This course provides a comprehensive overview of the quantum chemical procedures used to determine the energy levels of molecules, originating from the Schrödinger equation. Students will begin by mastering the mathematical methods to solve foundational quantum mechanical models, specifically the "Particle in a Box" and the "Harmonic Oscillator."

Building upon this quantum chemical platform, students will develop the competency to apply these principles to more complex systems, such as the hydrogen atom and the hydrogen molecular ion. The curriculum will culminate in learning the methodology to solve the hydrogen molecule by applying the Born-Oppenheimer approximation. Throughout the course, Braket (Dirac) notation will be extensively utilized.

The ultimate goal of this lecture is to deepen the theoretical understanding of quantum chemistry, equipping students to analyze and comprehend the properties of next-generation materials, such as eco-friendly energy materials like carbon-based structures.

Prerequisites: None. There are no special requirements for enrolling in this course.

As the course primarily aims for the mathematical derivation and understanding of major quantum models typically covered in Physical Chemistry 2, referring to a Physical Chemistry 2 textbook is recommended.

1st week : Introduction to quantum chemistry
2nd week : Limitation of classic atomic model
3rd week : Mr. Tomkins in the wonder land
4th week : Operator?
5th week : Born Interpretation
6th week : Mathematics of Particle in a box
7th week : Postulation of quantum chemistry
8th week : Review & Midterm exam
10th week : Mathematics of Harmonic Oscillator
11th week : Mathematics of Hydrogen atom
12th week : Hermitian
13th week : Variation Method
14th week : Mathematics of Hydrogen Ion
15th week : Mathematics of Hydrogen Molecule
16th week : Review & Final exam

Instruction will be delivered 100% via board work (blackboard/whiteboard).

As an engineer, it is worthwhile to learn the complete mathematical procedures of quantum chemistry at least once. The experience from this course will build the confidence and competency to more easily explore the theoretical foundations of quantum chemistry in the future.