Basic principles of quantum mechanics which constitutes the fundamental theory in understanding the properties of matters are introduced in this course. The structure and properties of individual atoms and molecules are examined from the viewpoint of quantum mechanics.

It studies a general principle and an application of the organic chemistry. Therefore easily understands. It learns compound nomenclature, energy transfer state, stereochemistry, radical reaction, nucleophillic and electrophillic reaction, conjugation, resonance and so on.

Mathematical concepts and methods for chemistry courses. Topics covered differential equations, Laplace transformation, vector analysis, Fourier series, and matrices.

Learning classical analytical theories among basic principles of analytical chemistry such as gravimetry and volumetric analysis Physical Chemistry Lab. This course is focused on essential laboratory principles and instrumental operations from experimental studies of fundamental physicochemical properties including various physical properties of substances. This course explores experimental methods and chemical principles from measurements of physiochemical and spectroscopic properties of substances including thermochemistry, equilibrium, and electrochemical reactions.

Lectures dealing with various topics related to interactions between light and matters. The topics include molecular symmetry and its applications to molecular structure and spectroscopy, rotational, vibrational and electronic transitions of molecules, lasers and their applications in chemistry, and nuclear magnetic resonance spectroscopy.

Continuation of Organic Chemistry I. This course covers the chemistry of carbonyl compounds, carboxylic acids, carboxylic acid derivatives, amines, and heterocyclic compounds. Topics include aromatic compounds, molecular orbital theory and pericyclic reactions, various natural products and biological molecules including carbohydrates, amino acids, proteins, and lipids.

With the present-day objection regarding a inorganic compound bond and a structure it lectures the fundamental concept regarding a chemistry of complex. Analytical Chemistry Lab. Learning how to analyze unknown samples throughout qualitative analysis and gravimetric experiments Physical Chemistry III The concepts that are needed for the discussion of equilibria in chemistry are developed in this course. Equilibria include physical change, such as fusion and vaporization, and chemical change, including electrochemistry. The discussion is in terms of thermodynamics, and particularly in terms of enthalpy and entropy, which deal with the bulk properties of matter.

This course aims at the delivery of up-to-date knowledge covering important organic chemical concepts, methodology, and the designing of synthetic target compounds, which are serving as the key stones in modern organic synthesis.
Relating with this purpose, synthetic analysis, synthetic strategies, and interrelated organic reactions will be taught. More specifically recent advanced organic reactions such as carbon-carbon coupling reactions, manipulation of functional groups, functional group interchange, thermally unfavorable reactions, cyclization reaction, organometallic reactions, etc., numerous organic mechanisms, and organic structures will be learned.

Learning the theory and practice on spectroscopic and electrochemical analysis among basic principles of analytical chemistry

During this lab., students will conduct synthesis, purification and characterization of various inorganic compounds including coordination compounds, racemic compounds and organometallic compounds, which they learn from inorganic lectures. In addition, students will also learn how to exploit the inorganic theorems to understand the inorganic products and the characterization results.

The basis of statistical thermodynamics. The diffraction methods. The electric and magnetic properties of molecules. The structures and physical properties of macromolecules.

This course will provide basic principles of spectroscopic methods, such as NMR, IR, UV, Mass spectrometer, which are essential in analysis of chemical structures of organic compounds. The course enables students to learn how to analyze spectroscopic data and how to anticipate exact chemical structures of unknown compounds from spectroscopic data.

Learning the structure and property of instrumental elements based on properties of light, UV-Vis spectroscopy, atomic absorption spectroscopy, and potentiometric analysis

It discusses a manufacture, a synthesis and a structure of the simple organometal complex and the coordinated chemical compound. It treats a theory, an interpretation and an applicability of the spectrum.

The primary aim of this course is to learn the basic experimental techniques for organic synthesis and medicinal chemistry. In this practical teaching lab, the students will learn synthetic strategies and simple practical skills for synthesis of small drug molecules and their derivatives. Before starting each experiment, students will learn (1) goals and principles of each experiment, (2) how to use laboratory apparatus correctly, and (3) how to write a report. The students must follow safety rules during this lab.

Basic concepts of reaction rate. Experimental and theoretical methods to study of rate and mechanism of chemical reaction. The reaction dynamics of elemental processes in molecular level. Application to the study of surface and atmospheric sciences.

This course examines fundamentals of modern electrochemistry including equilibrium/dynamic electrochemistry, and instrumentation associated with these methods.

This course aims at the understanding of general principles and mechanisms of organic reactions. Molecular orbital theory, kinetics, thermodynamics, nucleophilic substitution reactions, aromatic substitution reactions, radical reactions and photo reactions will be discussed.

Polymers are large molecules made of monomers. Examples include plastics, rubbers, fibers, biological polymers such as proteins and DNA, and inorganic polymers such as glass. We will discuss the basic concepts in polymer sciences. Covered topics include: Molecular weight & molecular weight determination; Polymer Synthesis; Copolymerization; Characterization of polymers; Polymer structures; Reactions of polymers

Learning the structure, property, and analytical methods of instrumental elements related fluorescence, ICS-AES polarography, chromatography.

This course will develop the concepts of descriptive and theoretical Inorganic Chemistry. The advanced topics to be present will included molecular shape and symmetry, complexes of the d-block elements and redox chemistry, an introduction to the electronic spectroscopy and reaction mechanisms of transition metal complexes. This course will present the inorganic chemistry necessary for employment in the chemical industry and further work at the advanced undergraduate level.

Historical view as well as goals of the chemical education is covered in this class. The other important subjects convered include teaching-learning theory in chemical eduction, evaluation of chemistry learning, and teaching chemical experiments.

A first course in molecular quantum mechanics dealing with the basic elements of quantum chemistry, quantitative treatments of Shrödinger equations and their applications to systems of interest to chemists, the electronic structure of atoms and molecules, and various approximate methods of calculations.

This course aims to provide modern synthetic methodologies for preparation of target organic molecules to undergraduate students who have took the basic courses of organic chemistry. The course will offer the students deeper understanding of retrosynthetic analysis, name reactions, and well-established synthetic routes for general pharmaceutical products.

It handles the important concepts and the fundamental knowledges of a biochemistry.

This subject deals with the theory of organometallic compounds that have direct bonds between metal and hydrogen or between metal and carbon from the viewpoint of inorganic chemist. The curriculum has three objectives. First, the contents of symmetry theory, group theory, molecular orbital theory, crystal field theory, and ligand field theory for inorganic complexes are extended to organometallic compounds. Secondly, we learn about organometallic compounds and their applications to catalytic reactions, organometallic reactions, industrial chemistry, and coordination polymer chemistry. Finally, we learn about the detailed mechanism in catalyst reaction and its interpretation.

Textbooks and reference books used in secondary school chemistry coures are reviewed. Chemistry and chemistry-related scientific contents from those books are analyzed and evaluated based on teaching theories.

Science uses logic to derive reasonable conclusions. Essays are critical for presenting the results obtained from the scientific experiments and observations. In this class logic and methods of scientific thinking are covered which lead to reasonable scientific conclusions. How to train students to enhance their ability to learn the method of scientific thinking and utilize logics. Teaching students to write scientific essays is an another important topic to be covered in this lecture.

Molecular structure, reactivity, reaction kinetics, and chemical properties of matter can be predicted by various computational chemistry methods to aid the analysis of experimental data. This course teaches the basic principles of the methods and how to implement it in real world.

The principles, features, and operating techniques of various spectrometers which are applicable to the chemical analysis of materials are discussed.