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In physics, solution to Schrödinger equation
In mathematics, a Coulomb wave function is a solution of the Coulomb wave equation, named after Charles-Augustin de Coulomb. They are used to describe
Coulomb_wave_function
Solution of a confluent hypergeometric equation
functions are solutions to the Coulomb wave equation. The Kummer functions, Whittaker functions, and Coulomb wave functions are essentially the same, and
Confluent hypergeometric function
Confluent_hypergeometric_function
state Coulomb stress transfer Coulomb wave function A coulomb wave function is a solution to the coulomb wave equation Coulomb, a lunar crater Coulomb-Sarton
List of things named after Charles-Augustin de Coulomb
List_of_things_named_after_Charles-Augustin_de_Coulomb
American mathematician (1915–1958)
relation. In 1954, Abramowitz and H. A. Antosiewicz studied the Coulomb wave functions in the form d 2 y / d ρ + ( 1 − 2 η ρ + L ( L + 1 ) ρ 2 ) y = 0
Milton_Abramowitz
Fundamental physical law of electromagnetism
Coulomb's inverse-square law, or simply Coulomb's law, is a scientific law of physics that describes the amount of force between two electrically charged
Coulomb's_law
Technique in quantum mechanics for solving scattering problems
assumed. This means that the stationary Schrödinger equation for the wave function Ψ ( r ) {\displaystyle \Psi (\mathbf {r} )} representing the particle
Partial-wave_analysis
Short "burst" or "envelope" of restricted wave action that travels as a unit
Each component wave function, and hence the wave packet, are solutions of a wave equation. Depending on the wave equation, the wave packet's profile
Wave_packet
This is a list of wave topics. Contents: Top 0–9 A B C D E F G H I J K L M N O P Q R S T U V W X Y Z
Index_of_wave_articles
Description of a quantum-mechanical system
Schrödinger equation is a partial differential equation that governs the wave function of a non-relativistic quantum-mechanical system. Its discovery was a
Schrödinger_equation
Procedure of coping with redundant degrees of freedom in physical field theories
gauge function is said to be gauge invariant: All physical observables are required to be gauge invariant. A gauge transformation from the Coulomb gauge
Gauge_fixing
Physical interaction of charged particles
Coulomb scattering is the elastic scattering of charged particles by the Coulomb interaction. The physical phenomenon was used by Ernest Rutherford in
Coulomb_scattering
American mathematician (1919–2008)
of Research of the National Bureau of Standards. "Generation of Coulomb Wave Functions by Means of Recurrence Relations" (1955, with Milton Abramowitz)
Irene_Stegun
Multivalued function in mathematics
function appears in a quantum-mechanical potential, which affords the fifth – next to those of the harmonic oscillator plus centrifugal, the Coulomb plus
Lambert_W_function
Interpretation of quantum mechanics
interpretation of quantum mechanics that postulates that, in addition to the wave function, a particle possesses a definite position at all times, even when unobserved
De_Broglie–Bohm_theory
Physical model of propagating energy
electromagnetic radiation (EMR) or an electromagnetic wave (EMW) is a self-propagating wave of the electromagnetic field that carries momentum and radiant
Electromagnetic_radiation
Elementary particle or quantum of light
waves and gravitons), but it would not be the speed of photons. If a photon did have non-zero mass, there would be other effects as well. Coulomb's law
Photon
Screened Coulomb potential which exponentially decays
and condensed matter physics, a Yukawa potential (also called a screened Coulomb potential[citation needed]) is a potential named after the Japanese physicist
Yukawa_potential
degenerate. The corresponding wave functions of scattering states in the Coulomb potential field are the Coulomb wave function. The mathematical treatment
Coulomb_scattering_state
Line integral of the electric field
(measured in joules) divided by the charge of that particle (measured in coulombs). By dividing out the charge on the particle a quotient is obtained that
Electric_potential
Approximation method in quantum physics
chemistry, the Hartree–Fock (HF) method is used for approximating the wave function and the energy of a quantum many-body system in a stationary state.
Hartree–Fock_method
Damping of electric fields
each pair of particles (with charges q1 and q2) interact through the Coulomb force as F = q 1 q 2 4 π ε | r | 2 r ^ , {\displaystyle \mathbf {F} ={\frac
Electric-field_screening
Quantum mechanical effect
exchange interaction. The wave function of indistinguishable particles is subject to exchange symmetry: the wave function either changes sign (for fermions)
Exchange_interaction
Approximation in many-body systems
the self-energy Σ in terms of the single particle Green's function G and the screened Coulomb interaction W Σ = i G W − G W G W G + ⋯ {\displaystyle \Sigma
GW_approximation
calculate the Coulomb energy of a configuration of charged particles in the following way. First, calculate the charge density ρ, where ρ is a function of the
Lieb–Oxford_inequality
Relativistic wave equation in quantum mechanics
perfect point-like Coulomb potentials. Another notable solution to the Klein–Gordon equation is the scattering of an initial plane-wave off an potential
Klein–Gordon_equation
Function that can be used to build the wave function of a multi-fermionic system
mechanics, a Slater determinant is an expression that describes the wave function of a multi-fermionic system. It satisfies anti-symmetry requirements
Slater_determinant
Quantum theory of interacting electron gas
}-|\mathbf {k} |)} is a Heaviside step function, where k F {\displaystyle k_{\mathbf {F} }} is the Fermi wave vector associated to the Fermi energy E
Lindhard_theory
Description of physical properties at the atomic and subatomic scale
mathematical formalisms. In one of them, a mathematical entity called the wave function provides information, in the form of probability amplitudes, about what
Quantum_mechanics
Elementary particle with negative charge
within atomic nuclei and the negative electrons without, held together by Coulomb force interaction. Ionization state (differences in the proportions of
Electron
Details in the emission spectrum of an atom
^{0}\right\rangle } where ψ 0 {\displaystyle \psi ^{0}} is the unperturbed wave function. Recalling the unperturbed Hamiltonian, we see H 0 | ψ 0 ⟩ = E n | ψ
Fine_structure
Chance of overcoming the Coulomb barrier
probability factor for two nuclear particles' chance of overcoming the Coulomb barrier in order to undergo nuclear reactions, for example in nuclear fusion
Gamow_factor
Physical interaction in post-classical physics
attractive, which is the opposite of the Coulomb interaction. In a plasma, the dispersion relation for an electromagnetic wave is ( c = 1 {\displaystyle c=1} )
Static forces and virtual-particle exchange
Static_forces_and_virtual-particle_exchange
1964 mathematical reference work edited by M. Abramowitz and I. Stegun
Confluent Hypergeometric Functions Coulomb Wave Functions Hypergeometric Functions Jacobian Elliptic Functions and Theta Functions Elliptic Integrals Weierstrass
Abramowitz_and_Stegun
Number assigned to each electron shell in an atom
and unique quantum state of a single electron in an atom, called its wave function or orbital. Two electrons belonging to the same atom cannot have the
Principal_quantum_number
Rapid oscillations of electron density
electron or a group of electrons slightly with respect to the ions, the Coulomb force pulls the electrons back, acting as a restoring force. If the thermal
Plasma_oscillation
Ansatz in condensed matter physics
Physics in 1998 for this discovery. If we ignore the jellium and mutual Coulomb repulsion between the electrons as a zeroth order approximation, we have
Laughlin_wavefunction
Quantum field of electrons
e., to form periodic "bumps" in charge. This standing wave affects each electronic wave function, and is created by combining electron states, or wavefunctions
Charge_density_wave
Electromagnetic property of matter
SI derived unit of electric charge is the coulomb (C) named after French physicist Charles-Augustin de Coulomb. In electrical engineering it is also common
Electric_charge
Scattering theory
amplitude, f {\displaystyle f} requires knowing the full scattering wave function ψ {\displaystyle \psi } , f ( k f , k i ) = − μ 2 π ℏ 2 ∫ ψ f ∗ V (
Born_approximation
Nonlinear modification of the Schrödinger equation
where the gravitational potential emerges from the treatment of the wave function as a mass density, including a term that represents interaction of a
Schrödinger–Newton_equation
Solid state physics calculation technique
as the nuclear coulomb potential can now be substituted with a smoother one. Rostgaard, Carsten (2010). "The Projector Augmented-wave Method". arXiv:0910
Projector augmented wave method
Projector_augmented_wave_method
Quantum mechanical phenomenon
the wave nature of matter and quantum indeterminacy. The quantum wave function describes the states of a particle or other physical system and wave equations
Quantum_tunnelling
Equation in solid state physics
1002/sapm192434191. ISSN 0097-1421. Hartree, D. R. (1928). "The Wave Mechanics of an Atom with a Non-Coulomb Central Field. Part I. Theory and Methods". Mathematical
Hartree_equations
Hamiltonian operator for molecules
in terms of some analytic functions. In the second step of the Born–Oppenheimer approximation the part of the full Coulomb Hamiltonian that depends on
Molecular_Hamiltonian
Quasiparticle which is a bound state of an electron and an electron hole
an electron hole which are attracted to each other by the electrostatic Coulomb force resulting from their opposite charges. It is an electrically neutral
Exciton
is a confluent hypergeometric function. For an application of this integral see Charge density spread over a wave function. Relation between Schrödinger's
Common integrals in quantum field theory
Common_integrals_in_quantum_field_theory
Type of wave in plasma
{\displaystyle F_{Au}=12.69(1-f_{B})/{\bar {Z}}} . Ion acoustic waves are damped both by Coulomb collisions and collisionless Landau damping. The Landau damping
Ion_acoustic_wave
Gauge fixing of electro magnetic potential
Maxwell. Maxwell had eliminated the Coulomb electrostatic force from his derivation of the electromagnetic wave equation since he was working in what
Lorenz_gauge_condition
Quantum mechanical property
spatial wave function, and specified by three variables (as with x, y, and z Cartesian coordinates). The square of an electron's wave function at a given
Orbital_motion_(quantum)
analytic ("exact") solution in closed form, described with the Coulomb wave function. The addition of a third particle Helium atom still admits analytic
Vladimir_Krivchenkov
Mechanism of electrical conduction in disordered materials
{W}{kT}}\right]} where α−1 is the attenuation length for a hydrogen-like localised wave-function. This assumes that hopping to a state with a higher energy is the rate
Variable-range_hopping
Mathematical formalism used in quantum field theory
the theory of matter. Bohm and Pines' RPA accounts for the weak screened Coulomb interaction and is commonly used for describing the dynamic linear electronic
Random_phase_approximation
Equation in physics
side is the vector Laplacian, not Laplacian applied on scalar functions.) gives the wave equation for the electric field E: 1 c 2 ∂ 2 E ∂ t 2 − ∇ 2 E =
Inhomogeneous electromagnetic wave equation
Inhomogeneous_electromagnetic_wave_equation
The square of the wave function is the probability of a particle's location at any given moment. Direct imaging of a wave function used to be considered
Quantum_microscopy
Physical field surrounding an electric charge
point charge q 1 {\displaystyle q_{1}} ; it is a vector-valued function equal to the Coulomb force per unit charge that a positive point charge would experience
Electric_field
Atom of the element hydrogen
radial dependence of the wave functions must be found. It is only here that the details of the 1 / r {\displaystyle 1/r} Coulomb potential enter (leading
Hydrogen_atom
Flow of electric charge
ampere (sometimes called an "amp", symbol A), which is equivalent to one coulomb per second. The ampere is an SI base unit and electric current is a base
Electric_current
Reaction that combines atomic nuclei
so-called Coulomb barrier. The kinetic energy to achieve this can be lower than the barrier itself because of quantum tunneling. The Coulomb barrier is
Nuclear_fusion
Relativistic wave equation derived by Gregory Breit in 1929
The Breit equation, or Dirac–Coulomb–Breit equation, is a relativistic wave equation derived by Gregory Breit in 1929 based on the Dirac equation, which
Breit_equation
Function used in quantum chemistry
Slater-type orbitals (STOs) or Slater-type functions (STFs) are functions used as atomic orbitals in the linear combination of atomic orbitals molecular
Slater-type_orbital
Fifteen problems in mathematical physic
Schrödinger operators, and five concern operators that incorporate the Coulomb potential. In 2014, Artur Avila won a Fields Medal for work including the
Simon_problems
Deviation of electrons from their original trajectories
force). Electrostatic Coulomb force also known as Coulomb interaction and electrostatic force, named for Charles-Augustin de Coulomb who published the result
Electron_scattering
Process by which atoms or molecules acquire charge by gaining or losing electrons
and numerous options exist e.g. B-splines, generalized Sturmians or Coulomb wave packets. Another non-perturbative method is to solve the corresponding
Ionization
Absence of diffusion waves in disordered media
to a strong mutual Coulomb repulsion of electrons. In the original Anderson tight-binding model, the evolution of the wave function ψ on the d-dimensional
Anderson_localization
Phenomena related to electric charge
electric current and produces a magnetic field. In most applications, Coulomb's law determines the force acting on an electrically charged particle. Electric
Electricity
Branch of theoretical physics
from this definition, though, is that the unit of E is N/C (newtons per coulomb). This unit is equal to V/m (volts per meter); see below. In electrostatics
Classical_electromagnetism
Measure of the electric polarizability of a dielectric material
electric constant) is the ratio D/E in free space. It also appears in the Coulomb force constant, k e = 1 4 π ε 0 {\displaystyle k_{\text{e}}={\frac
Permittivity
Model of electrically conducting fluids
Electromagnetic–Hydrodynamic Waves", which outlined his discovery of what are now known as Alfvén waves. Alfvén initially referred to these waves as "electromagnetic–hydrodynamic
Magnetohydrodynamics
Process of calculating the causal factors that produced a set of observations
mathematical model is available (for instance, Newton's gravitational law or Coulomb's equation for electrostatics), we can foresee, given some parameters that
Inverse_problem
Type of electric dipole moment
within the system. The SI unit of the transition dipole moment is the Coulomb-meter (Cm); a more conveniently sized unit is the Debye (D). For a transition
Transition_dipole_moment
Quantum-mechanical vector property in solid-state physics
single particle wave function ψ ( x ) {\displaystyle \psi (\mathbf {x} )} , finds its stationary state solutions in the form of a plane wave multiplied by
Crystal_momentum
Electric and magnetic fields produced by moving charged objects
an oscillation that propagates through space, known as an electromagnetic wave. Mathematically, the electromagnetic field is a pair of vector fields consisting
Electromagnetic_field
Random matrix with gaussian entries
Z β , N {\displaystyle \ln Z_{\beta ,N}} , termed the Coulomb gas free energy. The Coulomb gas free energy is minimized by the Wigner semicircle law
Gaussian_ensemble
Physical model of solid metals as electron gases
introducing a periodic potential into the Schrödinger equation results in a wave function of the form ψ k ( r ) = u k ( r ) e i k ⋅ r {\displaystyle \psi _{\mathbf
Nearly_free_electron_model
Polynomial sequence
spring. This is also called the electrostatic model, and relates to the Coulomb gas interpretation of the eigenvalues of gaussian ensembles. As the zeroes
Hermite_polynomials
Solvable quantum mechanics potential
E_{3}} Laplacian. Due to this analogy, the cotangent function is frequently termed to as "curved Coulomb" potential. Such an interpretation ascribes the cotangent
Trigonometric Rosen–Morse potential
Trigonometric_Rosen–Morse_potential
Measure of positive and negative charges
system's overall polarity. The SI unit for electric dipole moment is the coulomb-metre (C⋅m). The debye (D) is a CGS unit of measurement used in atomic
Electric_dipole_moment
Describe the optical response of semiconductors
k {\displaystyle V_{\mathbf {k} }} is the Coulomb matrix element, given here in terms of the carrier wave vector k {\displaystyle \mathbf {k} } . The
Semiconductor_Bloch_equations
Force that acts between the protons and neutrons of atoms
than the repulsive Coulomb force between protons; it thus overcomes the repulsion of protons within the nucleus. However, the Coulomb force between protons
Nuclear_force
Fundamental interaction between charged particles
units related to electromagnetism: ampere (electric current, SI unit) coulomb (electric charge) farad (capacitance) henry (inductance) ohm (resistance)
Electromagnetism
Interaction between electrons, often complicating physical calculations
quantum chemistry, the antisymmetric wave function is approximated by a single Slater determinant. Exact wave functions, however, cannot generally be expressed
Electronic_correlation
Concept in quantum mechanics
for proton-proton scattering, is the Coulomb-modified scattering length. As an example on how to compute the s-wave (i.e. angular momentum l = 0 {\displaystyle
Scattering_length
Electromagnetic effect in physics
can be chosen to be the product of a plane wave in y {\displaystyle y} -direction with some unknown function of x {\displaystyle x} , i.e., ψ x y = u (
Quantum_Hall_effect
Type of nuclear fusion that occurs at high densities & low temperatures
quantum physics, the phenomenon can be interpreted as overlap of the wave functions of neighboring ions, and is proportional to the overlapping amplitude
Pycnonuclear_fusion
Optical filter
solution. The band diagram is essentially a plot of k as a function of k0. The Bloch wave expansions in equations (1.2.1) are nothing more than exponential
Frequency_selective_surface
Molecular ion
^{2}+V\right)\psi =E\psi ~,} where V is the electron-nuclear Coulomb potential energy function: V = − e 2 4 π ε 0 ( 1 r a + 1 r b ) {\displaystyle V=-{\frac
Dihydrogen_cation
Energy held by an object because of its position relative to other objects
gravitational force is called gravitational potential energy; work of the Coulomb force is called electric potential energy; work of the nuclear force acting
Potential_energy
Quantum operator for the sum of energies of a system
which allows one to apply the Hamiltonian to systems described by a wave function Ψ ( r , t ) {\displaystyle \Psi (\mathbf {r} ,t)} . This is the approach
Hamiltonian (quantum mechanics)
Hamiltonian_(quantum_mechanics)
Change in optical absorption by a semiconductor when an electric field is applied
the electron and hole wavefunctions become Airy functions rather than plane waves. The Airy function includes a "tail" which extends into the classically
Franz–Keldysh_effect
Range of physical processes in physics
diffraction Brillouin scattering Characteristic mode analysis Compton scattering Coulomb scattering Deep scattering layer Diffuse sky radiation Doppler effect Dynamic
Scattering
changes in time. The wave itself is described by a mathematical function known as a "wave function". Schrödinger said that the wave function provides the "means
History_of_quantum_mechanics
Quantum-mechanical framework for simulating molecules and solids
computational foundations are analogous – to show that the (time-dependent) wave function is equivalent to the (time-dependent) electronic density, and then to
Time-dependent density functional theory
Time-dependent_density_functional_theory
Molecule investigation technique
i.e., electronic vacancies, in valence band attract each other via the Coulomb interaction. Under suitable conditions, electrons and holes can be bound
Terahertz_spectroscopy
Assumption that motions of nuclei and electrons can be separated
the Born–Oppenheimer (BO) approximation is the assumption that the wave functions of atomic nuclei and electrons in a molecule can be treated separately
Born–Oppenheimer approximation
Born–Oppenheimer_approximation
Probability density of electrons being somewhere
{\displaystyle N} spin coordinates). Conversely, the density determines the wave function modulo up to a phase factor, providing the formal foundation of density
Electron_density
Model of electronic band structures of solids
electronic band structure using an approximate set of wave functions based upon superposition of wave functions for isolated atoms located at each atomic site
Tight_binding
Mathematical model of how solid objects deform
(later Lord Kelvin) in 1848 (Thomson 1848). This solution is the analog of Coulomb's law in electrostatics. A derivation is given in Landau & Lifshitz. Defining
Linear_elasticity
\phi } electric potential volt (V) Higgs field work function Ψ {\displaystyle \Psi } psi wave function m−3/2 Ω {\displaystyle \Omega } omega electric resistance
List of common physics notations
List_of_common_physics_notations
Atom of helium
value, but if a better trial wave function is used, an even more accurate answer could be obtained. An ideal wave function would be one that doesn't ignore
Helium_atom
Shielding an object from view using materials made to redirect light
radiation. Objects in the defined location are still present, but incident waves are guided around them without being affected by the object itself. Electromagnetic
Metamaterial_cloaking
COULOMB WAVE-FUNCTION
COULOMB WAVE-FUNCTION
Female
French
French unisex form of Latin Columba, COLOMBE means "dove."
Surname or Lastname
English
English : from a Germanic personal name Walo, either a byname meaning ‘foreigner’ (see Wallace), or else a short form of the various compound names with this first element.English : nickname for a well-liked person, from Middle English wale ‘good’, ‘excellent’ (originally meaning ‘choice’).English : topographic name for someone who lived near an embankment, Middle English wale (Old English walu).
Surname or Lastname
English
English : from the Middle English personal name Wade, Old English Wada, from wadan ‘to go’. (Wada was the name of a legendary sea-giant.)English : topographic name for someone who lived near a ford, Old English (ge)wæd (of cognate origin to 1), or a habitational name from a place named with this word, as for example Wade in Suffolk.Dutch and North German : occupational name or nickname from Middle Dutch, Middle Low German wade ‘garment’, ‘large net’.Jonathan Wade emigrated from Norfolk, England, to Medford, MA, in 1632. Benjamin Franklin Wade (1800–1878), born near Springfield, MA, was a prominent U.S. senator from OH during the Civil War.
Boy/Male
Anglo Saxon American English Scandinavian
Moving.
Surname or Lastname
English (of Norman origin) and northern French
English (of Norman origin) and northern French : nickname for a bald man, from Anglo-Norman French cauf ‘bald’. Compare Chaffee.English : habitational name from a place in East Yorkshire called Cave, apparently from a river name derived from Old English cÄf ‘swift’.French : metonymic occupational name for someone employed in or in charge of the wine cellars of a great house, from Old French cave ‘cave’, ‘cellar’ (Latin cavea, a derivative of cavus ‘hollow’).French, possibly also English : topographic name for someone who lived in or near a cave, from the same word as in 3 in an older sense.
Boy/Male
Anglo Saxon English
Wise.
Boy/Male
Anglo, British, English, Jamaican
Wise; Watchful; Aware; Watchman; Careful
Surname or Lastname
English
English : topographic name for someone who lived by a dam or weir on a river (Old English wær, wer), or a habitational name from a place named with this word, such as Ware in Hertfordshire.English : nickname for a cautious person, from Middle English war(e) ‘wary’, ‘prudent’ (Old English (ge)wær).English : Robert Ware came to Dedham, MA, from England in or before 1642. Henry Ware (1764–1845), born in Sherborn, MA, was a Unitarian clergyman and theologian and father of the physician John Ware (b. 1795) and two clergymen, Henry (b. 1794) and William (b. 1797).
Female
Irish
Variant spelling of Irish Maeve, MAVE means "intoxicating."Â
Male
Scottish
Scottish form of Latin Columba, COLUMB means "dove."
Male
Italian
Italian form of Latin Columba, COLOMBO means "dove."
Boy/Male
Hebrew American Scottish Welsh
Cherished; Beloved.
Boy/Male
English
Alert.
Male
English
 English topographical surname transferred to forename use, WADE means "lives near the river crossing." Middle English form of Anglo-Saxon Wada (the name of a sea giant), meaning "to go," in the sense of going forward, proceeding.
Girl/Female
Irish
Joy.
Male
English
English short form of Hebrew David, DAVE means "beloved."
Surname or Lastname
English
English : variant spelling of Way.
Surname or Lastname
English
English : occupational name for a servant, from Middle English knave ‘boy’, ‘youth’, ‘servant’.English : possibly a metonymic occupational name for a maker of wheel-hubs, Middle English nave (from Old English nafa, nafu).German (also Näve) : variant of Neff (see Neve).Dutch (de Nave) : variant of Naef 1.In some cases possibly Portuguese : topographic name from nave ‘plain’ (a variant of nava), or a habitational name from a place named with this word. Compare Nava.
Girl/Female
Slavic
Stranger. Pet name formed from Varvara; the Russian form of Barbara.
Boy/Male
Hindu
Variant of David beloved
COULOMB WAVE-FUNCTION
COULOMB WAVE-FUNCTION
Girl/Female
Hindu, Indian
Full of Spiritual Power
Female
Greek
(ΞÎνη) Feminine form of Greek Xenon, XENE means "foreigner; stranger."
Female
Hungarian
Feminine form of Hungarian Károly, KAROLA means "man."
Girl/Female
Australian, British, English
Variant of Maidi
Boy/Male
Greek American English Shakespearean
Watchful. Famous bearer: American actor Gregory Peck, and Pope Gregory I who was also known as St...
Boy/Male
Tamil
Rituparan | ரிதà¯à®ªà®°à®¾à®£Â
Joyous
Boy/Male
Australian, Indonesian, Slovenia
Young Man
Girl/Female
Hindu, Indian
Head Pain
Boy/Male
Indian, Sanskrit
Excelling
Female
English
 Pet form of English Theodora, THEA means "gift of God." Compare with another form of Thea.
COULOMB WAVE-FUNCTION
COULOMB WAVE-FUNCTION
COULOMB WAVE-FUNCTION
COULOMB WAVE-FUNCTION
COULOMB WAVE-FUNCTION
n.
A wave.
v. t.
See Waive.
Indic. present
of Have
a.
Undulating on the border or surface; waved.
v. i.
To fluctuate; to waver; to be in an unsettled state; to vacillate.
imp. & p. p.
of Wave
v. i.
A vibration propagated from particle to particle through a body or elastic medium, as in the transmission of sound; an assemblage of vibrating molecules in all phases of a vibration, with no phase repeated; a wave of vibration; an undulation. See Undulation.
n.
A wale knot, or wall knot.
v. i.
To play loosely; to move like a wave, one way and the other; to float; to flutter; to undulate.
v. i.
To dwell in a cave.
imp.
of Weave
v. t.
To move like a wave, or by floating; to waft.
v. i.
Fig.: A swelling or excitement of thought, feeling, or energy; a tide; as, waves of enthusiasm.
n.
A million coulombs.
n.
A wave.
a.
Exhibiting a wavelike form or outline; undulating; intended; wavy; as, waved edge.
a.
Rising or swelling in waves; full of waves.