Eccentric search for Neutron star-black hole (NSBH) and binary neutron star (BNS) mergers within O3 advanced LIGO and advanced VIRGO data
[Rahul Dhurkunde]1, 2, Alexander H. Nitz3,
1. Max-Planck-Institut for Gravitationsphysik (Albert-Einstein-Institut), D-30167 Hannover, Germany
2. Leibniz Universitat Hannover, D-30167 Hannover, Germany
3. Department of Physics, Syracuse University, Syracuse, NY 13244, USA
(Image credits: Soheb Mandhai)
The possible formation histories of neutron star binaries remain unresolved by current gravitational-wave catalogs. The detection of an eccentric binary system could be vital in constraining compact binary formation models. We present the first search for aligned spin eccentric neutron star-black hole binaries (NSBH) and the most sensitive search for aligned-spin eccentric binary neutron star (BNS) systems using data from the third observing run of the advanced LIGO and advanced Virgo detectors. No new statistically significant candidates are found; we constrain the local merger rate to be less than 150
```
Eccentric-search-O3/
├── configs/ # Configuration files for the analysis
├── data/ # Config files specific to LIGO observing run data
├── injections/ # Files used to generate injections for the search
├── Jupyter-notebooks/ # Notebooks for plotting upper limits (observational and idealized)
├── measurability-analysis/ # Files to investigate measurable eccentric systems
│ ├── Full-simplified-PE-comparision-plots/ # Comparision corner plots for the different PE runs
│ ├── inferenc-configs/ # Configs for the PE analysis
│ ├── results/ # Measurable eccentric systems as a function of mchirp and eccentricity
├── psds/ # Contains various PSDs used in the study
├── sensitivity/ # Directory containing scripts and results used to obtain the observational constraints of our search
│ ├── idealized-search/ # Script for computing detectability of sources
│ ├── injections-results/ # Found and missed injections results from our search
│ ├── library/ # Custom PyCBC scripts to get VT and merger rate for our injection set.
│ ├── pop-models/ # Mchirp and eccentricity distributions for astrophysical models used.
│ └── precession-bais/ # Files to compute bias in merger rate due to neglecting precession.
├── README.md # Project documentation
└── LICENSE # License information
```
A preprint version of the paper is available on arXiv. This release contains the following:
- Search
- Configuration files for the search, template bank, and injections used for the analysis.
- Search results
- List of top candidates
- The search sensitivity as a function of mchirp and eccentricity (HDF5 files).
- Constraints
- Population synthesis data -- Mchirp and eccentricity samples.
- Noise ASDs used to compute the optimal SNRs for the idealized searches.
- Jupyter-lab notebooks to obtain the 90 % upper limits on the local merger rate.
- Measurability analysis
- Scripts to compute the simplified Bayesian inference.
- Dictionary of measurable binary sources for given SNRs (keys).
** The simulated data for the idealized searches is not provided due to the file size limit on GITHUB. This can be made available upon reasonable requests.
| Isolated binary (Belczynski et al. (2018a)) | [8.0, 50.0] |
| Globular cluster (Arca Sedda (2020b)) | <=0.1 |
| Triples (Trani et al. (2021)) | [0.04, 0.34] |
| Nuclear cluster (Fragione et al. (2019)) | [0.06. 0.1] |
| Isolated binary (Belczynski et al. (2018a)) | 149.02243058810643 |
| Globular cluster (Arca Sedda (2020b)) | 53.36526395563427 |
| Triples (Trani et al. (2021)) | 97.976810617951 |
| Nuclear cluster (Fragione et al. (2019)) | 70.44463776334753 |
We have estimated constraints for an idealized search that covers the entire parameter space of the astrophysical model, and captures the signal SNR perfectly. We provide three different types of constraints on each population:
- Full population
- Eccentric systems above a fixed eccentricity >= 0.01
- Measurable eccentric systems
- Three A+ detectors
| Isolated binary (Belczynski et al. (2018a)) | 3.8967851099830795 |
| Globular cluster (Arca Sedda (2020b)) | 0.8313479171178976 |
| Triples (Trani et al. (2021)) | 0.5604497225737369 |
| Nuclear cluster (Fragione et al. (2019)) | 0.7834932299108661 |
- Three Asharp detectors
| Isolated binary (Belczynski et al. (2018a)) | 0.48555766392578537 |
| Globular cluster (Arca Sedda (2020b)) | 0.10645969508981815 |
| Triples (Trani et al. (2021)) | 0.0778671896131999 |
| Nuclear cluster (Fragione et al. (2019)) | 0.10731093611667676 |
- CE (40km baseline) + CE(20km baseline)
| Isolated binary (Belczynski et al. (2018a)) | 0.0021919213943572277 |
| Globular cluster (Arca Sedda (2020b)) | 0.0011257530053556922 |
| Triples (Trani et al. (2021)) | 0.0010080234416283082 |
| Nuclear cluster (Fragione et al. (2019)) | 0.001082967826882465 |
- ET
| Isolated binary (Belczynski et al. (2018a)) | 0.010134497215643601 |
| Globular cluster (Arca Sedda (2020b)) | 0.00249218885268609 |
| Triples (Trani et al. (2021)) | 0.001648579773221853 |
| Nuclear cluster (Fragione et al. (2019)) | 0.0019435434126820943 |
- Three A+ detectors
| Isolated binary (Belczynski et al. (2018a)) | 5757.5 |
| Globular cluster (Arca Sedda (2020b)) | 26.77906976744186 |
| Triples (Trani et al. (2021)) | 0.8303288145370638 |
| Nuclear cluster (Fragione et al. (2019)) | 0.8947859196518766 |
- Three Asharp detectors
| Isolated binary (Belczynski et al. (2018a)) | 677.3529411764706 |
| Globular cluster (Arca Sedda (2020b)) | 3.330922765403529 |
| Triples (Trani et al. (2021)) | 0.1157658744520851 |
| Nuclear cluster (Fragione et al. (2019)) | 0.12335693701993637 |
- CE (40km baseline) + CE(20km baseline)
| Isolated binary (Belczynski et al. (2018a)) | 2.6722573839662442 |
| Globular cluster (Arca Sedda (2020b)) | 0.034350762054564186 |
| Triples (Trani et al. (2021)) | 0.0014993702562062906 |
| Nuclear cluster (Fragione et al. (2019)) | 0.0012444783733012645 |
- ET
| Isolated binary (Belczynski et al. (2018a)) | 12.179326923076921 |
| Globular cluster (Arca Sedda (2020b)) | 0.07535994764397905 |
| Triples (Trani et al. (2021)) | 0.0024534832818740725 |
| Nuclear cluster (Fragione et al. (2019)) | 0.002231164612793901 |
- Three A+ detectors
| Isolated binary (Belczynski et al. (2018a)) | 11520.0 |
| Globular cluster (Arca Sedda (2020b)) | 62.92 |
| Triples (Trani et al. (2021)) | 5.388 |
| Nuclear cluster (Fragione et al. (2019)) | 1.922 |
- Three Asharp detectors
| Isolated binary (Belczynski et al. (2018a)) | 1279.0 |
| Globular cluster (Arca Sedda (2020b)) | 8.53 |
| Triples (Trani et al. (2021)) | 0.7375 |
| Nuclear cluster (Fragione et al. (2019)) | 0.2632 |
- CE (40km baseline) + CE(20km baseline)
| Isolated binary (Belczynski et al. (2018a)) | 1.712 |
| Globular cluster (Arca Sedda (2020b)) | 0.06979 |
| Triples (Trani et al. (2021)) | 0.009821 |
| Nuclear cluster (Fragione et al. (2019)) | 0.004279 |
- ET
| Isolated binary (Belczynski et al. (2018a)) | 11.73 |
| Globular cluster (Arca Sedda (2020b)) | 0.08415 |
| Triples (Trani et al. (2021)) | 0.003113 |
| Nuclear cluster (Fragione et al. (2019)) | 0.002463 |
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