Scalar scattering amplitude in the Gaussian wave-packet formalism

Abstract We compute an $s$-channel $2\to2$ scalar scattering $\phi\phi\to\Phi\to\phi\phi$ in the Gaussian wave-packet formalism at the tree level. We find that wave-packet effects, including shifts of the pole and the width of the propagator of $\Phi$, persist even when we do not take into account the time boundary effect for $2\to2$ proposed earlier. An interpretation of the result is that a heavy scalar $1\to2$ decay $\Phi\to\phi\phi$, taking into account the production of $\Phi$, does not exhibit the in-state time boundary effect unless we further take into account in-boundary effects for the $2\to2$ scattering. We also show various plane-wave limits.

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On non-perturbative unitarity in gravitational scattering

The European Physical Journal C ◽

10.1140/epjc/s10052-019-7403-2 ◽

2019 ◽

Vol 79 (11) ◽

Author(s):

Ivo Sachs ◽

Tung Tran

Keyword(s):

General Relativity ◽

Plane Wave ◽

Low Energy ◽

Tree Level ◽

Back Reaction ◽

Classical Plane ◽

Gravitational Scattering ◽

Scalar Scattering ◽

Regge Limit

Abstract We argue that the tree-level graviton-scalar scattering in the Regge limit is unitarized by non-perturbative effects within General Relativity alone, that is without resorting to any extension thereof. At Planckian energy the back reaction of the incoming graviton on the background geometry produces a non-perturbative plane wave which softens the UV-behavior in turn. Our amplitude interpolates between the perturbative graviton-scalar scattering at low energy and scattering on a classical plane wave in the Regge limit that is bounded for all values of s.

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Composing effective prediction at five points

Journal of High Energy Physics ◽

10.1007/jhep06(2021)169 ◽

2021 ◽

Vol 2021 (6) ◽

Author(s):

John Joseph M. Carrasco ◽

Laurentiu Rodina ◽

Suna Zekioğlu

Keyword(s):

Gauge Theory ◽

Scattering Amplitude ◽

Building Blocks ◽

Tree Level ◽

Critical Aspect ◽

Higher Derivative ◽

Higher Dimensional ◽

Single Trace ◽

The Relationship ◽

Double Copy

Abstract Color-kinematics duality in the adjoint has proven key to the relationship between gauge and gravity theory scattering amplitude predictions. In recent work, we demonstrated that at four-point tree-level, a small number of color-dual EFT building blocks could encode all higher-derivative single-trace massless corrections to gauge and gravity theories compatible with adjoint double-copy. One critical aspect was the trivialization of building higher-derivative color-weights — indeed, it is the mixing of kinematics with non-adjoint-type color-weights (like the permutation-invariant d4) which permits description via adjoint double-copy. Here we find that such ideas clarify the predictions of local five-point higher-dimensional operators as well. We demonstrate how a single scalar building block can be combined with color structures to build higher-derivative color factors that generate, through double copy, the amplitudes associated with higher-derivative gauge-theory operators. These may then be suitably mapped, through another double-copy, to higher-derivative corrections in gravity.

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GEOMETRIC PHASES, SQUEEZED QUANTUM STATES AND GAUSSIAN WAVE PACKET STATES OF RELIC GRAVITONS

International Journal of Modern Physics Conference Series ◽

10.1142/s2010194512008136 ◽

2012 ◽

Vol 18 ◽

pp. 13-17

Author(s):

K. BAKKE ◽

I. A. PEDROSA ◽

C. FURTADO

Keyword(s):

Wave Packet ◽

Linear Time ◽

Invariant Operator ◽

Quantum States ◽

Time Dependent ◽

Gaussian Wave Packet ◽

Geometric Phases ◽

Uncertainty Product ◽

Quantized Field ◽

Generalized Time

In this contribution, we discuss quantum effects on relic gravitons described by the Friedmann-Robertson-Walker (FRW) spacetime background by reducing the problem to that of a generalized time-dependent harmonic oscillator, and find the corresponding Schrödinger states with the help of the dynamical invariant method. Then, by considering a quadratic time-dependent invariant operator, we show that we can obtain the geometric phases and squeezed quantum states for this system. Furthermore, we also show that we can construct Gaussian wave packet states by considering a linear time-dependent invariant operator. In both cases, we also discuss the uncertainty product for each mode of the quantized field.

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Solving Time-dependent Schrödinger Equation Using Gaussian Wave Packet Dynamics

Journal of the Korean Physical Society ◽

10.3938/jkps.73.1269 ◽

2018 ◽

Vol 73 (9) ◽

pp. 1269-1278

Author(s):

Min-Ho Lee ◽

Chang Woo Byun ◽

Nark Nyul Choi ◽

Dae-Soung Kim

Keyword(s):

Schrödinger Equation ◽

Wave Packet ◽

Schrodinger Equation ◽

Time Dependent ◽

Gaussian Wave Packet ◽

Wave Packet Dynamics

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The phase-functions method and scalar amplitude of nucleon–nucleon scattering

International Journal of Modern Physics E ◽

10.1142/s0218301316500889 ◽

2016 ◽

Vol 25 (11) ◽

pp. 1650088

Author(s):

V. I. Zhaba

Keyword(s):

Single Channel ◽

Scattering Amplitude ◽

Nucleon Nucleon ◽

Phase Shifts ◽

Computational Method ◽

Nucleon Scattering ◽

The Difference ◽

Scalar Scattering ◽

Scalar Amplitude ◽

Phase Functions

A known phase-functions method (PFM) has been considered for calculation of a single-channel nucleon–nucleon scattering. The following partial waves of a nucleon–nucleon scattering have been considered using the phase shifts by PFM: 1S0-, 3P0-, 3P1-, 1D2-, 3F3-states for nn-scattering, 1S0-, 3P0-, 3P1-, 1D2-states for pp-scattering and 1S0-, 1P1-, 3P0-, 3P1-, 1D2-, 3D2-states for np-scattering. The calculations have been carried out using phenomenological nucleon–nucleon Nijmegen group potentials (NijmI, NijmII, Nijm93 and Reid93) and Argonne v18 potential. The scalar scattering amplitude has been calculated using the obtained phase shifts. Our results are not much different from those obtained by using the known phase shifts published in other papers. The difference between calculations depending on a computational method of phase shifts makes: for real (imaginary) parts 0.14–4.36% (0.16–4.05%) for NijmI. 0.02–4.79% (0.08–3.88%) for NijmII. 0.01–5.49% (0.01–4.14%) for Reid93 and 0.01–5.11% (0.01–2.40%) for Argonne v18 potentials.

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