An instability due to the nonlinear coupling of p-modes to g-modes: Implications for coalescing neutron star binaries

Weinberg, Nevin N.; Arras, Phil; Burkart, Joshua

doi:10.1088/0004-637X/769/2/121

Title: An instability due to the nonlinear coupling of p-modes to g-modes: Implications for coalescing neutron star binaries

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Abstract

A weakly nonlinear fluid wave propagating within a star can be unstable to three-wave interactions. The resonant parametric instability is a well-known form of three-wave interaction in which a primary wave of frequency ω {sub a} excites a pair of secondary waves of frequency ω {sub b} + ω {sub c} ≅ ω {sub a}. Here we consider a nonresonant form of three-wave interaction in which a low-frequency primary wave excites a high-frequency p-mode and a low-frequency g-mode such that ω {sub b} + ω {sub c} >> ω {sub a}. We show that a p-mode can couple so strongly to a g-mode of similar radial wavelength that this type of nonresonant interaction is unstable even if the primary wave amplitude is small. As an application, we analyze the stability of the tide in coalescing neutron star binaries to p-g mode coupling. We find that the equilibrium tide and dynamical tide are both p-g unstable at gravitational wave frequencies f {sub gw} ≳ 20 Hz and drive short wavelength p-g mode pairs to significant energies on very short timescales (much less than the orbital decay time due to gravitational radiation). Resonant parametric coupling to the tide is, by contrast, eithermore »« less

Authors:

Weinberg, Nevin N. ^[1]; Arras, Phil ^[2]; Burkart, Joshua ^[3]

Department of Physics, and Kavli Institute for Astrophysics and Space Research, Massachusetts Institute of Technology, Cambridge, MA 02139 (United States)
Department of Astronomy, University of Virginia, P.O. Box 400325, Charlottesville, VA 22904-4325 (United States)
Department of Physics, University of California, 366 LeConte Hall, Berkeley, CA 94720 (United States)

Publication Date:: Sat Jun 01 00:00:00 EDT 2013

OSTI Identifier:: 22342052

Resource Type:: Journal Article

Journal Name:: Astrophysical Journal

Additional Journal Information:: Journal Volume: 769; Journal Issue: 2; Other Information: Country of input: International Atomic Energy Agency (IAEA); Journal ID: ISSN 0004-637X

Country of Publication:: United States

Language:: English

Subject:: 79 ASTROPHYSICS, COSMOLOGY AND ASTRONOMY; AMPLITUDES; BINARY STARS; DECAY; EMISSION; EQUILIBRIUM; ERRORS; EVOLUTION; FLUIDS; GRAVITATIONAL RADIATION; GRAVITATIONAL WAVES; HYDRODYNAMICS; INTERACTIONS; NEUTRON STARS; NEUTRONS; OSCILLATIONS; PARAMETRIC INSTABILITIES; SATURATION; STABILITY; WAVE PROPAGATION; WAVELENGTHS

Citation Formats


                    Weinberg, Nevin N., Arras, Phil, and Burkart, Joshua. An instability due to the nonlinear coupling of p-modes to g-modes: Implications for coalescing neutron star binaries.  United States: N. p., 2013. 
        Web.  doi:10.1088/0004-637X/769/2/121.

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                    Weinberg, Nevin N., Arras, Phil, & Burkart, Joshua. An instability due to the nonlinear coupling of p-modes to g-modes: Implications for coalescing neutron star binaries.  United States.  https://doi.org/10.1088/0004-637X/769/2/121

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                    Weinberg, Nevin N., Arras, Phil, and Burkart, Joshua. 2013.  
        "An instability due to the nonlinear coupling of p-modes to g-modes: Implications for coalescing neutron star binaries".  United States.  https://doi.org/10.1088/0004-637X/769/2/121.

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@article{osti_22342052,

  title        = {An instability due to the nonlinear coupling of p-modes to g-modes: Implications for coalescing neutron star binaries},

  author       = {Weinberg, Nevin N. and Arras, Phil and Burkart, Joshua},

  abstractNote = {A weakly nonlinear fluid wave propagating within a star can be unstable to three-wave interactions. The resonant parametric instability is a well-known form of three-wave interaction in which a primary wave of frequency ω {sub a} excites a pair of secondary waves of frequency ω {sub b} + ω {sub c} ≅ ω {sub a}. Here we consider a nonresonant form of three-wave interaction in which a low-frequency primary wave excites a high-frequency p-mode and a low-frequency g-mode such that ω {sub b} + ω {sub c} >> ω {sub a}. We show that a p-mode can couple so strongly to a g-mode of similar radial wavelength that this type of nonresonant interaction is unstable even if the primary wave amplitude is small. As an application, we analyze the stability of the tide in coalescing neutron star binaries to p-g mode coupling. We find that the equilibrium tide and dynamical tide are both p-g unstable at gravitational wave frequencies f {sub gw} ≳ 20 Hz and drive short wavelength p-g mode pairs to significant energies on very short timescales (much less than the orbital decay time due to gravitational radiation). Resonant parametric coupling to the tide is, by contrast, either stable or drives modes at a much smaller rate. We do not solve for the saturation of the p-g instability and therefore we cannot say precisely how it influences the evolution of neutron star binaries. However, we show that if even a single daughter mode saturates near its wave breaking amplitude, the p-g instability of the equilibrium tide will (1) induce significant orbital phase errors (Δφ ≳ 1 radian) that accumulate primarily at low frequencies (f {sub gw} ≲ 50 Hz) and (2) heat the neutron star core to a temperature of T ∼ 10{sup 10} K. Since there are at least ∼100 unstable p-g daughter pairs, Δφ and T are potentially much larger than these values. Tides might therefore significantly influence the gravitational wave signal and electromagnetic emission from coalescing neutron star binaries at much larger orbital separations than previously thought.},

  doi          = {10.1088/0004-637X/769/2/121},

  url          = {https://www.osti.gov/biblio/22342052},
  journal      = {Astrophysical Journal},

  issn         = {0004-637X},

  number       = 2,

  volume       = 769,

  place        = {United States},

  year         = {Sat Jun 01 00:00:00 EDT 2013},

  month        = {Sat Jun 01 00:00:00 EDT 2013}

}

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