Module de 4 jours sur le terrain avec des aspects de la sédimentologie carbonatée et clastique, analyses de provenance, déformation synsédimentaire, qualité de réservoir et évolution paléogéographique. Il faut étudier l’évolution du bassin, des environnements de dépôts, et la géologie structurale dans le contexte de la géologie régionale alpine. Physics, Engineering, Earth and Environmental Sciences and Mechanics Department (UFR PhITEM) Grenoble – Saint-Martin d’Hères IFXZWWRX 3 2nd year of master Lecture Course content can evolve at any time before the start of the course. It is strongly recommended to discuss with the course contact about the detailed program.

Please consider the following deadlines for inbound mobility to Grenoble:
– April 1st, 2020 for Full Year (September to June) and Fall Semester (September to January) intake ;
– September 1st, 2020 for Spring Semester intake (February – June). Dounia MOUKADEM / Thi Phuong POURTIER
phitem-international@univ-grenoble-alpes.fr

This course deals with neutron scattering and physics of synchrotron radiation. It is composed of 3 parts: – Description of the technical aspects, neutron sources and instrumentation. Examples from fundamental physiology to crystalline material are given. – Theory of diffusion of non-relativistic particles for the interpretation of experimental data – Synchrotron radiation *The city of Grenoble hosts large-scale facilities, especially one of the European Synchrotron Radiation Facilities Physics, Engineering, Earth and Environmental Sciences and Mechanics Department (UFR PhITEM) Grenoble – Domaine universitaire IGMBO5DA 3 2nd year of master Lecture Course content can evolve at any time before the start of the course. It is strongly recommended to discuss with the course contact about the detailed program.

Please consider the following deadlines for inbound mobility to Grenoble:
– April 1st, 2020 for Full Year (September to June) and Fall Semester (September to January) intake ;
– September 1st, 2020 for Spring Semester intake (February – June). Dounia MOUKADEM / Thi Phuong POURTIER
phitem-international@univ-grenoble-alpes.fr

Goal: Mechanics plays a forefront role at the nanoscale, from the generation of nano-structures by growth instabilities to the properties of nano-composite materials, the design of micro and nano-mechanical devices, the nano-imaging techniques, the control of biologic functions. This course introduces the mechanics of continuous media and its main applications to nanosciences and nano-technologies. Content: – Simple deformations, definition of elastic modulii E, G, K, nu – Flexion of beams, static, dynamics and waves. Example: the AFM cantilever. – 3D linear elasticity of isotropic media: strain tensor ; elasticity as a field theory (expression of the free energy) ; stress tensor ; general equilibrium equation – elastic instabilities in thin films – elasticity of membranes, ADN coil. Physics, Engineering, Earth and Environmental Sciences and Mechanics Department (UFR PhITEM) IGW869LX 3 1st year of master Lecture Course content can evolve at any time before the start of the course. It is strongly recommended to discuss with the course contact about the detailed program.

Please consider the following deadlines for inbound mobility to Grenoble:
– April 1st, 2020 for Full Year (September to June) and Fall Semester (September to January) intake ;
– September 1st, 2020 for Spring Semester intake (February – June). Dounia MOUKADEM / Thi Phuong POURTIER
phitem-international@univ-grenoble-alpes.fr

Goal: Introduction to local probe techniques in Nanosciences. Part 1: Scanning Tunneling Microscopy and its applications, near-field microscopies instrumentation Chapter 1: Scanning Tunneling Microscopy Refresher on the free electron model in a metal, including the work-function basis. Basics on electron tunneling though a square barrier. Field emission in the framework of the WKB approximation. Microscopic model of tunneling. Expression of the tunnel current as a function of the density of states and electronic distribution function. General description of STM. Chapter 2: Instrumentation for Scanning Probe Microscopy Chapter 3: STM imaging of surfaces Chapter 4: Scanning tunneling spectroscopy of nano-objects and nanostructures Principles of local spectroscopy and spectroscopic imaging Chapter 5: Nanomanipulation Chapter 6: New local probes. Combined AFM-STM Part 2: Atomic Force Microscopy and related techniques Chapter 1: Principles of AFM Chapter 2: Imaging modes Chapter 3: Spectroscopy mode. Force curves and related interaction measurements, Force mapping Chapter 4: Introduction to Electric Force Microscopy Chapter 5: AFM as a local tool Physics, Engineering, Earth and Environmental Sciences and Mechanics Department (UFR PhITEM) Grenoble – Domaine universitaire IGM9PK7A 3 1st year of master Lecture Course content can evolve at any time before the start of the course. It is strongly recommended to discuss with the course contact about the detailed program.

Please consider the following deadlines for inbound mobility to Grenoble:
– April 1st, 2020 for Full Year (September to June) and Fall Semester (September to January) intake ;
– September 1st, 2020 for Spring Semester intake (February – June). Dounia MOUKADEM / Thi Phuong POURTIER
phitem-international@univ-grenoble-alpes.fr

This first part of the course is dedicated on the theory and implementation of the finite element method for solving boundary value problems in solid mechanics: Overview of the finite element method in solid mechanics, the Finite Element Method for Static Linear Elasticity, The finite element method for time dependent and dynamic problems. Physics, Engineering, Earth and Environmental Sciences and Mechanics Department (UFR PhITEM) Grenoble – Domaine universitaire IGRY9H26 3 1st year of master Lecture Course content can evolve at any time before the start of the course. It is strongly recommended to discuss with the course contact about the detailed program.

Please consider the following deadlines for inbound mobility to Grenoble:
– April 1st, 2020 for Full Year (September to June) and Fall Semester (September to January) intake ;
– September 1st, 2020 for Spring Semester intake (February – June). Dounia MOUKADEM / Thi Phuong POURTIER
phitem-international@univ-grenoble-alpes.fr

The new discipline of cheminformatics covers the application of computer-

assisted methods to chemical problems such as information storage and

retrieval, the prediction of physical, chemical or biological properties of

compounds, spectra simulation, structure elucidation, reaction modeling,

synthesis planning and drug design. This class provides an introduction to the

representation of molecular structures and reactions, data types and

databases/data sources, search methods, methods for data analysis as well as

such applications as structure elucidation, reaction simulation, synthesis

planning and drug design.

* Basic chemistry for cheminformatics, representation of the chemical

structure, chemical nomenclature, elements, and formulas of compounds to

chemical structure fingerprints

* Chemical data, from 2D to 3D structure, structure comparison

* Chemical reactions,

* Calculation of physical chemical properties of compounds,

* Calculation of structure descriptors

* Methods for data analysis, and applications in computer-aided drug design,

spectra analysis, molecular modeling, simulation

College of Electrical Engineering & Computer Science Main Campus Tseng Y. Jane 50 Wednesday 6,7,8 CSIE5730 3 Half Graduate Institute of Computer Science & Information Engineering,
Graduate Institute of Biomedical Electronics and Bioinfornatics,
Energy Technology Program
http://www.csie.ntu.edu.tw/main.php?lang=en

LECTURE TOPICS

I. Soil Chemistry Overview and Problem Solving

II. Soil Matrix Composition

III. Chemical Processes Affecting Strongly Bound Soil Elements

– Aqueous complexation

– Precipitation and Dissolution

– Adsorption _ Macroscopic and Molecular Models

VI. Systematic Application of Soil Chemistry to Problem Solving

Course Objectives: (1) To gain awareness of the complexity of soils and soil components, and soil chemical processes that affect strongly bound nutrients and contaminants; (2) To develop skills in applying soil chemistry toward solving environmental and agricultural problems; and (3) To relate molecular-scale soil chemical properties and processes to macroscale behavior of soil contaminants and plant nutrients. College of Bio-Resources & Agriculture Main Campus Zeng-Yei Hseu 42 Monday X,A,B Wednesday X,A,B Friday X,A,B AC5068 1 Half Graduate Institute of Agricultural Chemistry http://www.ac.ntu.edu.tw/?locale=en

We have many international students in National Taiwan University. To fulfill the needs of international students of English courses, the College of Bio-resources and Agriculture opens a course “Exploring Taiwan ? Natural Environmental and Resources”, which is taught in English. The instructors of this course are all the best of Taiwan in their fields, including atmospheric science, environment science, physical and social geography. They will help students to learn more about the beautiful nature of Taiwan. It will give international students a wide range of background knowledge, increasing their understanding of Taiwan and enabling them to take advanced courses lectured in Chinese or partake in research in the future. College of Bio-Resources & Agriculture Main Campus Hsiao Wei Yuan 75 Wednesday 8,9 Forest5035 2 Half School of Forestry and Resource Conservation,
Program in Taiwan Studies http://www.fo.ntu.edu.tw/main.php?lang=en&Trad2Simp=n

The discovery of superconductor in 1911 can be marked as the inception of contemporary solid state physics. The quest for understanding the mechanism behind superconductivity lasted for decades, until the BCS theory finally arrived in 1957. However, the endeavor to discover high-Tc superconductor continued till today. The rich variations of novel solid state materials also emerged during the past 50 years, with the advancement of materials growth technology. In this course, we will start from some advanced languages of solid state physics such as second quantization and Hubbard model, then discuss several materials systems using these new tools.

(0) Quick review of basic solid state physics

(1) Second quantization of fermions

(2) Electron-electron interaction

(3) Hubbard model

(4) Mott insulator and localization

(5) Second quantization of bosons

(6) Electron-phonon interaction

(7) Bose-Einstein condensation

(8) Superconductor

(9) BCS theory

(10) Mesoscopic transport

(11) Quantum Hall effect

College of Social Engineering Main Campus Chi-Feng Pai 40 Wednesday 2,3,4 MSE5053 3 Half Department of Materials Science and Engineering,
Graduate Institute of Materials Science and Engineering http://www.mse.ntu.edu.tw/index.php?lang=en

1. Introduction and basic math (3 hrs)

(1) Introduction

(2) Scalars, vectors, and tensors

2. Kinematics (6 hrs)

(1) Lagrangian vs. Eulerian specifications, material derivatives

(2) Streamline, path line, and streak line

(3) Strain rate

(4) Vorticity and circulation

3. Conservation law (12 hrs)

(1) Reynolds transport theorem

(2) Conservation of mass, scalar, and heat

(3) Conservation of momentum: Navier-Stokes equation, viscous vs. inviscid flows

(4) Bernoulli equation

4. Vorticity dynamics (6 hrs)

(1) Kelvin’s circulation theorem

(2) Helmholtz vortex theorems

(3) Vorticity transport equation

5. Potential flow (6 hrs)

(1) Fundamentals and examples

(2) Conformal mapping

6. Laminar flow (8 hrs)

(1) Examples of steady flows

(2) Stokes’ first problem and similarity solution

The course aims to provide students a solid background of fluid mechanics required for related

research works.
College of Social Engineering Main Campus Yi-Ju Chou 98 Monday 2 Thursday 3,4 AM7097 3 Half Graduate Institute of Applied Mechanics http://www.iam.ntu.edu.tw/English/EN-homepage/homepage-Frameset.htm

This course is an integration of undergraduate chemical engineering core courses for process design. This course is divided into two parts: (1) the combined lectures for basic design principles, and (2) team design practice under the guidance of 5 to 7 professors. College of Social Engineering Main Campus *Prerequisite: Chemical Engineering Process Design Jeffrey Daniel Ward 17 Thursday 6,7 ChemE4015 2 Half Department of Chemical Engineering http://www.che.ntu.edu.tw/che/?lang=en

The rapid decline of coral reefs around the world motivates research to better understand how this complex ecosystem will respond to future environmental changes. This course will review current knowledge on reef organisms and coral reef ecosystem, and will study the factors responsible for reef degradation. The basic elements to assess resilience of this ecosystem will be introduced. The students will learn how the knowledge and skills obtained through the lectures and practice work can be used for the management and the conservation of this fragile ecosystem. College of Science Main Campus Vianney Denis 15 Tuesday 6,7,8 Ocean5097 3 Half Graduate Institute of Oceanography, Marine Biology & Fisheries Division http://www.oc.ntu.edu.tw/?lang=en