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Science Chemistry PHYSICAL CHEMISTRY-STUDENT SOLN.MAN.

The validation of the given statement that 2-D rotational motion wavefunctions have no nodes is to be explained. Concept introduction: The wavefunction for 2-D rotational motion is given below. Ψ m = 1 2 π e i m ϕ Where, Ψ m represents the wavefunction dependent on quantum number m . The values of m start from 0 . Also, it can take up both negative and positive integral values.

The validation of the given statement that 2-D rotational motion wavefunctions have no nodes is to be explained. Concept introduction: The wavefunction for 2-D rotational motion is given below. Ψ m = 1 2 π e i m ϕ Where, Ψ m represents the wavefunction dependent on quantum number m . The values of m start from 0 . Also, it can take up both negative and positive integral values.

Solution Summary: The author explains that 2-D rotational motion wavefunctions have no nodes as the probability of the function is independent of quantum number

PHYSICAL CHEMISTRY-STUDENT SOLN.MAN.

PHYSICAL CHEMISTRY-STUDENT SOLN.MAN.

2nd Edition

ISBN: 9781285074788

Author: Ball

Publisher: CENGAGE L

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Techniques and applications of quantum theory

Quantum theory, often known as quantum physics, is the foundation of modern physics and encompasses the nature and behavior of matter and energy at the atomic and molecular levels. As the exact nature and behavior of atomic and subatomic particles are im…

Question

Chapter 11, Problem 11.39E

Interpretation Introduction

Interpretation:

The validation of the given statement that 2-D rotational motion wavefunctions have no nodes is to be explained.

Concept introduction:

The wavefunction for 2-D rotational motion is given below.

Ψm=12πeimϕ

Where, Ψm represents the wavefunction dependent on quantum number m. The values of m start from 0. Also, it can take up both negative and positive integral values.

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Chapter 11, Problem 11.38E

Chapter 11, Problem 11.40E

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Chapter 11 Solutions

PHYSICAL CHEMISTRY-STUDENT SOLN.MAN.

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