The NANOGrav 15 yr Data Set: Search for Signals from New Physics

Afzal, Adeela; Agazie, Gabriella; Anumarlapudi, Akash; Archibald, Anne M.; Arzoumanian, Zaven; Baker, P. T.; Bazzan, M.; Blanco-Pillado, José J.; Blecha, Laura; Boddy, Kimberly K.; Brazier, A.; Brook, Paul R.; Burke-Spolaor, S.; Burnette, Rand; Case, Ryan; Charisi, Maria; Chatterjee, Shami; Chatziioannou, Katerina; Cheeseboro, B. D.; Chen, Siyuan; Cohen, Tyler; Cordes, J. M.; Cornish, N.; Crawford, F.; Cromartie, H. T.; Crowter, Kathryn; Cutler, Curt; DeCesar, Megan E.; DeGan, Dallas; Demorest, Paul; Deng, Heling; Dolch, Timothy; Drachler, Brendan; Eckardstein, Richard von; Ferrara, E. C.; Fiore, William; Fonseca, Emmanuel; Freedman, Gabriel E.; Garver-Daniels, Nathaniel; Gentile, Peter A.; Gersbach, Kyle A.; Glaser, Joseph; Good, Deborah C.; Guertin, Louis; Gültekin, Kayhan; Hazboun, Jeffrey S.; Hourihane, S.; Islo, Kristina; Jennings, Ross J.; Johnson, Aaron D.; Jones, Megan L.; Kaiser, Andrew R.; Kaplan, David L.; Kelley, Luke Zoltan; Kerr, M.; Key, J. S.; Laal, Nima; Lam, Michael T.; Lamb, William G.; Lazio, T. Joseph W.; Lee, Vincent S. H.; Lewandowska, N.; Santos, Rafael R. Lino dos; Littenberg, T. B.; Liu, Tingting; Lorimer, D. R.; Luo, Jing; Lynch, R.; Ma, Chung‐Pei; Madison, D. R.; McEwen, Alexander; McKee, James W.; McLaughlin, M. A.; McMann, Natasha; Meyers, Bradley W.; Meyers, P. M.; Mingarelli, Chiara M. F.; Mitridate, Andrea; Nay, Jonathan; Natarajan, Priyamvada; Ng, Cherry; Nice, D. J.; Ocker, Stella Koch; Olum, Ken D.; Pennucci, Timothy T.; Perera, B. B. P.; Petrov, Polina; Pol, Nihan S.; Radovan, H. A.; Ransom, S. M.; Ray, Paul S.; Romano, Joseph D.; Sardesai, Shashwat C.; Schmiedekamp, Ann; Schmiedekamp, Carl; Schmitz, Kai; Schröder, Tobias; Schult, Levi; Shapiro-Albert, Brent J.; Siemens, X.; Simon, Joseph; Siwek, Magdalena S.; Stairs, I. H.; Stinebring, D. R.; Stovall, K.; Stratmann, Peter; Sun, Jerry P.; Susobhanan, Abhimanyu; Swiggum, Joseph K.; Taylor, Jacob M.; Taylor, Stephen R.; Trickle, Tanner; Turner, Jacob E.; Ünal, Caner; Vallisneri, Michele; Verma, Sonali; Vigeland, Sarah J.; Wahl, Haley M.; Wang, Qiaohong; Witt, Caitlin A.; Wright, David; Young, Olivia; Zurek, Kathryn M.

doi:10.3847/2041-8213/acdc91

Cited by 202 publications

(137 citation statements)

References 374 publications

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“…In June 2023 the NANOGrav, EPTA, PPTA, and CPTA PTA experiments reported evidence for excess red common-spectrum signals in their latest datasets (NANOGrav 15-year, EPTA DR2 complemented with InPTA DR1, PPTA DR3, and CPTA DR1), with interpulsar correlations following the HD pattern [26][27][28][29][30][31][32][33][34][35][36][37][38][39][40][41][42][43]. Considering that all four signals are consistent with each other, and the fact that NANOGrav achieved the most precise determination of the spectral index (which not all experiments managed to infer), for concreteness and simplicity I will focus on the NANOGrav 15-year signal in the remainder of this work, but I expect my main conclusions to broadly carry over to the results of the other three PTA experiments as well.…”

Section: Methodsmentioning

confidence: 99%

“…Very recently, in June 2023, various PTA experiments, including NANOGrav, EPTA, PPTA, and the Chinese Pulsar Timing Array (CPTA), in the case of EPTA including also data from the Indian PTA (InPTA), reported on the analyses of their latest datasets, which all confirm the presence of excess red common-spectrum signals, with strain amplitude of order O(10 −15 ) at the reference frequency f = 1 yr −1 [26][27][28][29][30][31][32][33][34][35][36][37][38][39][40][41][42][43]. Importantly, all analyses report evidence (with varying strength) for HD correlations, which point to a genuine GW origin for the signals, in turn making these the first convincing detections of a SGWB signal in the nHz range.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Inflationary interpretation of the stochastic gravitational wave background signal detected by pulsar timing array experiments

Vagnozzi

2023

Journal of High Energy Astrophysics

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Inflationary interpretation of the stochastic gravitational wave background signal detected by pulsar timing array experiments

Vagnozzi

2023

Journal of High Energy Astrophysics

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“…Given the large measurement and modeling uncertainties of the GWB spectrum, detecting an individual binary would also be the most reliable indicator that the background is indeed due to binaries instead of other cosmological sources (Afzal et al 2023). These prospects motivate the continuous improvement of our search algorithms such as making them more efficient , searching for multiple binaries simultaneously (see, e.g., Babak & Sesana 2012;Bécsy & Cornish 2020), searching for a correlated background along with the individual binary, searching for eccentric binaries (see, e.g., Taylor et al 2016;Susobhanan et al 2020;Susobhanan 2022), and many more.…”

Section: Discussionmentioning

confidence: 99%

The NANOGrav 15 yr Data Set: Bayesian Limits on Gravitational Waves from Individual Supermassive Black Hole Binaries

Agazie¹,

Anumarlapudi²,

Archibald

et al. 2023

ApJL

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Evidence for a low-frequency stochastic gravitational-wave background has recently been reported based on analyses of pulsar timing array data. The most likely source of such a background is a population of supermassive black hole binaries, the loudest of which may be individually detected in these data sets. Here we present the search for individual supermassive black hole binaries in the NANOGrav 15 yr data set. We introduce several new techniques, which enhance the efficiency and modeling accuracy of the analysis. The search uncovered weak evidence for two candidate signals, one with a gravitational-wave frequency of ∼4 nHz, and another at ∼170 nHz. The significance of the low-frequency candidate was greatly diminished when Hellings–Downs correlations were included in the background model. The high-frequency candidate was discounted due to the lack of a plausible host galaxy, the unlikely astrophysical prior odds of finding such a source, and since most of its support comes from a single pulsar with a commensurate binary period. Finding no compelling evidence for signals from individual binary systems, we place upper limits on the strain amplitude of gravitational waves emitted by such systems. At our most sensitive frequency of 6 nHz, we place a sky-averaged 95% upper limit of 8 × 10−15 on the strain amplitude. We also calculate an exclusion volume and a corresponding effective radius, within which we can rule out the presence of black hole binaries emitting at a given frequency.

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“…As displayed, there exist several FOPTs with T * ≃ 1 ÷ 100 MeV and α ≃ 0.1 ÷ 0.3 that are compatible with the NANOGrav excess of a stochastic spectrum. The degeneracy in the (T * , α) parameter space has also been obtained in the recent Monte Carlo analysis by the NANOGrav collaboration [5] and allows to accommodate the results by the PPTA and EPTA collaborations which report a different best fit within 2σ.…”

mentioning

confidence: 89%

“…Fresh batches of pulsar timing (PTA) data have recently been released by various collaborations, reporting an excess of a stochastic spectrum which appears to be compatible with a gravitational wave background (GWB) at frequencies around f ∼ 1 ÷ 10 nHz. Among these, the North American Nanohertz Observatory for Gravitational Waves (NANOGrav) collaboration has recently released the data collected in the first 15 yrs of activity [1][2][3][4][5]. In addition to previous analyses [6][7][8][9], the recent NANOGrav 15-year data also reports the evidence for quadrupolar correlations that follow the signature described by Hellings and Downs [10] and is then conclusive with regard to the nature of the detection.…”

mentioning

confidence: 99%

NANOGrav results and dark first order phase transitions

Addazi

Cai

Gan

et al. 2021

Sci. China Phys. Mech. Astron.

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We show that the recent detection of a gravitational wave (GW) background reported by various pulsar timing array (PTA) collaborations including NANOGrav-15yr, PPTA, EPTA, and CPTA can be explained in terms of first order phase transitions (FOPTs) from dark sector models (DSM). Specifically, we explore a model for first order phase transitions that involves the majoron, a Nambu-Goldstone boson that is emerging from the spontaneous symmetry breaking of a U (1)L or U (1)B−L symmetry. We show how the predicted GW power spectrum, with a realistic choice of the FOPT parameters, is consistent with 1-σ deviations from the estimated parameters of the background detected by the PTA collaborations.must be included in the Lagrangian.

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The NANOGrav 15 yr Data Set: Search for Signals from New Physics

Cited by 202 publications

References 374 publications

Inflationary interpretation of the stochastic gravitational wave background signal detected by pulsar timing array experiments

Inflationary interpretation of the stochastic gravitational wave background signal detected by pulsar timing array experiments

The NANOGrav 15 yr Data Set: Bayesian Limits on Gravitational Waves from Individual Supermassive Black Hole Binaries

NANOGrav results and dark first order phase transitions

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