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Longer titles found: Strongly interacting massive particle (view), Weakly interacting massive particle (view)

searching for Massive particle 60 found (97 total)

alternate case: massive particle

Bullough–Dodd model (224 words) [view diff] exact match in snippet view article find links to article

Toda field theories. The spectrum of the model consists of a single massive particle. List of integrable models Dodd, R. K.; Bullough, R. K. (4 February

condensate due to a pool of instantons. The photon in this model becomes a massive particle at low temperatures. This model can be solved exactly and is used as

particles that decay into two on-shell photons. The theorem states that a massive particle with spin 1 cannot decay into two photons. A photon here is any particle

^{4}} is Euclidean 4-space; the mass gap Δ is the mass of the least massive particle predicted by the theory. Therefore, the winner must prove that: Yang–Mills

expectation value of the force F = − V ′ ( x ) {\displaystyle F=-V'(x)} on a massive particle moving in a scalar potential V ( x ) {\displaystyle V(x)} , m d d t

respect to proper time τ {\displaystyle \scriptstyle \tau } . For a massive particle, the components of the four-velocity satisfy the following equation:

discrete values, the eigenvalues of helicity are also discrete. For a massive particle of spin S, the eigenvalues of helicity are S, S − 1, S − 2, ..., −S

the photon, related by speed of light constant. This contrasts with a massive particle of which the energy depends on its velocity and rest mass. Legend

comprises the matter. The de Broglie wavelength associated with a massive particle is λ = h p {\displaystyle \lambda ={\frac {h}{p}}} where h is the Planck

allows the derivation of the Compton frequency f for a stationary massive particle, equal to mc2/h. De Broglie also proposed that the wavelength λ for

before the length is calculated). The relativistic energy of a single massive particle contains a term related to its rest mass in addition to its kinetic

inequality using superpositions of positions instead of spin with a massive particle. At that time, and so far up until today, the Cesium atoms employed

ensemble of classical systems in phase space (top). The systems are a massive particle in a one-dimensional potential well (red curve, lower figure). The

two of the simplest include: From the relativistic dynamics of a massive particle, By evaluating the norm of the four-momentum of the system. This method

can be described as an exchange force transmitted by a yet unknown massive particle, this idea was later developed by Hideki Yukawa into a theory of meson

the constant being finite. A typical example is offered by a free massive particle and, in this case, the constant has the value 1/m2. In the same limit

work on correctly identifying the pointer states in the case of a massive particle decohered by collisions with a fluid environment, often known as collisional

take two paths, but the property of the particle, like the spin of a massive particle or the polarization of a light beam, travels only through one of the

any two four-momenta p and q, the quantity p ⋅ q is invariant. For a massive particle, the four-momentum is given by the particle's invariant mass m multiplied

Dirac sea for a massive particle.  •  particles,  •  antiparticles

space occupied by the mass distribution m = mr is the mass moment of a massive particle τ = ∫ V n d m × g {\displaystyle {\boldsymbol {\tau }}=\int _{V_{n}}\mathrm

coupling, meaning that the Higgs boson will couple most to the most massive particle. This means that the most significant corrections to the Higgs mass

that a massive particle would exist and calculated some of its properties;: 167  he was therefore "the first to postulate the existence of a massive particle"

equivalency equation to be of paramount importance because it showed that a massive particle possesses an energy, the "rest energy", distinct from its classical

classical systems in phase space (top). Each system consists of one massive particle in a one-dimensional potential well (red curve, lower figure). Whereas

Zhi-Peng (2004). "Projection Operator and Feynman Propagator for a Free Massive Particle of Arbitrary Spin". Communications in Theoretical Physics. 41 (3):

than 5 MeV. The team was eventually convinced they had observed a massive particle and named it "J". Ting considered announcing his discovery in October

integer (0, 1, 2 ...) or a half-integer (1/2, 3/2, 5/2 ...). For a massive particle with spin S, its spin quantum number m always assumes one of the 2S

University of California Press. ISBN 978-0-520-06426-3. David Kestenbaum, Massive Particle Accelerator Revving Up NPR's Morning Edition article on 9 April 2007

massive, it must interact with itself. Because the Higgs boson is a very massive particle and also decays almost immediately when created, only a very high-energy

classical systems in phase space (top). Each system consists of one massive particle in a one-dimensional potential well (red curve, lower figure). The

transformations have important implications: The relativistic momentum of a massive particle would increase with speed in such a way that at the speed of light

Evolution of a world line of an accelerated massive particle. This world line is restricted to the timelike top and bottom sections of this spacetime figure;

S2CID 2027732. J. Bros; H. Epstein; U. Moschella (2008). "Lifetime of a massive particle in a de Sitter universe". Transactions of the American Fisheries Society

Hooper". IMDB. Internet Movie Database. Retrieved March 9, 2018. "Massive Particle Accelerator Is Ready To Go". NPR WBEZ. National Public Radio. August

thought to be stable on theoretical grounds: the electron is the least massive particle with non-zero electric charge, so its decay would violate charge conservation

analogous to gross mass-conservation in chemistry). For example, a massive particle can decay into photons which individually have no mass, but which (as

matrices. Also, the solutions to a relativistic wave equation, for a massive particle of spin s, are complex-valued 2(2s + 1)-component spinor fields. As

classical systems in phase space (top). Each system consists of one massive particle in a one-dimensional potential well (red curve, lower figure). The

produced in weak interactions as chirality eigenstates. Chirality of a massive particle is not a constant of motion; helicity is, but the chirality operator

from irreducible spinors A and B, symmetric in all indices, for a massive particle of spin n + ½ for integer n (see Van der Waerden notation for the meaning

{\sqrt {n!}}}|n\rangle } In the picture where the coherent state is a massive particle in a quantum harmonic oscillator, the position and momentum operators

}\right)\,d^{3}x={\frac {e}{E}}\int {\mathbf {S} }\,d^{3}x~.} For a single massive particle in its rest frame, where E = m {\displaystyle E=m} , the magnetic moment

have not yet gained mass through the Higgs mechanism. However exotic massive particle-like entities, sphalerons, are thought to have existed. This epoch

have mass, and since chirality can change during the propagation of a massive particle, right-handed neutrinos must exist in reality. This does not however

used to "reverse-engineer" the Lagrangian. For the case of the free massive particle, in Cartesian coordinates, the x component of relativistic momentum

is the curvature vector of the world line in Minkowski space. For a massive particle of rest mass (or invariant mass) m0, the four-momentum is given by:

time-independent Schrödinger equation for a stationary state of a massive particle with energy E > V 0 {\displaystyle E>V_{0}} is solved: − ℏ 2 2 m d

the homogeneous space SO+(1, 3) / SO(3) is the momentum space of a massive particle; geometrically, this space is none other than three-dimensional hyperbolic

results, which were released in August 2015, verify the experiment's massive particle detector is detecting neutrinos fired from 800 kilometers away and

the finite phase space of the point vortex system: in contrast to a massive particle moving on a plane, each point vortex only has two degrees of freedom

spacetime physics and its applications in relativistic dynamics of a massive particle and gyroscopic precession", Scientific Reports, 12 (1): 3981, arXiv:2111

Frandsen & Francesco Sannino (2010). "Isotriplet technicolor interacting massive particle as dark matter". Physical Review D. 81 (9): 097704. arXiv:0911.1570

equivalency equation to be of paramount importance because it showed that a massive particle possesses an energy, the "rest energy", distinct from its classical

Big Science has since been associated with physics, which requires massive particle accelerators. In biology, Big Science debuted in 1990 with the Human

Corner joins the UN forces in a large, golden mobile armor and fires a massive particle cannon at the Ptolemaios, Setsuna and Lasse attack Alejandro, but could

William Herschel Telescope WIMP – (celestial object) Weakly Interacting Massive Particle, a hypothetical subatomic particle that may comprise most of the dark

mv_{\rm {D}}^{2}} , not the rest mass m c 2 {\displaystyle mc^{2}} of a massive particle. γ μ {\displaystyle \gamma ^{\mu }} refers to a set of Dirac matrices

trimuon events, the interaction seemed to require the presence of a new massive particle. The theorized particle, which was expected to have a previously unobserved

then arrives and manages to destroy the Sadogashima Hive with two massive particle beam shots, proving that humanity now has a superweapon against the