The Gross–Neveu model is a theoretical model in quantum field theory that describes a type of interacting fermionic field. It was initially introduced by David J. Gross and Igor J. R. Neveu in 1974. The model is significant in the study of non-abelian gauge theories and serves as a simpler setting to explore concepts related to quantum field theories, including symmetry breaking and phase transitions.
The Haag–Łopuszański–Sohnius theorem is a result in theoretical physics concerning the structure of supersymmetry. Specifically, it states conditions under which a globally supersymmetric field theory can exist. The theorem is one of the foundational results in the study of supersymmetry, which is a symmetry relating bosons (particles with integer spin) and fermions (particles with half-integer spin).
Hamiltonian truncation is a method used in theoretical physics, particularly in the study of quantum field theories (QFTs) and in the context of many-body physics. It involves simplifying a complicated quantum system by truncating or approximating the Hamiltonian, which is the operator that describes the total energy of the system, including both kinetic and potential energy contributions. ### Key Concepts 1.
Hawking radiation is a theoretical prediction made by physicist Stephen Hawking in 1974. It refers to the radiation that is emitted by black holes due to quantum effects near the event horizon. According to quantum mechanics, empty space is not truly empty but is rather filled with virtual particles that are continually popping in and out of existence. Near the event horizon of a black hole, it is thought that these virtual particle pairs can be separated.
Hegerfeldt's theorem is a result in quantum mechanics that addresses the phenomenon of faster-than-light (FTL) signaling in the context of quantum information and relativistic quantum field theory. The theorem was first presented by Hegerfeldt in a 1998 paper. It demonstrates that certain quantum states evolve in such a way that they can lead to superluminal communication, which contradicts the principles of relativity that prohibit faster-than-light signaling.
Helicity in particle physics refers to the projection of a particle's spin onto its momentum vector. It is a way to characterize the intrinsic angular momentum of a particle relative to its direction of motion.
The Higgs boson is a subatomic particle associated with the Higgs field, which is a fundamental field believed to give mass to other elementary particles through the Higgs mechanism. It was first predicted by physicist Peter Higgs and others in the 1960s as part of the Standard Model of particle physics, which describes the electromagnetic, weak, and strong nuclear interactions.
The history of quantum field theory (QFT) is a rich and complex narrative that spans much of the 20th century and beyond. It involves the development of ideas stemming from both quantum mechanics and special relativity, eventually leading to a theoretical framework that describes how particles and fields interact. Here’s a general overview: ### Early 20th Century Foundations 1.
An **infraparticle** refers to a conceptual particle in theoretical physics that is characterized by an infinite wavelength. This concept arises primarily in the context of quantum field theory (QFT) and is often discussed in relation to particles that have non-trivial mass or momentum distributions. Infraparticles differ from standard particles in several ways: 1. **Infinite Wavelength**: Since infraparticles have infinite wavelength, they cannot be described by the usual relation between energy and momentum.
Infrared divergence refers to a type of divergence that occurs in quantum field theory (QFT) and certain fields of theoretical physics when dealing with low-energy (or long-wavelength) phenomena. Specifically, it manifests when evaluating Feynman integrals or loop diagrams that include virtual particles with very low momenta (approaching zero). In such scenarios, the contributions from these low-energy states can lead to integrals that diverge, meaning they yield infinite values.
Infrared safety in particle physics is a concept that addresses the behavior of certain types of divergences (infinities) that can arise in quantum field theory calculations, particularly in the context of high-energy collisions and the production of particles. In particle collisions, particularly those occurring at high energies, one can encounter divergent contributions from virtual photons (or other massless particles) due to soft emissions—where particles are produced with very low energies.
Initial State Radiation (ISR) and Final State Radiation (FSR) are terms used in particle physics to describe phenomena related to the emission of photons during particle interactions, specifically in high-energy collisions. ### Initial State Radiation (ISR): - **Definition**: ISR refers to the emission of one or more photons by incoming particles before the primary interaction occurs.
Intrinsic parity is a concept in particle physics that refers to a property of particles that characterizes their behavior under spatial inversion (or parity transformation). Parity transformation involves flipping the spatial coordinates, essentially transforming a point in space \((x, y, z)\) to \((-x, -y, -z)\). In terms of intrinsic parity, particles can be classified as having either positive or negative parity. This classification helps in understanding the symmetries and conservation laws of physical processes involving particles.
The kinetic term refers to the part of an equation or expression that represents the kinetic energy of a system. In physics, kinetic energy is the energy that an object possesses due to its motion.
The Kinoshita–Lee–Nauenberg theorem is a result in the field of quantum field theory and particle physics that addresses the issue of how certain types of divergences in amplitudes of scattering processes should be handled when considering the effects of external legs in perturbative calculations. The theorem is particularly relevant in high-energy physics, where particle processes can be complicated due to the presence of many interacting fields.
The Klein transformation, often referred to in the context of the Klein bottle, is a mathematical concept related to topology and geometry, specifically in the study of non-orientable surfaces. The Klein bottle is a famous example of such a surface, which can be described as a two-dimensional manifold that cannot be embedded in three-dimensional Euclidean space without self-intersecting.
The Källén–Lehmann spectral representation is a fundamental concept in quantum field theory, particularly in the context of the study of quantum fields and their propagators. It provides a way to express correlation functions (or Green's functions) of quantum fields in terms of their spectral properties.
The LSZ reduction formula, named after Lüders, Steinweg, and Ziman, is a fundamental result in quantum field theory (QFT) that relates S-matrix elements to time-ordered correlation functions (or Green's functions). It provides a method for calculating the S-matrix (which describes the scattering processes) from the theoretical correlation functions computed in a given quantum field theory.
Light-front quantization is a theoretical framework used in quantum field theory (QFT) that reformulates how particles and fields are quantized. Instead of using the conventional equal-time quantization where fields are defined and treated at equal times (often leading to complications in dealing with relativistic systems), light-front quantization operates in a frame where the "front" of space-time is characterized by light-cone coordinates.
Quantum theory, also known as quantum mechanics, involves a variety of mathematical concepts and structures. Here’s a list of key mathematical topics that are often encountered in the study of quantum mechanics: 1. **Linear Algebra**: - Vector spaces - Inner product spaces - Operators (linear operators on Hilbert spaces) - Eigenvalues and eigenvectors - Matrix representations of operators - Schur decomposition and Jordan forms 2.