Monday, Apr. 14, 2014
... Classically, the particle would speed up passing the well region, because K = mv2 / 2 = E - V0. According to quantum mechanics, reflection and transmission may occur, but the wavelength inside the potential well is shorter than outside. When the width of the potential well is precisely equal to half ...
... Classically, the particle would speed up passing the well region, because K = mv2 / 2 = E - V0. According to quantum mechanics, reflection and transmission may occur, but the wavelength inside the potential well is shorter than outside. When the width of the potential well is precisely equal to half ...
Initial Stages of Bose-Einstein Condensation
... Rb [3], 7 Li [4] , and 23 Na [5] vapors instead of an atomic hydrogen gas, it appears feasible that experimental studies of the dynamics of Bose-Einstein condensation can be performed in such detail that a more elaborate theory is required to fully understand the outcome of these future experiments. ...
... Rb [3], 7 Li [4] , and 23 Na [5] vapors instead of an atomic hydrogen gas, it appears feasible that experimental studies of the dynamics of Bose-Einstein condensation can be performed in such detail that a more elaborate theory is required to fully understand the outcome of these future experiments. ...
MODIFIED NONLINEAR SCHRÖDINGER EQUATION FOR
... index of the fibre quadratically depends on the electric field amplitude of the optical pulses. In a weakly nonlinear, dispersive medium, the pulse propagation is governed by the cubic nonlinear Schrödinger (cNS) equation [14, 15]. When the effects of dispersion and nonlinearity are exactly balanced ...
... index of the fibre quadratically depends on the electric field amplitude of the optical pulses. In a weakly nonlinear, dispersive medium, the pulse propagation is governed by the cubic nonlinear Schrödinger (cNS) equation [14, 15]. When the effects of dispersion and nonlinearity are exactly balanced ...
Chapter 41. One-Dimensional Quantum Mechanics
... A Particle in a Rigid Box Consider a particle of mass m confined in a rigid, one‐ dimensional box. The boundaries of the box are at x = 0 and x = L. 1. The particle can move freely between 0 and L at constant speed and thus with constant kinetic constant speed and thus with constant kinetic ene ...
... A Particle in a Rigid Box Consider a particle of mass m confined in a rigid, one‐ dimensional box. The boundaries of the box are at x = 0 and x = L. 1. The particle can move freely between 0 and L at constant speed and thus with constant kinetic constant speed and thus with constant kinetic ene ...
Paper
... described as a probability, but there is nothing in the equation to justify such interpretation, and there are many phenomena that contradict it. For instance, when the wave packet hits a boundary, it bounces and interferes with itself (figure ...
... described as a probability, but there is nothing in the equation to justify such interpretation, and there are many phenomena that contradict it. For instance, when the wave packet hits a boundary, it bounces and interferes with itself (figure ...
MC_Paper2_Multiverse
... To understand how the multiverse theory originated, there needs to be an understanding of how the measurement problem was interpreted by High Everett. The measurement problem in quantum mechanics originates from the question on whether or how wave function collapse happens. Wave function simply is t ...
... To understand how the multiverse theory originated, there needs to be an understanding of how the measurement problem was interpreted by High Everett. The measurement problem in quantum mechanics originates from the question on whether or how wave function collapse happens. Wave function simply is t ...
Advanced Atomic, Molecular and Optical Physics
... Motivation and introduction. Organizational issues. Atomic units. Cross sections. Coincidence measurements. Time-of-flight methods. Counting statistics. Atomic beams. Spin and relativity, from Schrödinger to Dirac equation. Solutions with ...
... Motivation and introduction. Organizational issues. Atomic units. Cross sections. Coincidence measurements. Time-of-flight methods. Counting statistics. Atomic beams. Spin and relativity, from Schrödinger to Dirac equation. Solutions with ...
Erwin Schrödinger
Erwin Rudolf Josef Alexander Schrödinger (German: [ˈɛʁviːn ˈʃʁøːdɪŋɐ]; 12 August 1887 – 4 January 1961), sometimes written as Erwin Schrodinger or Erwin Schroedinger, was a Nobel Prize-winning Austrian physicist who developed a number of fundamental results in the field of quantum theory, which formed the basis of wave mechanics: he formulated the wave equation (stationary and time-dependent Schrödinger equation) and revealed the identity of his development of the formalism and matrix mechanics. Schrödinger proposed an original interpretation of the physical meaning of the wave function.In addition, he was the author of many works in various fields of physics: statistical mechanics and thermodynamics, physics of dielectrics, colour theory, electrodynamics, general relativity, and cosmology, and he made several attempts to construct a unified field theory. In his book What Is Life? Schrödinger addressed the problems of genetics, looking at the phenomenon of life from the point of view of physics. He paid great attention to the philosophical aspects of science, ancient and oriental philosophical concepts, ethics, and religion. He also wrote on philosophy and theoretical biology. He is also known for his ""Schrödinger's cat"" thought-experiment.