.

It is very difficult to think of an error that would exhibit itself in the form of such asymmetry. The classification algorithm is mathematically symmetric and was tested empirically to show inverse results when the images are mirrored. Even if the annotation algorithm had an error, that error should have been consistent throughout the sky, rather than being flipped in opposite hemispheres. Obviously, no change in the algorithm or code was done while the analysis was performed, and all galaxies were annotated by the exact same algorithm and code, the exact same computer, and the exact same processor.

The algorithm used to annotate the galaxies is fully symmetric and works by clear mathematically defined rules. Therefore, an error in the galaxy annotation should affect both clockwise and counterclockwise galaxies similarly and therefore cannot lead to asymmetry. That is also true for artefacts or bad data that might be relatively rare but still exist in large databases such as the DESI Legacy Survey. A detailed theoretical and empirical analysis of the effect of error in the galaxy annotation was done in Shamir (Reference Shamir2021). In summary, the asymmetry between clockwise and counterclockwise galaxies A can be defined as $A=\frac{(N_{cw}+E_{cw})-(N_{ccw}+E_{ccw})}{N_{cw}+E_{cw}+N_{ccw}+E_{ccw}}$ , where $N_{cw}$ is the number of clockwise galaxies correctly annotated as clockwise, $N_{ccw}$ is the number of counterclockwise galaxies correctly annotated as counterclockwise, $E_{cw}$ is the number of counterclockwise galaxies incorrectly classified as clockwise galaxies, and $E_{ccw}$ is the number of clockwise galaxies incorrectly classified as counterclockwise galaxies.

If the galaxy classification algorithm is symmetric, $E_{cw}$ should be roughly the same as $E_{ccw}$ , and therefore the asymmetry can be defined by $A=\frac{N_{cw}-N_{ccw}}{N_{cw}+E_{cw}+N_{ccw}+E_{ccw}}$ . Since $E_{cw}$ and $E_{ccw}$ cannot be negative values, a higher number of misclassified galaxies is expected to make A smaller. Therefore, an error in the annotation algorithm is expected to make the asymmetry lower and cannot lead to a statistically significant A in a population of evenly distributed galaxies. The analysis agrees with empirical experiments done by adding an artificial error to the galaxy annotation algorithm, showing that such error weakens the signal (Shamir Reference Shamir2021). Therefore, if the algorithm is symmetric, error in the annotations is expected to weaken the signal and cannot lead to statistically significant asymmetry if the real distribution of the galaxies is random. In some rare cases, the actual spin of a galaxy can be different from the curves of the arms. However, these cases should be distributed equally between clockwise and counterclockwise galaxies and therefore are not expected to lead to signal in the distribution of spin directions.

Cosmic variance also cannot explain such asymmetry. The difference between the number of clockwise and counterclockwise galaxies is a relative measurement, made of two measurements made in the same field. The number of clockwise galaxies is one measurement, while the number of counterclockwise spiral galaxies is another measurement made from the same field. Any effect that can impact the number of clockwise galaxies identified in the field is expected to make the same impact on the number of counterclockwise galaxies.

As mentioned in Section 2, in some cases, photometric objects can be part of the same galaxy, and therefore any object that has another object within less than 0.01 $^\circ$ was removed from the dataset to ensure that no galaxy is represented more than once. Previously, Iye, Yagi, & Fukumotoi (Reference Iye, Yagi and Fukumoto2021) reported on photometric objects that are part of the same galaxies in the dataset of Shamir (Reference Shamir2017b). If that dataset was used for the purpose of profiling asymmetry in the population of clockwise and counterclockwise galaxies, photometric objects that are part of the same galaxy become duplicate objects. However, the dataset of Shamir (Reference Shamir2017b) was used to analyse the possible link between photometry and spin direction, and not for analysing the large-scale distribution of clockwise and counterclockwise galaxies as done here or in previous studies (Shamir Reference Shamir2012, Reference Shamir2019, Reference Shamir2020a,b,c, Reference Shamir2021). That is, if the dataset of Shamir (Reference Shamir2017b) was used to identify a dipole axis in the clockwise/counterclockwise distribution, the photometric objects that are part of the same galaxies would have been duplicate objects. However, the Shamir (Reference Shamir2017b) was designed for a different purpose and was not used for identifying a dipole axis in the clockwise/counterclockwise galaxy distribution.

It is important to mention that unlike the analysis applied here, in which the location of each galaxy is identified by its RA and Dec, Iye et al. (Reference Iye, Yagi and Fukumoto2021) applied a 3D analysis, which required each galaxy to have its RA, Dec, and redshift. Because the vast majority of the galaxies used in Shamir (Reference Shamir2017b) do not have spectra, Iye et al. (Reference Iye, Yagi and Fukumoto2021) used the photometric redshifts taken from the photometric redshift catalogue of Paul, Virag, & Shamir (Reference Paul, Virag and Shamir2018). The error of the photometric redshift in that catalogue is $\sim\!18.5\%$ , which is far greater than the expected asymmetry. Also, because photometric objects that are part of the same galaxy can be assigned with different photometric redshifts, such analysis with the photometric redshift can lead to biased results that are not of astronomical origin. In summary, using the photometric redshift for identifying subtle asymmetries in the large-scale structure might be limited by the relatively large error and the possible systematic bias of the photometric redshift and might not provide sound evidence for the existence or inexistence of such cosmological-scale asymmetries.

Another difference between the study of Iye et al. (Reference Iye, Yagi and Fukumoto2021) and the work done in previous papers (Shamir Reference Shamir2012, Reference Shamir2020a,b) is that Iye et al. (Reference Iye, Yagi and Fukumoto2021) reported on random distribution in a subset of the data, limited to $z_{phot}<0.1$ . As shown in Shamir (Reference Shamir2020b), no statistically significant asymmetry is expected in that redshift range, and in fact all previous attempts to limit the redshift to any value below 0.15 showed random distribution (Shamir Reference Shamir2020b). An experiment of identifying a dipole axis when limiting the galaxies to $z<0.15$ showed statistical signal lower than 2 $\sigma$ (Shamir Reference Shamir2020b), and the distribution in different parts of the sky showed low P values for the lower redshift ranges, as shown in Tables, 3, 5, 6, and 7 in Shamir (Reference Shamir2020b).

A dataset from the same telescope (SDSS) and the same limiting magnitude (g $<$ 19) that does not contain duplicate objects was used for the analysis of spin direction asymmetry and a possible dipole axis. The analysis showed that when not using the photometric redshift and when not limiting the galaxies to $z_{phot}<0.1$ , the patterns are statistically significant at $\sim\!2.6\sigma$ (Shamir Reference Shamir2021).

In any case, duplicate objects are expected to be distributed evenly between galaxies that spin clockwise and galaxies that spin counterclockwise. Empirical experiments by adding artificial duplicate objects to randomly distributed data showed that duplicate objects do not have substantial impact on the results, until an extremely large number of duplicate objects is present. The results show that even when duplicating each object five times, the asymmetry signal is still below 2 $\sigma$ if the original data are random (Shamir Reference Shamir2021).

The contention that alignment in galaxy spin directions is related to the large-scale structure was also proposed with smaller-scale experiments, in which correlation between spin directions of spiral galaxies were identified even when the galaxies were too far to have gravitational interactions (Lee et al. Reference Lee, Pak, Song, Lee, Kim and Jeong2019b). Unless assuming modified Newtonian dynamics (MOND) gravity models that support longer gravitational span (Amendola et al. Reference Amendola, Bettoni, Pinho and Casas2020), these findings might conflict with standard cosmology. Alignment of the position angle of radio galaxies also showed large-scale consistency of angular momentum (Taylor & Jagannathan Reference Taylor and Jagannathan2016). These observations have been aligned with observations made with datasets such as the TIFR GMRT Sky Survey (TGSS) and the Faint Images of the Radio Sky at Twenty-centimetres (FIRST), showing large-scale alignment of radio galaxies (Contigiani et al. Reference Contigiani2017; Panwar et al. Reference Panwar, Sandhu, Wadadekar and Jain2020).

Large-scale anisotropy has been reported also by using several other probes such as the cosmic microwave background (Eriksen et al. Reference Eriksen, Hansen, Banday, Gorski and Lilje2004), frequency of galaxy morphology types (Javanmardi & Kroupa Reference Javanmardi and Kroupa2017), short gamma ray bursts (Mészáros Reference Mészáros2019), Ia supernova (Javanmardi et al. Reference Javanmardi, Porciani, Kroupa and Pflam-Altenburg2015; Lin, Li, & Chang Reference Lin, Li and Chang2016), LX-T scaling (Migkas et al. Reference Migkas, Schellenberger, Reiprich, Pacaud, Ramos-Ceja and Lovisari2020), and quasars (Secrest et al. Reference Secrest, Hausegger, Rameez, Mohayaee, Sarkar and Colin2020). The cosmic microwave background also shows the possibility of the existence of a cold spot (Cruz et al. Reference Cruz, Cayon, Martinez-Gonzalez, Vielva and Jin2007; Mackenzie et al. Reference Mackenzie, Shanks, Bremer, Cai, Gunawardhana, Kovács, Norberg and Szapudi2017; Farhang & Movahed Reference Farhang and Movahed2021), which makes another indication of the possibility of cosmological-scale anisotropy. The location of the most probable location of the dipole axis shown in this paper is very close to the location of the CMB Cold Spot.

The possible anisotropy observed in the cosmic microwave background (Cline, Crotty, & Lesgourgues Reference Cline, Crotty and Lesgourgues2003; Gordon & Hu Reference Gordon and Hu2004; Zhe, Xin, & Sai Reference Zhe, Xin and Sai2015) has led to cosmological theories that challenge the standard cosmology models. These theories include primordial anisotropic vacuum pressure (Rodrigues Reference Rodrigues2008), double inflation (Feng & Zhang Reference Feng and Zhang2003), contraction prior to inflation (Piao, Feng, & Zhang Reference Piao, Feng and Zhang2004), moving dark energy (Jiménez & Maroto Reference Jiménez and Maroto2007), multiple vacua (Piao Reference Piao2005), and spinor-driven inflation (Bohmer & Mota Reference Bohmer and Mota2008). Understanding and profiling the possible cosmological-scale anisotropy can provide important information leading to additional theories that shift from the existing standard models.

A large-scale axis can be related also to other cosmological models such as rotating universe (Gödel Reference Gödel1949; Ozsváth & Schücking Reference Ozsváth and Schücking1962; Ozsvath & Schücking Reference Ozsvath and Schücking2001; Sivaram & Arun Reference Sivaram and Arun2012; Chechin Reference Chechin2016), or ellipsoidal universe (Campanelli, Cea, & Tedesco Reference Campanelli, Cea and Tedesco2006, Reference Campanelli, Cea and Tedesco2007; Campanelli et al. Reference Campanelli, Cea, Fogli and Tedesco2011; Gruppuso Reference Gruppuso2007; Cea Reference Cea2014), where a large-scale asymmetry axis is assumed, and has also been associated with the axis formed by CMB anisotropy (Campanelli et al. Reference Campanelli, Cea and Tedesco2007).

Cosmological theories such as holographic big bang (Pourhasan, Afshordi, & Mann Reference Pourhasan, Afshordi and Mann2014; Altamirano et al. Reference Altamirano, Gould, Afshordi and Mann2017) can also be related to a cosmological-scale axis. The existence of such axis is also aligned with the black hole cosmology theory (Pathria Reference Pathria1972; Easson & Brandenberger Reference Easson and Brandenberger2001; Chakrabarty et al. Reference Chakrabarty, Abdujabbarov, Malafarina and Bambi2020), providing an explanation to cosmic inflation that does not involve dark energy. The spin of black holes is originated from the spin of the stars from which they were created (McClintock et al. Reference McClintock, Shafee, Narayan, Remillard, Davis and Li2006). Since a black hole spins, a cosmological-scale axis is expected to exist in the universe hosted by it. If the universe was formed in a black hole, the universe should have a preferred direction inherited from the spin direction of the black hole hosting it (Popławski Reference Popławski2010; Seshavatharam Reference Seshavatharam2010; Seshavatharam & Lakshminarayana Reference Seshavatharam and Lakshminarayana2020a), and therefore an axis (Seshavatharam & Lakshminarayana Reference Seshavatharam and Lakshminarayana2020b). Such black hole universe might not be aligned with the cosmological principle (Stuckey Reference Stuckey1994).

The ability to analyse and profile non-random distribution of the spin directions of galaxies is a relatively new research topic that became possible due to the availability of digital sky survey. These studies were not possible in the pre-information era. As the evidence for the existence of such axis are accumulating, it is clear that further research will be required to fully understand the nature of the possible non-random structures formed by the distribution of spin directions of galaxies.

Acknowledgments

I would like to thank the anonymous reviewer for the insightful comments that helped to improve the manuscript. This study was supported in part by NSF grants AST-1903823 and IIS-1546079. I would like to thank Ethan Nguyen for downloading and organising the image data from DESI Legacy Survey.

The Legacy Surveys consist of three individual and complementary projects: the Dark Energy Camera Legacy Survey (DECaLS; Proposal ID #2014B-0404; PIs: David Schlegel and Arjun Dey), the Beijing-Arizona Sky Survey (BASS; NOAO Prop. ID #2015A-0801; PIs: Zhou Xu and Xiaohui Fan), and the Mayall z-band Legacy Survey (MzLS; Prop. ID #2016A-0453; PI: Arjun Dey). DECaLS, BASS, and MzLS together include data obtained, respectively, at the Blanco telescope, Cerro Tololo Inter-American Observatory, NSF’s NOIRLab; the Bok telescope, Steward Observatory, University of Arizona; and the Mayall telescope, Kitt Peak National Observatory, NOIRLab. The Legacy Surveys project is honoured to be permitted to conduct astronomical research on Iolkam Du’ag (Kitt Peak), a mountain with particular significance to the Tohono O’odham Nation.

NOIRLab is operated by the Association of Universities for Research in Astronomy (AURA) under a cooperative agreement with the National Science Foundation.

This project used data obtained with the Dark Energy Camera (DECam), which was constructed by the Dark Energy Survey (DES) collaboration. Funding for the DES Projects has been provided by the US Department of Energy, the US National Science Foundation, the Ministry of Science and Education of Spain, the Science and Technology Facilities Council of the United Kingdom, the Higher Education Funding Council for England, the National Center for Supercomputing Applications at the University of Illinois at Urbana-Champaign, the Kavli Institute of Cosmological Physics at the University of Chicago, Center for Cosmology and Astro-Particle Physics at the Ohio State University, the Mitchell Institute for Fundamental Physics and Astronomy at Texas A&M University, Financiadora de Estudos e Projetos, Fundacao Carlos Chagas Filho de Amparo, Financiadora de Estudos e Projetos, Fundacao Carlos Chagas Filho de Amparo a Pesquisa do Estado do Rio de Janeiro, Conselho Nacional de Desenvolvimento Cientifico e Tecnologico and the Ministerio da Ciencia, Tecnologia e Inovacao, the Deutsche Forschungsgemeinschaft, and the Collaborating Institutions in the Dark Energy Survey. The Collaborating Institutions are Argonne National Laboratory, the University of California at Santa Cruz, the University of Cambridge, Centro de Investigaciones Energeticas, Medioambientales y Tecnologicas-Madrid, the University of Chicago, University College London, the DES-Brazil Consortium, the University of Edinburgh, the Eidgenossische Technische Hochschule (ETH) Zurich, Fermi National Accelerator Laboratory, the University of Illinois at Urbana-Champaign, the Institut de Ciencies de l’Espai (IEEC/CSIC), the Institut de Fisica d’Altes Energies, Lawrence Berkeley National Laboratory, the Ludwig Maximilians Universitat Munchen and the associated Excellence Cluster Universe, the University of Michigan, NSF’s NOIRLab, the University of Nottingham, the Ohio State University, the University of Pennsylvania, the University of Portsmouth, SLAC National Accelerator Laboratory, Stanford University, the University of Sussex, and Texas A&M University.

BASS is a key project of the Telescope Access Program (TAP), which has been funded by the National Astronomical Observatories of China, the Chinese Academy of Sciences (the Strategic Priority Research Program ‘The Emergence of Cosmological Structures’ Grant # XDB09000000), and the Special Fund for Astronomy from the Ministry of Finance. The BASS is also supported by the External Cooperation Program of Chinese Academy of Sciences (Grant # 114A11KYSB20160057), and Chinese National Natural Science Foundation (Grant # 11433005).

The Legacy Survey team makes use of data products from the Near-Earth Object Wide-field Infrared Survey Explorer (NEOWISE), which is a project of the Jet Propulsion Laboratory/California Institute of Technology. NEOWISE is funded by the National Aeronautics and Space Administration.

The Legacy Surveys imaging of the DESI footprint is supported by the Director, Office of Science, Office of High Energy Physics of the US Department of Energy under Contract No. DE-AC02-05CH1123, by the National Energy Research Scientific Computing Center, a DOE Office of Science User Facility under the same contract; and by the US National Science Foundation, Division of Astronomical Sciences under Contract No. AST-0950945 to NOAO.

References

Ade, P. A., et al. 2014, A&A, 571, A23 Google Scholar
Altamirano, N., Gould, E., Afshordi, N., & Mann, R. B. 2017, arXiv preprint arXiv:1703.00954Google Scholar
Amendola, L., Bettoni, D., Pinho, A. M., & Casas, S. 2020, Universe, 6, 20 CrossRefGoogle Scholar
Bohmer, C. G., & Mota, D. F. 2008, PLB, 663, 168 CrossRefGoogle Scholar
Campanelli, L., Cea, P., Fogli, G., & Tedesco, L. 2011, MPhL A, 26, 1169 CrossRefGoogle Scholar
Campanelli, L., Cea, P., & Tedesco, L. 2006, PRL, 97, 131302 CrossRefGoogle Scholar
Campanelli, L., Cea, P., & Tedesco, L. 2007, PRD, 76, 063007 CrossRefGoogle Scholar
Cea, P. 2014, MNRAS, 441, 1646 CrossRefGoogle Scholar
Chakrabarty, H., Abdujabbarov, A., Malafarina, D., & Bambi, C. 2020, EPJC, 80, 1 CrossRefGoogle Scholar
Chechin, L. 2016, ARep, 60, 535 CrossRefGoogle Scholar
Cline, J. M., Crotty, P., & Lesgourgues, J. 2003, JCAP, 2003, 010 CrossRefGoogle Scholar
Cole, S., et al. 2005, MNRAS, 362, 505 Google Scholar
Contigiani, O., et al. 2017, MNRAS, 472, 636 CrossRefGoogle Scholar
Cruz, M., Cayon, L., Martinez-Gonzalez, E., Vielva, P., & Jin, J. 2007, ApJ, 655CrossRefGoogle Scholar
Dey, A., et al. 2019, AJ, 157, 168 Google Scholar
Dojcsak, L., & Shamir, L. 2014, NewA, 28, 1 CrossRefGoogle Scholar
Easson, D. A., & Brandenberger, R. H. 2001, JHEP, 2001, 024 CrossRefGoogle Scholar
Eriksen, H. K., Hansen, F. K., Banday, A. J., Gorski, K. M., & Lilje, P. B. 2004, ApJ, 605, 14 CrossRefGoogle Scholar
Farhang, M., & Movahed, S. 2021, ApJ, 906, 41 CrossRefGoogle Scholar
Feng, B., & Zhang, X. 2003, PLB, 570, 145 CrossRefGoogle Scholar
Gödel, K. 1949, RvMP, 21, 447 CrossRefGoogle Scholar
Gordon, C., & Hu, W. 2004, PRD, 70, 083003 CrossRefGoogle Scholar
Gruppuso, A. 2007, PRD, 76, 083010 CrossRefGoogle Scholar
Hayes, W. B., Davis, D., & Silva, P. 2017, MNRAS, 466, 3928 CrossRefGoogle Scholar
Hoehn, C., & Shamir, L. 2014, AN, 335, 189 CrossRefGoogle Scholar
Hutsemékers, D., Braibant, L., Pelgrims, V., & Sluse, D. 2014, A&A, 572, A18 CrossRefGoogle Scholar
Iye, M., Yagi, M., & Fukumoto, H. 2021, ApJ, 907, 123 CrossRefGoogle Scholar
Javanmardi, B., & Kroupa, P. 2017, A&A, 597, A120 CrossRefGoogle Scholar
Javanmardi, B., Porciani, C., Kroupa, P., & Pflam-Altenburg, J. 2015, ApJ, 810, 47 CrossRefGoogle Scholar
Jiménez, J. B., & Maroto, A. L. 2007, PRD, 76, 023003 CrossRefGoogle Scholar
Land, K., & Magueijo, J. 2005, PRL, 95, 071301 CrossRefGoogle Scholar
Land, K., et al. 2008, MNRAS, 388, 1686 CrossRefGoogle Scholar
Lee, J. H., Pak, M., Lee, H.-R., & Song, H. 2019a, ApJ, 872, 78 CrossRefGoogle Scholar
Lee, J. H., Pak, M., Song, H., Lee, H.-R., Kim, S., & Jeong, H. 2019b, ApJ, 884, 104 CrossRefGoogle Scholar
Libeskind, N. I., Hoffman, Y., Forero-Romero, J., Gottlöber, S., Knebe, A., Steinmetz, M., & Klypin, A. 2013, MNRAS, 428, 2489 CrossRefGoogle Scholar
Libeskind, N. I., Knebe, A., Hoffman, Y., & Gottlöber, S. 2014, MNRAS, 443, 1274 CrossRefGoogle Scholar
Lin, H.-N., Li, X., & Chang, Z. 2016, MNRAS, 460, 617 CrossRefGoogle Scholar
Longo, M. J. 2007, arXiv, astro-ph/0703694Google Scholar
Longo, M. J. 2011, PLB, 699, 224 CrossRefGoogle Scholar
Mackenzie, R., Shanks, T., Bremer, M. N., Cai, Y.-C., Gunawardhana, M. L., Kovács, A., Norberg, P., & Szapudi, I. 2017, MNRAS, 470, 2328 CrossRefGoogle Scholar
Mariano, A., & Perivolaropoulos, L. 2013, PRD, 87, 043511 CrossRefGoogle Scholar
McClintock, J. E., Shafee, R., Narayan, R., Remillard, R. A., Davis, S. W., & Li, L.-X., 2006, ApJ, 652, 518 CrossRefGoogle Scholar
Mészáros, A. 2019, AN, 340, 564 CrossRefGoogle Scholar
Migkas, K., Schellenberger, G., Reiprich, T., Pacaud, F., Ramos-Ceja, M., & Lovisari, L. 2020, A&A, 636, A15 CrossRefGoogle Scholar
Morháč, M., Kliman, J., Matoušek, V., Veselsky, M., & Turzo, I. 2000, Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment, 443, 108 CrossRefGoogle Scholar
Ozsváth, I., & Schücking, E. 1962, Natur, 193, 1168 CrossRefGoogle Scholar
Ozsvath, I., & Schücking, E. 2001, CQG, 18, 2243 CrossRefGoogle Scholar
Panwar, M., Sandhu, P. K., Wadadekar, Y., & Jain, P. 2020, MNRAS, 499, 1226 Google Scholar
Pathria, R. 1972, Natur, 240, 298 CrossRefGoogle Scholar
Paul, N., Virag, N., & Shamir, L. 2018, Galaxies, 6, 64 CrossRefGoogle Scholar
Piao, Y.-S. 2005, PRD, 71, 087301 CrossRefGoogle Scholar
Piao, Y.-S., Feng, B., & Zhang, X. 2004, PRD, 69, 103520 CrossRefGoogle Scholar
Popławski, N. J. 2010, PLB, 694, 181 CrossRefGoogle Scholar
Pourhasan, R., Afshordi, N., & Mann, R. B. 2014, JCAP, 2014, 005 CrossRefGoogle Scholar
Rodrigues, D. C. 2008, PRD, 77, 023534 CrossRefGoogle Scholar
Santos, L., Cabella, P., Villela, T., & Zhao, W. 2015, A&A, 584, A115 CrossRefGoogle Scholar
Secrest, N., Hausegger, S., Rameez, M., Mohayaee, R., Sarkar, S., & Colin, J. 2020, arXiv, p. 2009.14826Google Scholar
Seshavatharam, U. 2010, PPh, 2, 7 Google Scholar
Seshavatharam, U., & Lakshminarayana, S. 2020a, IAARJ, 9Google Scholar
Seshavatharam, U., & Lakshminarayana, S. 2020b, IAARJ, 74Google Scholar
Shamir, L. 2011, ApJ, 736, 141 CrossRefGoogle Scholar
Shamir, L. 2012, PLB, 715, 25 Google Scholar
Shamir, L. 2013, Galaxies, 1, 210 CrossRefGoogle Scholar
Shamir, L. 2016, ApJ, 823, 32 CrossRefGoogle Scholar
Shamir, L. 2017a, PASA, 34, e44 Google Scholar
Shamir, L. 2017b, PASA, 34, e011 Google Scholar
Shamir, L. 2017c, ApSS, 362, 33 CrossRefGoogle Scholar
Shamir, L. 2019, arXiv, p. 1912.05429Google Scholar
Shamir, L. 2020a, PASA, 37, e053 Google Scholar
Shamir, L. 2020b, ApSS, 365, 136 Google Scholar
Shamir, L. 2020c, AN, 341, 324 CrossRefGoogle Scholar
Shamir, L. 2021, Particles, 4, 11 CrossRefGoogle Scholar
Sivaram, C., & Arun, K. 2012, OA, 5, 7 Google Scholar
Stuckey, W. 1994, AJP, 62, 788 CrossRefGoogle Scholar
Sugai, H., & Iye, M. 1995, MNRAS, 276, 327 Google Scholar
Taylor, A., & Jagannathan, P. 2016, MNRASL, 459, L36 CrossRefGoogle Scholar
Tempel, E., & Libeskind, N. I. 2013, ApJL, 775, L42 CrossRefGoogle Scholar
Tempel, E., Stoica, R. S., & Saar, E. 2013, MNRAS, 428, 1827 CrossRefGoogle Scholar
Wang, P., Guo, Q., Kang, X., & Libeskind, N. I. 2018, ApJ, 866, 138 CrossRefGoogle Scholar
Wang, P., & Kang, X. 2017, MNRASL, 468, L123 CrossRefGoogle Scholar
Wang, P., & Kang, X. 2018, MNRASL, 473, 1562 CrossRefGoogle Scholar
Zhang, Y., Yang, X., Faltenbacher, A., Springel, V., Lin, W., & Wang, H. 2009, ApJ, 706, 747 CrossRefGoogle Scholar
Zhe, C., Xin, L., & Sai, W. 2015, CPC, 39, 055101 Google Scholar
Figure 0

Figure 1. Examples of the peaks of the radial intensity plots of different galaxy images. The direction of the lines generated by the peaks identifies the curves of the galaxy arms and therefore can be used to determine the spin directions. The algorithm is fully symmetric and is not based on complex non-intuitive data-driven rules commonly used in machine learning.

Figure 1

Table 1. The number of galaxies in different right ascension ranges.

Figure 2

Table 2. The number of galaxies in different declination ranges.

Figure 3

Table 3. The number of galaxies in different z ranges. The distribution is determined by a subset of 17 027 galaxies that had redshift in the 2dF redshift survey.

Figure 4

Figure 2. Asymmetry in the distribution of the galaxies in different RA ranges. The graph shows inverse asymmetry in corresponding sky regions in opposite hemispheres.

Figure 5

Table 4. Number of clockwise and counterclockwise galaxies in opposite hemispheres. The P is the binomial distribution probability to have such difference or stronger by chance when assuming 0.5 probability for a galaxy to spin clockwise or counterclockwise.

Figure 6

Figure 3. The probability of a dipole axis in galaxy spin directions from every possible integer $(\alpha,\delta)$ combination.

Figure 7

Figure 4. The probability of a dipole axis in the galaxy spin directions when the galaxies are assigned with random spin directions.

Figure 8

Figure 5. The probability of a dipole axis formed by the galaxy spin directions of $\sim\!3.3\times10^4$ Pan-STARRS galaxies (Shamir 2020b). The profile is very similar to the profile formed by the galaxy spin directions of the galaxies imaged by the DESI Legacy Survey as shown in Figure 3.

Figure 9

Figure 6. The probability of a dipole axis in different $(\alpha,\delta)$ when using $\sim\!3.3\times 10^4$ SDSS galaxies (Shamir 2020b).

Figure 10

Figure 7. The profile of probabilities of a dipole axis in the spin directions of HST galaxies (Shamir 2020a).

Figure 11

Figure 8. The profile of probabilities of a quadrupole axis in the spin directions of DESI Legacy Survey galaxies.

Figure 12

Figure 9. The profile of a quadrupole in Pan-STARRS (Shamir 2020b).

Figure 13

Figure 10. The profile of a quadrupole in SDSS (Shamir 2020b).