**Static Forces:** Static forces refer to the forces that act on objects at rest or in equilibrium. In physics, when we analyze static forces, we generally consider the forces that are not changing with time and that keep an object in a stable state. Examples include gravitational forces, normal forces, frictional forces, and tension forces. In classical mechanics, static forces can be represented using vector diagrams where the net force acting on an object is zero.
Stochastic Electrodynamics (SED) is a theoretical framework that seeks to explain certain quantum phenomena using classical electromagnetic fields and random fluctuations. Unlike conventional quantum mechanics, which typically describes particles and fields using wave functions and probabilities, SED attempts to derive quantum effects from the properties of classical fields influenced by stochastic (random) processes.
In quantum field theory (QFT), "sum rules" refer to relationships or constraints that arise from the principles of quantum mechanics, symmetries of the system, and the structure of the underlying quantum fields. These rules serve to relate various physical quantities and often provide important insights into the properties of particles and interactions. A few important types of sum rules in quantum field theory include: 1. **Sum Rules from Current Algebra**: These arise from the conservation of certain currents in the theory.
Superselection refers to a concept in quantum mechanics that deals with the restrictions on the allowed states of a quantum system based on certain conservation laws or symmetries. Specifically, it distinguishes between different sectors or subspaces of a Hilbert space that cannot be coherently superposed, meaning that states from different superselection sectors cannot be combined into a single quantum state.
In quantum mechanics, symmetry refers to the invariance of a physical system under certain transformations. These transformations can include spatial translations, rotations, or changes in time, and they often correspond to conservation laws due to Noether's theorem.
In physics, a "tadpole" typically refers to a specific kind of diagram used in quantum field theory, especially in the context of perturbation theory in quantum electrodynamics and other quantum field theories. The term is most often associated with Feynman diagrams. In this context, a tadpole diagram represents a one-point function or a loop diagram that has one external vertex and a loop.
The quantum vacuum, often referred to simply as the "vacuum" in the context of quantum field theory, is a fundamental concept in modern physics. Contrary to the classical notion of a vacuum as an empty space devoid of matter, the quantum vacuum is a dynamic state filled with fluctuating energy and virtual particles that constantly pop in and out of existence.
The Thirring model is a theoretical model in quantum field theory that describes a system of relativistic fermions interacting with each other through four-fermion contact interactions. It was introduced by Walter Thirring in the 1950s and serves as an important example in the study of non-abelian quantum field theories and the behavior of fermions in a relativistic framework.
The Thirring-Wess model is a theoretical framework used in quantum field theory that describes the dynamics of fermionic fields. It is primarily a two-dimensional model that provides insights into the behavior of quantum fields with interactions. The model is notable because it exhibits non-trivial interactions between fermions and can lead to rich phenomena such as spontaneous symmetry breaking and the emergence of various phases. The model is characterized by its Lagrangian density, which typically includes terms for free fermions and interaction terms.
Toda field theory refers to a class of integrable models that arise in the study of two-dimensional field theories and statistical mechanics. The most commonly discussed model in this context is the Toda lattice, which is related to the integrable systems known as the Toda chain. ### Key Features of Toda Field Theory: 1. **Integrability**: Toda field theories are integrable systems, which means they possess a large number of conserved quantities and can be solved exactly.
Topological Yang–Mills theory is a variant of Yang–Mills theory that emphasizes topological rather than local geometric properties. In traditional Yang–Mills theory, the focus is on gauge fields and their dynamics, which are described using the local geometric structure of a manifold. However, topological Yang–Mills theory studies the global properties of the gauge fields and their configurations.
Topological Quantum Field Theory (TQFT) is a branch of theoretical physics and mathematics that explores the relationships between quantum field theory and topology, a branch of mathematics that studies properties of space that are preserved under continuous transformations. ### Key Concepts of TQFT: 1. **Quantum Field Theory (QFT)**: - QFT is a framework for constructing quantum mechanical models of subatomic particles in particle physics. It combines classical field theory, special relativity, and quantum mechanics.
Topological quantum numbers are integer values that arise in the context of topological phases of matter and quantum field theories, particularly in condensed matter physics. They characterize different phases of a system based on their global properties rather than local properties, which can be crucial for understanding phenomena that are stable against local perturbations. A few key points about topological quantum numbers are: 1. **Robustness**: Topological quantum numbers are robust against small perturbations or changes in the system.
Transactional Interpretation (TI) is an interpretation of quantum mechanics proposed by physicists John G. Cramer in the 1980s. It is designed to address some of the conceptual problems related to the standard Copenhagen interpretation, particularly the role of the observer and the nature of wave function collapse. The central idea of the Transactional Interpretation is that quantum events involve a "handshake" between waves traveling forward in time and those traveling backward in time.
Twistor theory is a mathematical framework developed by the British mathematician Roger Penrose in the 1960s. It is designed to provide a new perspective on the geometry of space-time and the fundamental structures of physical theories, particularly in the context of general relativity and quantum gravity. At its core, twistor theory transforms the conventional approach to understanding space-time by introducing a new set of mathematical objects called "twistors.
The Uehling potential, named after the physicist Eugene Uehling, is an important concept in quantum mechanics and field theory, particularly in the context of quantum electrodynamics (QED). It refers to a potential energy associated with the interaction between charged particles due to vacuum polarization effects. Vacuum polarization is a phenomenon where a vacuum behaves like a medium due to the temporary creation of virtual particle-antiparticle pairs.
Ultraviolet (UV) completion refers to a theoretical framework within particle physics that addresses the behavior of a quantum field theory at very high energy scales. In many quantum field theories (QFTs) or models, the interactions and particles exhibit divergences or inconsistencies when energy scales approach very high values, typically on the order of the Planck scale (\(10^{19}\) GeV) or at energies significantly higher than those probed by current experiments.
Ultraviolet (UV) divergence is a concept in quantum field theory and quantum mechanics that refers to the phenomenon where certain integrals, especially those that arise in the calculation of particle interactions and vacuum fluctuations, yield infinite results when evaluated at high energy (or short distance) scales. This is particularly relevant in theories like quantum electrodynamics (QED) and quantum chromodynamics (QCD), where loop diagrams (representing virtual particles) can produce divergences.
The Unruh effect is a prediction in quantum field theory that suggests an observer accelerating through a vacuum will perceive that vacuum as a warm bath of particles, or thermal radiation, while an inertial observer would see no particles at all. This phenomenon was first proposed by physicist William Unruh in 1976.
Vacuum energy refers to the underlying energy present in empty space, or "vacuum." In quantum field theory, even in a perfect vacuum devoid of matter, there are still fluctuations due to the Heisenberg uncertainty principle. These oscillations happen because pairs of virtual particles can spontaneously form and annihilate within very short time periods.