Corrections to The Pauli Principle: Effects on the Wave Function Seen through the Lens of Orbital Overlap

We explain how to treat a microscopic wave function of α-condensation named THSR taking 3α-condensation as a typical example. The microscopic model, which fully takes into account the Pauli principle between all the constituent nucleons and effective inter-nucleon forces simultaneously, can play an important role in reproducing an α-gas-like nature thanks to α-condensation. We study its typical features by giving numerical results of the norm kernel for 3α-condensation.

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The Pauli Principle: Effects on the Wave Function Seen through the Lens of Orbital Overlap

Journal of Chemical Education ◽

10.1021/acs.jchemed.8b00407 ◽

2018 ◽

Vol 95 (9) ◽

pp. 1587-1591 ◽

Cited By ~ 2

Author(s):

David R. McMillin

Keyword(s):

Wave Function ◽

Pauli Principle

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Identical particles and the helium atom

10.1093/oso/9780198857242.003.0014 ◽

2021 ◽

pp. 164-178

Author(s):

Geoffrey Brooker

Keyword(s):

Wave Function ◽

Helium Atom ◽

Pauli Principle ◽

Quantum States ◽

Spin States ◽

Identical Particles ◽

Space Wave

“Identical particles and the helium atom” introduces bosons and fermions. Fermion states are expressed in terms of Slater determinants and the Pauli Principle. Helium is presented in such a way as to show what properties are and are not due to electron identity. Quantum states are described according as the space wave function is symmetric or antisymmetric under interchange of labels attached to the electrons. These in turn form singlet and triplet spin states when the electrons’ fermion identity is taken into account. Helium is an example of LS coupling, but a rather stunted example.

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Effect of a repulsive core in the theory of complex nuclei

Proceedings of the Royal Society of London Series A - Mathematical and Physical Sciences ◽

10.1098/rspa.1957.0017 ◽

1957 ◽

Vol 238 (1215) ◽

pp. 551-567 ◽

Cited By ~ 229

Keyword(s):

Differential Equation ◽

Wave Function ◽

Effective Mass ◽

Pauli Principle ◽

Large Momentum ◽

Repulsive Core ◽

Spherical Waves ◽

Mass Approximation ◽

Spatial Wave Function ◽

Complex Nuclei

Using Brueckner’s method for the treatment of complex nuclei, the effect of an infinite repulsive core in the interaction between nucleons is studied. The Pauli principle is taken into account from the beginning. A spatial wave function for two nucleons is defined, and an integro-differential equation for this function is derived. Owing to the Pauli principle, the wave function contains no outgoing spherical waves. A solution is given for the case when only a repulsive core potential acts. The effective-mass approximation is investigated for virtual states of very large momentum.

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Analytic integration of contrast transfer functions

Proceedings, annual meeting, Electron Microscopy Society of America ◽

10.1017/s042482010010617x ◽

1988 ◽

Vol 46 ◽

pp. 822-823

Author(s):

Peter Rez

Keyword(s):

Wave Function ◽

Transfer Function ◽

Transfer Functions ◽

Spherical Aberration ◽

Continuous Distribution ◽

Objective Lens ◽

Direction Parallel ◽

Scattering Angle ◽

Analytic Integration ◽

Image Position

In high resolution microscopy the image amplitude is given by the convolution of the specimen exit surface wave function and the microscope objective lens transfer function. This is usually done by multiplying the wave function and the transfer function in reciprocal space and integrating over the effective aperture. For very thin specimens the scattering can be represented by a weak phase object and the amplitude observed in the image plane is1where fe (Θ) is the electron scattering factor, r is a postition variable, Θ a scattering angle and x(Θ) the lens transfer function. x(Θ) is given by2where Cs is the objective lens spherical aberration coefficient, the wavelength, and f the defocus.We shall consider one dimensional scattering that might arise from a cross sectional specimen containing disordered planes of a heavy element stacked in a regular sequence among planes of lighter elements. In a direction parallel to the disordered planes there will be a continuous distribution of scattering angle.

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Atomic Imaging of Crystals using Large-Angle Electron Scattering in STEM

Proceedings, annual meeting, Electron Microscopy Society of America ◽

10.1017/s0424820100179129 ◽

1990 ◽

Vol 48 (1) ◽

pp. 74-75

Author(s):

D.E. Jesson ◽

S. J. Pennycook

Keyword(s):

Wave Function ◽

Electron Scattering ◽

Numerical Solutions ◽

Large Angle ◽

Real Space ◽

High Angle ◽

Analytical Treatment ◽

Order Zero ◽

Experimental Conditions ◽

Ewald Sphere

It is well known that conventional atomic resolution electron microscopy is a coherent imaging process best interpreted in reciprocal space using contrast transfer function theory. This is because the equivalent real space interpretation involving a convolution between the exit face wave function and the instrumental response is difficult to visualize. Furthermore, the crystal wave function is not simply related to the projected crystal potential, except under a very restrictive set of experimental conditions, making image simulation an essential part of image interpretation. In this paper we present a different conceptual approach to the atomic imaging of crystals based on incoherent imaging theory. Using a real-space analysis of electron scattering to a high-angle annular detector, it is shown how the STEM imaging process can be partitioned into components parallel and perpendicular to the relevant low index zone-axis.It has become customary to describe STEM imaging using the analytical treatment developed by Cowley. However, the convenient assumption of a phase object (which neglects the curvature of the Ewald sphere) fails rapidly for large scattering angles, even in very thin crystals. Thus, to avoid unpredictive numerical solutions, it would seem more appropriate to apply pseudo-kinematic theory to the treatment of the weak high angle signal. Diffraction to medium order zero-layer reflections is most important compared with thermal diffuse scattering in very thin crystals (<5nm). The electron wave function ψ(R,z) at a depth z and transverse coordinate R due to a phase aberrated surface probe function P(R-RO) located at RO is then well described by the channeling approximation;

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Vector wave function expansions of dyadic Green's functions for bianisotropic media

IEE Proceedings - Microwaves Antennas and Propagation ◽

10.1049/ip-map:20020292 ◽

2002 ◽

Vol 149 (1) ◽

pp. 57-63 ◽

Cited By ~ 7

Author(s):

E.L. Tan

Keyword(s):

Wave Function ◽

Green's Functions ◽

Green’S Functions ◽

Vector Wave ◽

Vector Wave Function ◽

Dyadic Green’S Functions ◽

Dyadic Green's Functions

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DEUTERON: WAVE FUNCTION AND PARAMETERS

Scientific Herald of Uzhhorod University Series Physics ◽

10.24144/2415-8038.2014.36.100-106 ◽

2014 ◽

Vol 36 (0) ◽

pp. 100-106 ◽

Cited By ~ 3

Author(s):

І. І. Гайсак ◽

В. І. Жаба

Keyword(s):

Wave Function ◽

Deuteron Wave Function

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Operators and meaning of wave function

JOURNAL OF ADVANCES IN PHYSICS ◽

10.24297/jap.v11i8.216 ◽

2016 ◽

pp. 4039-4042

Author(s):

Viliam Malcher

Keyword(s):

Wave Function ◽

Quantum Theory ◽

State Vector ◽

The State ◽

Physical Significance ◽

Central Problem ◽

Quantum Mechanical ◽

Mechanical Description ◽

Quantum Mechanical Description ◽

Interpretation Of Quantum Theory

The interpretation problems of quantum theory are considered. In the formalism of quantum theory the possible states of a system are described by a state vector. The state vector, which will be represented as |Ïˆ> in Dirac notation, is the most general form of the quantum mechanical description. The central problem of the interpretation of quantum theory is to explain the physical significance of the |Ïˆ>. In this paper we have shown that one of the best way to make of interpretation of wave function is to take the wave function as an operator.

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The build of nonlinear quantum mechancs and variations of feature of microscopic particles as well as their experimental affirmation

JOURNAL OF ADVANCES IN PHYSICS ◽

10.24297/jap.v5i3.1927 ◽

2014 ◽

Vol 5 (3) ◽

pp. 871-981 ◽

Cited By ~ 1

Author(s):

Pang Xiao Feng

Keyword(s):

Wave Function ◽

Quantum Mechanics ◽

Lagrange Equation ◽

Minimum Principle ◽

Superposition Principle ◽

Type Equation ◽

Experimental Results ◽

Traditional Concept ◽

Nonlinear Quantum ◽

Nonlinear Quantum Mechanics

We establish the nonlinear quantum mechanics due to difficulties and problems of original quantum mechanics, in which microscopic particles have only a wave feature, not corpuscle feature, which are completely not consistent with experimental results and traditional concept of particle. In this theory the microscopic particles are no longer a wave, but localized and have a wave-corpuscle duality, which are represented by the following facts, the solutions of dynamic equation describing the particles have a wave-corpuscle duality, namely it consists of a mass center with constant size and carrier wave, is localized and stable and has a determinant mass, momentum and energy, which obey also generally conservation laws of motion, their motions meet both the Hamilton equation, Euler-Lagrange equation and Newton-type equation, their collision satisfies also the classical rule of collision of macroscopic particles, the uncertainty of their position and momentum is denoted by the minimum principle of uncertainty. Meanwhile the microscopic particles in this theory can both propagate in solitary wave with certain frequency and amplitude and generate reflection and transmission at the interfaces, thus they have also a wave feature, which but are different from linear and KdV solitary waveâ€™s. Therefore the nonlinear quantum mechanics changes thoroughly the natures of microscopic particles due to the nonlinear interactions. In this investigation we gave systematically and completely the distinctions and variations between linear and nonlinear quantum mechanics, including the significances and representations of wave function and mechanical quantities, superposition principle of wave function, property of microscopic particle, eigenvalue problem, uncertainty relation and the methods solving the dynamic equations, from which we found nonlinear quantum mechanics is fully new and different from linear quantum mechanics. Finally, we verify further the correctness of properties of microscopic particles described by nonlinear quantum mechanics using the experimental results of light soliton in fiber and water soliton, which are described by same nonlinear SchrÃ¶dinger equation. Thus we affirm that nonlinear quantum mechanics is correct and useful, it can be used to study the real properties of microscopic particles in physical systems.

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