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Gravitational Radiation from Massless Particle Collisions
We compute classical gravitational bremsstrahlung from the gravitational scattering of two massless particles at leading order in the (center of mass) deflection angle $\theta\sim 8 G E/b \ll 1$. The calculation, although non-perturbative in the gravitational constant, is surprisingly simple and yie...
| Autores principales: | , |
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| Lenguaje: | eng |
| Publicado: |
2014
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| Acceso en línea: | https://dx.doi.org/10.1088/0264-9381/33/12/125012 http://cds.cern.ch/record/1756004 |
| _version_ | 1780943328751124480 |
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| author | Gruzinov, Andrei Veneziano, Gabriele |
| author_facet | Gruzinov, Andrei Veneziano, Gabriele |
| author_sort | Gruzinov, Andrei |
| collection | CERN |
| description | We compute classical gravitational bremsstrahlung from the gravitational scattering of two massless particles at leading order in the (center of mass) deflection angle $\theta\sim 8 G E/b \ll 1$. The calculation, although non-perturbative in the gravitational constant, is surprisingly simple and yields explicit formulae --in terms of multidimensional integrals-- for the frequency and angular distribution of the radiation. In the range $ b^{-1} < \omega < (GE)^{-1}$, the GW spectrum behaves like $ \log (1/GE\omega) d \omega$, is confined to cones of angular sizes (around the deflected particle trajectories) ranging from $O(\theta)$ to $O(1/\omega b)$, and exactly reproduces, at its lower end, a well-known zero-frequency limit. At $\omega > (GE)^{-1}$ the radiation is confined to cones of angular size of order $\theta (GE\omega)^{-1/2}$ resulting in a scale-invariant ($d\omega/\omega$) spectrum. The total efficiency in GW production is dominated by this "high frequency" region and is formally logarithmically divergent in the UV. If the spectrum is cutoff at the limit of validity of our approximations ($ GE \omega \sim \theta^{-2}$), the fraction of incoming energy radiated away turns out to be $\frac{1}{\pi} \theta ^2 \log \theta^{-2}$ at leading logarithmic accuracy. |
| id | cern-1756004 |
| institution | Organización Europea para la Investigación Nuclear |
| language | eng |
| publishDate | 2014 |
| record_format | invenio |
| spelling | cern-17560042023-03-12T04:08:47Zdoi:10.1088/0264-9381/33/12/125012http://cds.cern.ch/record/1756004engGruzinov, AndreiVeneziano, GabrieleGravitational Radiation from Massless Particle CollisionsGeneral Relativity and CosmologyWe compute classical gravitational bremsstrahlung from the gravitational scattering of two massless particles at leading order in the (center of mass) deflection angle $\theta\sim 8 G E/b \ll 1$. The calculation, although non-perturbative in the gravitational constant, is surprisingly simple and yields explicit formulae --in terms of multidimensional integrals-- for the frequency and angular distribution of the radiation. In the range $ b^{-1} < \omega < (GE)^{-1}$, the GW spectrum behaves like $ \log (1/GE\omega) d \omega$, is confined to cones of angular sizes (around the deflected particle trajectories) ranging from $O(\theta)$ to $O(1/\omega b)$, and exactly reproduces, at its lower end, a well-known zero-frequency limit. At $\omega > (GE)^{-1}$ the radiation is confined to cones of angular size of order $\theta (GE\omega)^{-1/2}$ resulting in a scale-invariant ($d\omega/\omega$) spectrum. The total efficiency in GW production is dominated by this "high frequency" region and is formally logarithmically divergent in the UV. If the spectrum is cutoff at the limit of validity of our approximations ($ GE \omega \sim \theta^{-2}$), the fraction of incoming energy radiated away turns out to be $\frac{1}{\pi} \theta ^2 \log \theta^{-2}$ at leading logarithmic accuracy.We compute classical gravitational bremsstrahlung from the gravitational scattering of two massless particles at leading order in the (centre of mass) deflection angle $\theta \sim 4G\sqrt{s}/b=8\mathrm{GE}/b\ll 1$. The calculation, although non-perturbative in the gravitational constant, is surprisingly simple and yields explicit formulae—in terms of multidimensional integrals—for the frequency and angular distribution of the radiation. In the range ${b}^{-1}\lt \omega \lt {(\mathrm{GE})}^{-1}$, the GW spectrum behaves like $\mathrm{log}(1/\mathrm{GE}\omega ){\rm{d}}\omega $, is confined to cones of angular sizes (around the deflected particle trajectories) ranging from $O(\theta )$ to $O(1/\omega b)$, and exactly reproduces, at its lower end, a well-known zero-frequency limit. At $\omega \gt {(\mathrm{GE})}^{-1}$ the radiation is confined to cones of angular size of order $\theta {(\mathrm{GE}\omega )}^{-1/2}$ resulting in a scale-invariant (${\rm{d}}\omega /\omega $) spectrum. The total efficiency in GW production is dominated by this ‘high frequency’ region and is formally logarithmically divergent in the UV. If the spectrum is cutoff at the limit of validity of our approximations (where a conjectured bound on GW power is also saturated), the fraction of incoming energy radiated away turns out to be $\tfrac{1}{2\pi }{\theta }^{2}\mathrm{log}{\theta }^{-2}$ at leading logarithmic accuracy.We compute classical gravitational bremsstrahlung from the gravitational scattering of two massless particles at leading order in the (center of mass) deflection angle $\theta\sim 4 G \sqrt{s}/b = 8 G E/b \ll 1$. The calculation, although non-perturbative in the gravitational constant, is surprisingly simple and yields explicit formulae --in terms of multidimensional integrals-- for the frequency and angular distribution of the radiation. In the range $ b^{-1} < \omega < (GE)^{-1}$, the GW spectrum behaves like $ \log (1/GE\omega) d \omega$, is confined to cones of angular sizes (around the deflected particle trajectories) ranging from $O(\theta)$ to $O(1/\omega b)$, and exactly reproduces, at its lower end, a well-known zero-frequency limit. At $\omega > (GE)^{-1}$ the radiation is confined to cones of angular size of order $\theta (GE\omega)^{-1/2}$ resulting in a scale-invariant ($d\omega/\omega$) spectrum. The total efficiency in GW production is dominated by this "high frequency" region and is formally logarithmically divergent in the UV. If the spectrum is cutoff at the limit of validity of our approximations (where a conjectured bound on GW power is also saturated), the fraction of incoming energy radiated away turns out to be $\frac{1}{2 \pi} \theta ^2 \log \theta^{-2}$ at leading logarithmic accuracy.arXiv:1409.4555oai:cds.cern.ch:17560042014-09-16 |
| spellingShingle | General Relativity and Cosmology Gruzinov, Andrei Veneziano, Gabriele Gravitational Radiation from Massless Particle Collisions |
| title | Gravitational Radiation from Massless Particle Collisions |
| title_full | Gravitational Radiation from Massless Particle Collisions |
| title_fullStr | Gravitational Radiation from Massless Particle Collisions |
| title_full_unstemmed | Gravitational Radiation from Massless Particle Collisions |
| title_short | Gravitational Radiation from Massless Particle Collisions |
| title_sort | gravitational radiation from massless particle collisions |
| topic | General Relativity and Cosmology |
| url | https://dx.doi.org/10.1088/0264-9381/33/12/125012 http://cds.cern.ch/record/1756004 |
| work_keys_str_mv | AT gruzinovandrei gravitationalradiationfrommasslessparticlecollisions AT venezianogabriele gravitationalradiationfrommasslessparticlecollisions |