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Riga 35: <math>{\cal S}' = \sqrt{8\pi G} \frac{\eta p^\mu p^\nu \epsilon_{\mu\nu}}{p \cdot p_G - i \eta \varepsilon}{\cal S}-i\sqrt{8\pi G} \frac{\eta p^\mu ({p_G}_\rho J^{\rho\nu}) \epsilon_{\mu\nu}}{p \cdot p_G - i \eta \varepsilon}{\cal S} + O(p_G^1)</math>, dove <math>J^{\rho\nu}</math>rappresenta il momento angolare della particella che interagisce con il gravitone.<ref>{{Cita libro\|nome=Freddy\|cognome=Cachazo\|nome2=Andrew\|cognome2=Strominger\|wkautore2=Andrew Strominger\|titolo=Evidence for a New Soft Graviton Theorem\|url=https://arxiv.org/pdf/1404.4091\|data=aprile 2014\|pp=1-3\|capitolo=1 .Introduction}}</ref> [[:en:Francis_E._Low\|F.E. Low]] per il fotone [2] F. E. Low, “Scattering of light of very low frequency by systems of spin 1/2,” Phys. Rev. 96 (1954) 1428–32. [4] F. E. Low, “Bremsstrahlung of very low-energy quanta in elementary particle collisions,”Phys. Rev. 110 (1958) 974–77. == Dimostrazione == Riga 81 ⟶ 88: '''propagator.''' Andrew Strominger - Lectures on the Infrared Structure of Gravity and Gauge Theory, p. 35 Riga 93 ⟶ 98: Weinberg’s soft graviton theorem<ref name=":0" /> is a universal formula relating any S-matrix element in any quantum theory including gravity to a second S-matrix element which differs only by the addition of a graviton whose four-momentum is taken to zero. Remarkably, the formula is blind to the spin or any other quantum numbers of the asymptotic particles involved in the S-matrix element. https://dash.harvard.edu/bitstream/handle/1/29374083/1401.7026.pdf;jsessionid=6392FB47A36DFFDF342EC0BC22893C9E?sequence=1 ''Consider an amplitude M involving some incoming and some outgoing particles. Now, consider the same amplitude with an additional soft-photon (''<math>\omega_{\text{photon}} \to 0</math>'') coupled to one of the particles. Call this amplitude M'. The two amplitudes are related by'' ~~<math>{\cal M}' = {\cal M} \frac{\eta q p \cdot \epsilon}{p \cdot p_\gamma - i \eta \varepsilon}</math>~~ ''where p is the momentum of the particle that the photon couples to,'' <math>\epsilon</math>'' is the polarization of the photon and'' <math>p_\gamma</math>'' is the momentum of the soft-photon. ''<math>\eta = 1</math>''for outgoing particles and'' <math>\eta = -1</math>'' for incoming ones. Finally, q is the charge of the particle.'' ~~the proportionality factor relating M and M' is independent of the type of particle that the photon couples to.~~ == Note ==