Nápady 57 Quantum Mechanical Model Of Atom Gif

Nápady 57 Quantum Mechanical Model Of Atom Gif. The quantum mechanical model of the atom comes from the solution to schrödinger's equation. Introduction to the quantum mechanical model of the atom:

Tady Atomic Science

This is unlike the bohr model… Quantization of electron energies is a requirement to solve the equation. The quantum mechanical model of the atom comes from the solution to schrödinger's equation.

This is unlike the bohr model…

The quantum mechanical model of the atom. Thinking about electrons as probabilistic matter waves using the de broglie wavelength, the schrödinger equation, and the heisenberg uncertainty principle. The quantum mechanical model of the atom. Introduction to the quantum mechanical model of the atom: The quantum mechanical model of the atom comes from the solution to schrödinger's equation. This is unlike the bohr model… Quantization of electron energies is a requirement in order to solve the equation. The quantum mechanical model of the atom comes from the solution to schrödinger's equation.

Thinking about electrons as probabilistic matter waves using the de broglie wavelength, the schrödinger equation, and the heisenberg uncertainty principle. Introduction to the quantum mechanical model of the atom: Quantization of electron energies is a requirement in order to solve the equation. The quantum mechanical model of the atom. Models of the atom (animation) the early 20th century brought a succession of scientific models, or theories, to describe the atom and its components. Quantization of electron energies is a requirement to solve the equation. Thinking about electrons as probabilistic matter waves using the de broglie wavelength, the schrödinger equation, and the heisenberg uncertainty principle. This is unlike the bohr model… The quantum mechanical model of the atom comes from the solution to schrödinger's equation. Thinking about electrons as probabilistic matter waves using the de broglie wavelength, the schrödinger equation, and the heisenberg uncertainty principle.

Introduction to the quantum mechanical model of the atom: Quantization of electron energies is a requirement in order to solve the equation. The quantum mechanical model of the atom comes from the solution to schrödinger's equation. Models of the atom (animation) the early 20th century brought a succession of scientific models, or theories, to describe the atom and its components. This is unlike the bohr model… The quantum mechanical model of the atom comes from the solution to schrödinger's equation. Introduction to the quantum mechanical model of the atom: Quantization of electron energies is a requirement to solve the equation. Thinking about electrons as probabilistic matter waves using the de broglie wavelength, the schrödinger equation, and the heisenberg uncertainty principle. The quantum mechanical model of the atom comes from the solution to schrödinger's equation.

This is unlike the bohr model…. Quantization of electron energies is a requirement in order to solve the equation. The quantum mechanical model of the atom. Introduction to the quantum mechanical model of the atom:. The quantum mechanical model of the atom.

The quantum mechanical model of the atom. The quantum mechanical model of the atom comes from the solution to schrödinger's equation. Models of the atom (animation) the early 20th century brought a succession of scientific models, or theories, to describe the atom and its components. This is unlike the bohr model… The quantum mechanical model of the atom comes from the solution to schrödinger's equation. Quantization of electron energies is a requirement to solve the equation. Introduction to the quantum mechanical model of the atom: Thinking about electrons as probabilistic matter waves using the de broglie wavelength, the schrödinger equation, and the heisenberg uncertainty principle.

The quantum mechanical model of the atom comes from the solution to schrödinger's equation... Thinking about electrons as probabilistic matter waves using the de broglie wavelength, the schrödinger equation, and the heisenberg uncertainty principle. The quantum mechanical model of the atom comes from the solution to schrödinger's equation. Quantization of electron energies is a requirement to solve the equation. Quantization of electron energies is a requirement in order to solve the equation. The quantum mechanical model of the atom.. Quantization of electron energies is a requirement in order to solve the equation.

The quantum mechanical model of the atom comes from the solution to schrödinger's equation. .. Introduction to the quantum mechanical model of the atom:

Quantization of electron energies is a requirement in order to solve the equation... . Quantization of electron energies is a requirement to solve the equation.

The quantum mechanical model of the atom. Introduction to the quantum mechanical model of the atom: Quantization of electron energies is a requirement to solve the equation. This is unlike the bohr model….. The quantum mechanical model of the atom.

Quantization of electron energies is a requirement to solve the equation. The quantum mechanical model of the atom. Models of the atom (animation) the early 20th century brought a succession of scientific models, or theories, to describe the atom and its components. Quantization of electron energies is a requirement in order to solve the equation. This is unlike the bohr model… Thinking about electrons as probabilistic matter waves using the de broglie wavelength, the schrödinger equation, and the heisenberg uncertainty principle. Introduction to the quantum mechanical model of the atom:. The quantum mechanical model of the atom comes from the solution to schrödinger's equation.

Quantization of electron energies is a requirement to solve the equation. Introduction to the quantum mechanical model of the atom: Quantization of electron energies is a requirement in order to solve the equation. Thinking about electrons as probabilistic matter waves using the de broglie wavelength, the schrödinger equation, and the heisenberg uncertainty principle. The quantum mechanical model of the atom. Quantization of electron energies is a requirement to solve the equation. The quantum mechanical model of the atom comes from the solution to schrödinger's equation. The quantum mechanical model of the atom comes from the solution to schrödinger's equation. This is unlike the bohr model… Models of the atom (animation) the early 20th century brought a succession of scientific models, or theories, to describe the atom and its components. Introduction to the quantum mechanical model of the atom:

The quantum mechanical model of the atom comes from the solution to schrödinger's equation. Introduction to the quantum mechanical model of the atom: This is unlike the bohr model… Models of the atom (animation) the early 20th century brought a succession of scientific models, or theories, to describe the atom and its components. The quantum mechanical model of the atom comes from the solution to schrödinger's equation. Thinking about electrons as probabilistic matter waves using the de broglie wavelength, the schrödinger equation, and the heisenberg uncertainty principle. The quantum mechanical model of the atom comes from the solution to schrödinger's equation. Quantization of electron energies is a requirement to solve the equation. The quantum mechanical model of the atom. Models of the atom (animation) the early 20th century brought a succession of scientific models, or theories, to describe the atom and its components.

This is unlike the bohr model…. Models of the atom (animation) the early 20th century brought a succession of scientific models, or theories, to describe the atom and its components.

Thinking about electrons as probabilistic matter waves using the de broglie wavelength, the schrödinger equation, and the heisenberg uncertainty principle... The quantum mechanical model of the atom comes from the solution to schrödinger's equation. The quantum mechanical model of the atom. The quantum mechanical model of the atom comes from the solution to schrödinger's equation. Introduction to the quantum mechanical model of the atom: Quantization of electron energies is a requirement in order to solve the equation. Models of the atom (animation) the early 20th century brought a succession of scientific models, or theories, to describe the atom and its components. Thinking about electrons as probabilistic matter waves using the de broglie wavelength, the schrödinger equation, and the heisenberg uncertainty principle.. The quantum mechanical model of the atom comes from the solution to schrödinger's equation.

Quantization of electron energies is a requirement to solve the equation... The quantum mechanical model of the atom. Quantization of electron energies is a requirement in order to solve the equation. The quantum mechanical model of the atom comes from the solution to schrödinger's equation. The quantum mechanical model of the atom comes from the solution to schrödinger's equation.. Thinking about electrons as probabilistic matter waves using the de broglie wavelength, the schrödinger equation, and the heisenberg uncertainty principle.

Models of the atom (animation) the early 20th century brought a succession of scientific models, or theories, to describe the atom and its components.. Quantization of electron energies is a requirement in order to solve the equation. Introduction to the quantum mechanical model of the atom: Thinking about electrons as probabilistic matter waves using the de broglie wavelength, the schrödinger equation, and the heisenberg uncertainty principle. The quantum mechanical model of the atom. This is unlike the bohr model… The quantum mechanical model of the atom comes from the solution to schrödinger's equation. Quantization of electron energies is a requirement to solve the equation. Models of the atom (animation) the early 20th century brought a succession of scientific models, or theories, to describe the atom and its components. The quantum mechanical model of the atom comes from the solution to schrödinger's equation. The quantum mechanical model of the atom comes from the solution to schrödinger's equation.

This is unlike the bohr model… . Models of the atom (animation) the early 20th century brought a succession of scientific models, or theories, to describe the atom and its components.

Quantization of electron energies is a requirement to solve the equation. Quantization of electron energies is a requirement in order to solve the equation. Quantization of electron energies is a requirement to solve the equation. The quantum mechanical model of the atom comes from the solution to schrödinger's equation. The quantum mechanical model of the atom comes from the solution to schrödinger's equation.. Introduction to the quantum mechanical model of the atom:

The quantum mechanical model of the atom comes from the solution to schrödinger's equation.. Thinking about electrons as probabilistic matter waves using the de broglie wavelength, the schrödinger equation, and the heisenberg uncertainty principle. Models of the atom (animation) the early 20th century brought a succession of scientific models, or theories, to describe the atom and its components. Quantization of electron energies is a requirement in order to solve the equation. The quantum mechanical model of the atom comes from the solution to schrödinger's equation. Quantization of electron energies is a requirement to solve the equation. The quantum mechanical model of the atom.

Thinking about electrons as probabilistic matter waves using the de broglie wavelength, the schrödinger equation, and the heisenberg uncertainty principle. The quantum mechanical model of the atom comes from the solution to schrödinger's equation. This is unlike the bohr model… The quantum mechanical model of the atom.

Quantization of electron energies is a requirement to solve the equation. Quantization of electron energies is a requirement in order to solve the equation.. Thinking about electrons as probabilistic matter waves using the de broglie wavelength, the schrödinger equation, and the heisenberg uncertainty principle.

Quantization of electron energies is a requirement to solve the equation... Quantization of electron energies is a requirement in order to solve the equation. Quantization of electron energies is a requirement to solve the equation. This is unlike the bohr model… Thinking about electrons as probabilistic matter waves using the de broglie wavelength, the schrödinger equation, and the heisenberg uncertainty principle. The quantum mechanical model of the atom comes from the solution to schrödinger's equation. Models of the atom (animation) the early 20th century brought a succession of scientific models, or theories, to describe the atom and its components. Introduction to the quantum mechanical model of the atom: The quantum mechanical model of the atom comes from the solution to schrödinger's equation. Thinking about electrons as probabilistic matter waves using the de broglie wavelength, the schrödinger equation, and the heisenberg uncertainty principle.

Quantization of electron energies is a requirement in order to solve the equation... The quantum mechanical model of the atom comes from the solution to schrödinger's equation. Thinking about electrons as probabilistic matter waves using the de broglie wavelength, the schrödinger equation, and the heisenberg uncertainty principle. Models of the atom (animation) the early 20th century brought a succession of scientific models, or theories, to describe the atom and its components. Quantization of electron energies is a requirement to solve the equation. Introduction to the quantum mechanical model of the atom: This is unlike the bohr model… The quantum mechanical model of the atom comes from the solution to schrödinger's equation... Introduction to the quantum mechanical model of the atom:

Thinking about electrons as probabilistic matter waves using the de broglie wavelength, the schrödinger equation, and the heisenberg uncertainty principle... Introduction to the quantum mechanical model of the atom: This is unlike the bohr model… The quantum mechanical model of the atom.

The quantum mechanical model of the atom comes from the solution to schrödinger's equation.. The quantum mechanical model of the atom comes from the solution to schrödinger's equation. Introduction to the quantum mechanical model of the atom: Quantization of electron energies is a requirement to solve the equation. The quantum mechanical model of the atom. Thinking about electrons as probabilistic matter waves using the de broglie wavelength, the schrödinger equation, and the heisenberg uncertainty principle. Models of the atom (animation) the early 20th century brought a succession of scientific models, or theories, to describe the atom and its components. The quantum mechanical model of the atom comes from the solution to schrödinger's equation. The quantum mechanical model of the atom comes from the solution to schrödinger's equation.

Quantization of electron energies is a requirement to solve the equation. Thinking about electrons as probabilistic matter waves using the de broglie wavelength, the schrödinger equation, and the heisenberg uncertainty principle. Quantization of electron energies is a requirement in order to solve the equation. This is unlike the bohr model… Quantization of electron energies is a requirement to solve the equation. The quantum mechanical model of the atom. Introduction to the quantum mechanical model of the atom:. The quantum mechanical model of the atom comes from the solution to schrödinger's equation.

Introduction to the quantum mechanical model of the atom: Models of the atom (animation) the early 20th century brought a succession of scientific models, or theories, to describe the atom and its components. Thinking about electrons as probabilistic matter waves using the de broglie wavelength, the schrödinger equation, and the heisenberg uncertainty principle. Introduction to the quantum mechanical model of the atom: This is unlike the bohr model….. Models of the atom (animation) the early 20th century brought a succession of scientific models, or theories, to describe the atom and its components.

This is unlike the bohr model… The quantum mechanical model of the atom comes from the solution to schrödinger's equation. Models of the atom (animation) the early 20th century brought a succession of scientific models, or theories, to describe the atom and its components. Thinking about electrons as probabilistic matter waves using the de broglie wavelength, the schrödinger equation, and the heisenberg uncertainty principle. This is unlike the bohr model… The quantum mechanical model of the atom. Introduction to the quantum mechanical model of the atom: Quantization of electron energies is a requirement to solve the equation. Quantization of electron energies is a requirement in order to solve the equation. The quantum mechanical model of the atom comes from the solution to schrödinger's equation.

The quantum mechanical model of the atom comes from the solution to schrödinger's equation. The quantum mechanical model of the atom comes from the solution to schrödinger's equation. Models of the atom (animation) the early 20th century brought a succession of scientific models, or theories, to describe the atom and its components. This is unlike the bohr model…. Models of the atom (animation) the early 20th century brought a succession of scientific models, or theories, to describe the atom and its components.

This is unlike the bohr model… Introduction to the quantum mechanical model of the atom: Thinking about electrons as probabilistic matter waves using the de broglie wavelength, the schrödinger equation, and the heisenberg uncertainty principle. The quantum mechanical model of the atom comes from the solution to schrödinger's equation. The quantum mechanical model of the atom. Quantization of electron energies is a requirement to solve the equation. This is unlike the bohr model… Models of the atom (animation) the early 20th century brought a succession of scientific models, or theories, to describe the atom and its components. Quantization of electron energies is a requirement in order to solve the equation.. Quantization of electron energies is a requirement in order to solve the equation.

Quantization of electron energies is a requirement in order to solve the equation... The quantum mechanical model of the atom comes from the solution to schrödinger's equation. The quantum mechanical model of the atom comes from the solution to schrödinger's equation. Introduction to the quantum mechanical model of the atom: Quantization of electron energies is a requirement to solve the equation. Quantization of electron energies is a requirement in order to solve the equation. The quantum mechanical model of the atom. Models of the atom (animation) the early 20th century brought a succession of scientific models, or theories, to describe the atom and its components. This is unlike the bohr model… Thinking about electrons as probabilistic matter waves using the de broglie wavelength, the schrödinger equation, and the heisenberg uncertainty principle... Introduction to the quantum mechanical model of the atom:

The quantum mechanical model of the atom. Thinking about electrons as probabilistic matter waves using the de broglie wavelength, the schrödinger equation, and the heisenberg uncertainty principle. The quantum mechanical model of the atom. Introduction to the quantum mechanical model of the atom: The quantum mechanical model of the atom comes from the solution to schrödinger's equation. Quantization of electron energies is a requirement in order to solve the equation. Quantization of electron energies is a requirement to solve the equation. Models of the atom (animation) the early 20th century brought a succession of scientific models, or theories, to describe the atom and its components.. Introduction to the quantum mechanical model of the atom:

This is unlike the bohr model… Thinking about electrons as probabilistic matter waves using the de broglie wavelength, the schrödinger equation, and the heisenberg uncertainty principle. Models of the atom (animation) the early 20th century brought a succession of scientific models, or theories, to describe the atom and its components. Quantization of electron energies is a requirement to solve the equation. The quantum mechanical model of the atom comes from the solution to schrödinger's equation. This is unlike the bohr model… The quantum mechanical model of the atom comes from the solution to schrödinger's equation. Quantization of electron energies is a requirement in order to solve the equation. The quantum mechanical model of the atom. Introduction to the quantum mechanical model of the atom:. Introduction to the quantum mechanical model of the atom:

The quantum mechanical model of the atom comes from the solution to schrödinger's equation. Quantization of electron energies is a requirement in order to solve the equation. This is unlike the bohr model… The quantum mechanical model of the atom. Models of the atom (animation) the early 20th century brought a succession of scientific models, or theories, to describe the atom and its components. The quantum mechanical model of the atom comes from the solution to schrödinger's equation. Thinking about electrons as probabilistic matter waves using the de broglie wavelength, the schrödinger equation, and the heisenberg uncertainty principle. Introduction to the quantum mechanical model of the atom: Quantization of electron energies is a requirement to solve the equation. The quantum mechanical model of the atom comes from the solution to schrödinger's equation. Introduction to the quantum mechanical model of the atom:

Introduction to the quantum mechanical model of the atom:. The quantum mechanical model of the atom. Models of the atom (animation) the early 20th century brought a succession of scientific models, or theories, to describe the atom and its components.. Thinking about electrons as probabilistic matter waves using the de broglie wavelength, the schrödinger equation, and the heisenberg uncertainty principle.

The quantum mechanical model of the atom comes from the solution to schrödinger's equation. Introduction to the quantum mechanical model of the atom: The quantum mechanical model of the atom... Thinking about electrons as probabilistic matter waves using the de broglie wavelength, the schrödinger equation, and the heisenberg uncertainty principle.

Models of the atom (animation) the early 20th century brought a succession of scientific models, or theories, to describe the atom and its components. The quantum mechanical model of the atom comes from the solution to schrödinger's equation. The quantum mechanical model of the atom. Introduction to the quantum mechanical model of the atom: Models of the atom (animation) the early 20th century brought a succession of scientific models, or theories, to describe the atom and its components.. Thinking about electrons as probabilistic matter waves using the de broglie wavelength, the schrödinger equation, and the heisenberg uncertainty principle.

This is unlike the bohr model…. Quantization of electron energies is a requirement to solve the equation. The quantum mechanical model of the atom comes from the solution to schrödinger's equation... Quantization of electron energies is a requirement in order to solve the equation.

The quantum mechanical model of the atom comes from the solution to schrödinger's equation. The quantum mechanical model of the atom comes from the solution to schrödinger's equation.

Models of the atom (animation) the early 20th century brought a succession of scientific models, or theories, to describe the atom and its components. The quantum mechanical model of the atom comes from the solution to schrödinger's equation. Quantization of electron energies is a requirement to solve the equation... Quantization of electron energies is a requirement in order to solve the equation.

The quantum mechanical model of the atom comes from the solution to schrödinger's equation. The quantum mechanical model of the atom comes from the solution to schrödinger's equation. Thinking about electrons as probabilistic matter waves using the de broglie wavelength, the schrödinger equation, and the heisenberg uncertainty principle. Quantization of electron energies is a requirement to solve the equation.. Introduction to the quantum mechanical model of the atom:

Introduction to the quantum mechanical model of the atom: This is unlike the bohr model… The quantum mechanical model of the atom comes from the solution to schrödinger's equation. Quantization of electron energies is a requirement in order to solve the equation. Thinking about electrons as probabilistic matter waves using the de broglie wavelength, the schrödinger equation, and the heisenberg uncertainty principle. Quantization of electron energies is a requirement to solve the equation. Introduction to the quantum mechanical model of the atom: Models of the atom (animation) the early 20th century brought a succession of scientific models, or theories, to describe the atom and its components. The quantum mechanical model of the atom comes from the solution to schrödinger's equation. The quantum mechanical model of the atom. Thinking about electrons as probabilistic matter waves using the de broglie wavelength, the schrödinger equation, and the heisenberg uncertainty principle.

This is unlike the bohr model… Introduction to the quantum mechanical model of the atom:. Introduction to the quantum mechanical model of the atom:

Quantization of electron energies is a requirement in order to solve the equation. Introduction to the quantum mechanical model of the atom: The quantum mechanical model of the atom comes from the solution to schrödinger's equation. Introduction to the quantum mechanical model of the atom:

Introduction to the quantum mechanical model of the atom: Quantization of electron energies is a requirement in order to solve the equation. This is unlike the bohr model… The quantum mechanical model of the atom. The quantum mechanical model of the atom comes from the solution to schrödinger's equation. Quantization of electron energies is a requirement to solve the equation. Models of the atom (animation) the early 20th century brought a succession of scientific models, or theories, to describe the atom and its components. Introduction to the quantum mechanical model of the atom:. The quantum mechanical model of the atom comes from the solution to schrödinger's equation.

Quantization of electron energies is a requirement in order to solve the equation.. The quantum mechanical model of the atom. Models of the atom (animation) the early 20th century brought a succession of scientific models, or theories, to describe the atom and its components. Quantization of electron energies is a requirement in order to solve the equation. Quantization of electron energies is a requirement to solve the equation. The quantum mechanical model of the atom comes from the solution to schrödinger's equation. The quantum mechanical model of the atom comes from the solution to schrödinger's equation. Introduction to the quantum mechanical model of the atom: The quantum mechanical model of the atom comes from the solution to schrödinger's equation.

The quantum mechanical model of the atom comes from the solution to schrödinger's equation. Introduction to the quantum mechanical model of the atom: The quantum mechanical model of the atom comes from the solution to schrödinger's equation. Thinking about electrons as probabilistic matter waves using the de broglie wavelength, the schrödinger equation, and the heisenberg uncertainty principle. This is unlike the bohr model… Models of the atom (animation) the early 20th century brought a succession of scientific models, or theories, to describe the atom and its components. Quantization of electron energies is a requirement to solve the equation... Introduction to the quantum mechanical model of the atom:

Thinking about electrons as probabilistic matter waves using the de broglie wavelength, the schrödinger equation, and the heisenberg uncertainty principle.. The quantum mechanical model of the atom comes from the solution to schrödinger's equation. Models of the atom (animation) the early 20th century brought a succession of scientific models, or theories, to describe the atom and its components. Quantization of electron energies is a requirement to solve the equation. The quantum mechanical model of the atom comes from the solution to schrödinger's equation.. Quantization of electron energies is a requirement in order to solve the equation.

Models of the atom (animation) the early 20th century brought a succession of scientific models, or theories, to describe the atom and its components. Quantization of electron energies is a requirement to solve the equation. Thinking about electrons as probabilistic matter waves using the de broglie wavelength, the schrödinger equation, and the heisenberg uncertainty principle. The quantum mechanical model of the atom comes from the solution to schrödinger's equation. The quantum mechanical model of the atom. Introduction to the quantum mechanical model of the atom: This is unlike the bohr model… Models of the atom (animation) the early 20th century brought a succession of scientific models, or theories, to describe the atom and its components. Quantization of electron energies is a requirement in order to solve the equation. The quantum mechanical model of the atom comes from the solution to schrödinger's equation.. Quantization of electron energies is a requirement to solve the equation.

The quantum mechanical model of the atom comes from the solution to schrödinger's equation.. The quantum mechanical model of the atom... Quantization of electron energies is a requirement to solve the equation.

The quantum mechanical model of the atom comes from the solution to schrödinger's equation.. Thinking about electrons as probabilistic matter waves using the de broglie wavelength, the schrödinger equation, and the heisenberg uncertainty principle. Quantization of electron energies is a requirement in order to solve the equation. The quantum mechanical model of the atom comes from the solution to schrödinger's equation. The quantum mechanical model of the atom. The quantum mechanical model of the atom comes from the solution to schrödinger's equation.. Models of the atom (animation) the early 20th century brought a succession of scientific models, or theories, to describe the atom and its components.

Introduction to the quantum mechanical model of the atom: The quantum mechanical model of the atom. This is unlike the bohr model… The quantum mechanical model of the atom comes from the solution to schrödinger's equation. Quantization of electron energies is a requirement in order to solve the equation. Thinking about electrons as probabilistic matter waves using the de broglie wavelength, the schrödinger equation, and the heisenberg uncertainty principle. Introduction to the quantum mechanical model of the atom: The quantum mechanical model of the atom comes from the solution to schrödinger's equation. Quantization of electron energies is a requirement to solve the equation. Models of the atom (animation) the early 20th century brought a succession of scientific models, or theories, to describe the atom and its components.. The quantum mechanical model of the atom.

The quantum mechanical model of the atom comes from the solution to schrödinger's equation. The quantum mechanical model of the atom comes from the solution to schrödinger's equation. Quantization of electron energies is a requirement to solve the equation. Models of the atom (animation) the early 20th century brought a succession of scientific models, or theories, to describe the atom and its components.. Models of the atom (animation) the early 20th century brought a succession of scientific models, or theories, to describe the atom and its components.

The quantum mechanical model of the atom comes from the solution to schrödinger's equation.. Quantization of electron energies is a requirement to solve the equation. The quantum mechanical model of the atom. Models of the atom (animation) the early 20th century brought a succession of scientific models, or theories, to describe the atom and its components. Quantization of electron energies is a requirement in order to solve the equation. Thinking about electrons as probabilistic matter waves using the de broglie wavelength, the schrödinger equation, and the heisenberg uncertainty principle. Introduction to the quantum mechanical model of the atom: The quantum mechanical model of the atom comes from the solution to schrödinger's equation.. Introduction to the quantum mechanical model of the atom: