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Through lectures of physical chemistry classes, fundamentals of physical and mathematical knowledge will be lectured. However, it is also necessary to solve actual problems in physical chemistry issues. Topics and exercises in special cases will be extended.
Through lectures of physical chemistry classes, fundamentals of physical and mathematical knowledge will be lectured. However, it is also necessary to solve actual problems in physical chemistry issues. Topics and exercises in special cases will be extended.
Through lectures of physical chemistry classes, fundamentals of physical and mathematical knowledge will be lectured. However, it is also necessary to solve actual problems in physical chemistry issues. Topics and exercises in special cases will be extended.
Through lectures of physical chemistry classes, fundamentals of physical and mathematical knowledge will be lectured. However, it is also necessary to solve actual problems in physical chemistry issues. Topics and exercises in special cases will be extended.
Chemical kinetics, also known as reaction kinetics, is the study of the speed of chemical processes.
A study of chemical kinetics includes investigations of how experimental conditions can influence on the speed of a chemical reaction. In this class, appropriate construction of mathematical models that can describe the characteristics of a chemical reaction will be discussed. Concept of "order of reaction" and "how to determine order of reaction along with integrated rate laws" are also the most important topics of this class. Moreover, the enzymatic reaction kinetics will be introduced to understand the specific examples of chemical reaction rate determination.
On the other hand, starting from the discussion of molecular velocities in the gas phase (Maxwell-Boltzmann distribution), the relationship between molecular collisions and reaction rates will be discussed. This discussion will be continued to study the relationship between chemical reactions in the gas phase and the internal and potential energies of the reacting molecules.Through the trial to solve the problems in the textbook, the establishment of the knowledge will be achieved.
Chemical kinetics, also known as reaction kinetics, is the study of the speed of chemical processes.
A study of chemical kinetics includes investigations of how experimental conditions can influence on the speed of a chemical reaction. In this class, appropriate construction of mathematical models that can describe the characteristics of a chemical reaction will be discussed. Concept of "order of reaction" and "how to determine order of reaction along with integrated rate laws" are also the most important topics of this class. Moreover, the enzymatic reaction kinetics will be introduced to understand the specific examples of chemical reaction rate determination.
On the other hand, starting from the discussion of molecular velocities in the gas phase (Maxwell-Boltzmann distribution), the relationship between molecular collisions and reaction rates will be discussed. This discussion will be continued to study the relationship between chemical reactions in the gas phase and the internal and potential energies of the reacting molecules.Through the trial to solve the problems in the textbook, the establishment of the knowledge will be achieved.
この講義では、量子力学と量子化学の基礎を学び理解を深める。量子力学の基礎から始め、基本であるシュレディンガー方程式について学ぶ。粒子の波動性を記述する波動関数の基本概念(=シュレディンガー方程式の解)や量子力学における分子の振動、回転運動や水素原子の電子状態のモデル化やその応用を習得する。
In this lecture, we try to understand fundamentals of the quantum mechanics and quantum chemistry that are required for advanced chemistry courses. Starting with a lecture of the early quantum mechanics, we learn how to formulate the Schrödinger equation, which is the basic equation of quantum mechanics. The basic concept of wavefunctions ( = solutions of the Schrödinger equations) are presented to understand the wave nature of particles in atomic scale. Then the simple models for vibrational and rotational motions of molecules, and the electronic state of the hydrogen atom are treated quantum mechanically as the prototypes for more complex atoms and molecules.
In this course, we study thermodynamics, statistical mechanics, and the properties of many-body systems at finite temperature. The course is intended for the understanding both of chemical physical phenomena appeared in material science. We will cover the classical thermodynamics, the relationship between the macroscopic phenomena and the microscopic properties (statistical mechanics), and the application of these ideas to the observed states of actual materials.
In this course, we study thermodynamics, statistical mechanics, and the properties of many-body systems at finite temperature. The course is intended for the understanding both of chemical physical phenomena appeared in material science. We will cover the classical thermodynamics, the relationship between the macroscopic phenomena and the microscopic properties (statistical mechanics), and the application of these ideas to the observed states of actual materials.
物理化学・量子化学の基礎となる量子力学とその化学結合への応用について学ぶ。具体的には、量子力学における数学的手法・近似法、原子構造、化学結合、原子価結合、分子軌道理論について学ぶ。
The course deals with the introduction to the principles of quantum mechanics and their application to chemical systems.Topics include the formalism and mahtematical tools of quantum mechanics; approximate methods; atomic structure; the chemical bond,valence bond; and molecular orbital theory.
Starting from a lecture of the basic of spectroscopy,we try to survey modem spectroscopic methods used in physical chemistry.
Gain the skill for the analysis of molecules,focusing on the understanding and application to the
spectroscopic methods. We cover wide area of the spectroscopic methods,including optical absorprion/emission spectroscopy and magnetic resonance spectroscopy.
液体界面は我々の周りに広く見られ、気液界面、液液界面、固液界面と多岐にわたり、蒸発や凝縮はもとより、抽出や分離、センサー、電気化学反応など多くの例で重要な対象である。本講義では、これらの液体界面の現象を理解するための理論および計測方法の基礎を概説する。
学部で学んだ物理化学、とくに熱力学をもとに不均一な界面系に応用する発展を扱い、界面を特徴づける量を熱力学の観点から理解する。そして界面の熱力学を基盤として、さらに統計力学、電気化学、分光学、分子シミュレーションなどの手法と知見と取り扱う。
Liquid interfaces, including gas-liquid, liquid-liquid and solid-liquid, are ubiquitous in our life, and play important roles in a number of phenomena, such as vaporization, condensation, extraction, separation, sensing, electrochemical reactions, etc. This course deals with fundamental aspects of theory and measurements for liquid interfaces.
This course is based on physical chemistry, particularly thermodynamics, in undergraduate level, and extend the physical chemistry to heterogeneous systems including interfaces. We further treat statistical mechanics, electrochemistry, spectroscopy and molecular simulation to explore the detailed structure and dynamics at liquid interfaces.
Since organic, coordination , inorganic, bio and materials chemistries all require the ability to use spectroscopy to characterize molecules. This course will provide students tools needed to interpret spectra from different spectroscopic techniques.
Since organic, coordination , inorganic, bio and materials chemistries all require the ability to use spectroscopy to characterize molecules. This course will provide students tools needed to interpret spectra from different spectroscopic techniques.
This class is offered to freshmen enrolled in the AMC course. Fundamental knowledge and cutting-edge research in chemistry and materials science will be presented in the form of seminars in each laboratory. Throughout these seminars, the differences in high school-level and college-level chemistry will be emphasized, and students will be given motivation for their future studies.
This class is offered to freshmen enrolled in the AMC course. Fundamental knowledge and cutting-edge research in chemistry and materials science will be presented in the form of seminars in each laboratory. Throughout these seminars, the differences in high school-level and college-level chemistry will be emphasized, and students will be given motivation for their future studies.