Presentation is loading. Please wait.

Presentation is loading. Please wait.

Solutions of the Schrödinger equation for the ground helium by finite element method Jiahua Guo.

Published byGlenna Budiaman Modified over 6 years ago

Similar presentations

Presentation on theme: "Solutions of the Schrödinger equation for the ground helium by finite element method Jiahua Guo."— Presentation transcript:

1 Solutions of the Schrödinger equation for the ground helium by finite element method
Jiahua Guo

2 Introduction Schrödinger equation Problems with traditional methods
Helium atom system Challenge of solving He with FEM

3 Governing equations In Cartesian coordinates, the spin-independent, nonrelativistic Schrödinger equation for the two electrons in the helium atom is: In spherical coordinates: L is the angular momentum operator and can be written as: Thus the Hamiltonian operator can be finally written as:

4 Boundary conditions & Formulation
When out of the boundary Formulation Coefficient form of eigenvalue PDE in FEMlab:

5 Solution E = -2.7285 hartree = -74.22eV (Experimental result:
Eexp = eV The slice scheme of the helium wave function with the lowest eigenvalue

6 Validation Energy levels for hydrogen atom Atomic orbits Energy level
Energy value based on Bohr model (hartree) Energy value calculated by FemLab (hartree) Error n=1 0.28% n=2 0.24% Atomic orbits 1s 2s 2px 2py 2pz

7 Conclusion Schrödinger equation can be simplified by decreasing some variables, making it an equation with fewer dimensions. FEMlab is a good tool when trying to find out the eigenvalues of energy of some three-dimensional systems (e.g. hydrogen and helium atoms). However, it can’t deal with a complicated many-body Schrödinger equation.

8 Thank you!

Download ppt "Solutions of the Schrödinger equation for the ground helium by finite element method Jiahua Guo."

Similar presentations

Infinite Square Well “Particle in a Box”: Hydrogen (like) Atom Bohr Model: eV Bohr radius: a 0 = 0.0529 nm Orbital angular momentum.

Infinite Square Well “Particle in a Box”: Hydrogen (like) Atom Bohr Model: eV Bohr radius: a 0 = nm Orbital angular momentum.
Atomic Physics Selected Topics - 3 Selected Topics - 3.

Atomic Physics Selected Topics - 3 Selected Topics - 3.
Chap 12 Quantum Theory: techniques and applications Objectives: Solve the Schrödinger equation for: Translational motion (Particle in a box) Vibrational.

Chap 12 Quantum Theory: techniques and applications Objectives: Solve the Schrödinger equation for: Translational motion (Particle in a box) Vibrational.
Quantum Mechanics in three dimensions.

Quantum Mechanics in three dimensions.
Physics 452 Quantum mechanics II Winter 2011 Karine Chesnel.

Physics 452 Quantum mechanics II Winter 2011 Karine Chesnel.
Infinite Potential Well … bottom line

Infinite Potential Well … bottom line
PHYS 30101 Quantum Mechanics PHYS 30101 Quantum Mechanics Dr Jon Billowes Nuclear Physics Group (Schuster Building, room 4.10)

PHYS Quantum Mechanics PHYS Quantum Mechanics Dr Jon Billowes Nuclear Physics Group (Schuster Building, room 4.10)
Quantum Theory of Atoms The Bohr theory of Hydrogen(1913) cannot be extended to other atoms with more than one electron we have to solve the Schrödinger.

Quantum Theory of Atoms The Bohr theory of Hydrogen(1913) cannot be extended to other atoms with more than one electron we have to solve the Schrödinger.
Wave mechanics in potentials Modern Ch.4, Physical Systems, 30.Jan.2003 EJZ Particle in a Box (Jason Russell), Prob.12 Overview of finite potentials Harmonic.

Wave mechanics in potentials Modern Ch.4, Physical Systems, 30.Jan.2003 EJZ Particle in a Box (Jason Russell), Prob.12 Overview of finite potentials Harmonic.
Ground State of the He Atom – 1s State First order perturbation theory Neglecting nuclear motion 1 - electron 1 2 - electron 2 r 1 - distance of 1 to nucleus.

Ground State of the He Atom – 1s State First order perturbation theory Neglecting nuclear motion 1 - electron electron 2 r 1 - distance of 1 to nucleus.
Lecture 17 Hydrogenic atom (c) So Hirata, Department of Chemistry, University of Illinois at Urbana-Champaign. This material has been developed and made.

Lecture 17 Hydrogenic atom (c) So Hirata, Department of Chemistry, University of Illinois at Urbana-Champaign. This material has been developed and made.
What is meant by the term “ground state”? It is the lowest energy state that an electron can occupy.

What is meant by the term “ground state”? It is the lowest energy state that an electron can occupy.
Quantum mechanics unit 2

Quantum mechanics unit 2
MULTIELECTRON ATOMS l ELECTRON SPIN: Electron has intrinsic angular momentum - “spin”; it behaves as if it were “spinning”, i.e. rotating around its axis.

MULTIELECTRON ATOMS l ELECTRON SPIN: Electron has intrinsic angular momentum - “spin”; it behaves as if it were “spinning”, i.e. rotating around its axis.
Lecture VIII Hydrogen Atom and Many Electron Atoms dr hab. Ewa Popko.

Lecture VIII Hydrogen Atom and Many Electron Atoms dr hab. Ewa Popko.
LECTURE 21 THE HYDROGEN AND HYDROGENIC ATOMS PHYSICS 420 SPRING 2006 Dennis Papadopoulos.

LECTURE 21 THE HYDROGEN AND HYDROGENIC ATOMS PHYSICS 420 SPRING 2006 Dennis Papadopoulos.
Quantum Theory. The Quantum Model of the Atom Heisenberg Uncertainty Principle: This idea involves the detection of electrons. Electrons are detected.

Quantum Theory. The Quantum Model of the Atom Heisenberg Uncertainty Principle: This idea involves the detection of electrons. Electrons are detected.
1 MODELING MATTER AT NANOSCALES 4. Introduction to quantum treatments 4.02. The variational method.

1 MODELING MATTER AT NANOSCALES 4. Introduction to quantum treatments The variational method.
Wednesday, Nov. 13, 2013 PHYS 3313-001, Fall 2013 Dr. Jaehoon Yu 1 PHYS 3313 – Section 001 Lecture #18 Wednesday, Nov. 13, 2013 Dr. Jaehoon Yu Solutions.

Wednesday, Nov. 13, 2013 PHYS , Fall 2013 Dr. Jaehoon Yu 1 PHYS 3313 – Section 001 Lecture #18 Wednesday, Nov. 13, 2013 Dr. Jaehoon Yu Solutions.
Hydrogen Atom and QM in 3-D 1. HW 8, problem 6.32 and A review of the hydrogen atom 2. Quiz 10.30 3. Topics in this chapter:  The hydrogen atom  The.

Hydrogen Atom and QM in 3-D 1. HW 8, problem 6.32 and A review of the hydrogen atom 2. Quiz Topics in this chapter:  The hydrogen atom  The.

Similar presentations

Ads by Google