课程大纲
COURSE SYLLABUS
1.
课程代码/名称
Course Code/Title
MAE5019 微纳力学
Micro and Nano Mechanics
2.
课程性质
Compulsory/Elective
专业选修课 Subject-Elective
3.
课程学分/学时
Course Credit/Hours
3/48
4.
授课语
Teaching Language
英语 English
5.
授课教
Instructor(s)
待定
6.
是否面向本科生开放
Open to undergraduates
or not
Yes
7.
先修要
Pre-requisites
MA102B 高等数学(下)A
Calculus II A
8.
教学目
Course Objectives
过去,微纳米尺度力学的研究主要源于传统力学方法的基础性兴趣。这种动机正在改变,因为微纳米物体
不再仅仅满足人们对科学的好奇心他们更是工程组件。本课程将介绍在微纳米级应用工程力学所需的
进概念和方法。具体来说1.学生将获得在微/纳米力学中进行自主学习所需的背景知识。 2.学生将能
够将基本和先进的力学概念和方法应用于纳米技术。3. 学生将会了解微纳米力学进展情况。课程将重点关
注微纳米级的技术和力学研究领域。受这一领域影响的技术包括传感器,纳米电子学,纳米光学,纳米机
器和纳米材料设计
In the past, investigations into mechanics at the micro/ nanoscale were motivated by interest in
the fundamental basis of more traditional Mechanics methods. This motivation is changing
because micro / nanoscale objects are no longer just subjects of scientific curiosity; they are
themselves engineering components. This course will introduce advanced concepts and methods
needed to apply Engineering Mechanics at the micro/nanoscale. Specifically, 1.Students will
gain the background needed to pursue independent study in Micro / nanomechanics. 2. Students
will be able to apply basic and advanced Mechanics concepts and methods to problems in
Nanotechnology.3. Students will learn the state of ongoing developments in micro/ nano
mechanics. Classes will focus on technology and mechanics research areas at micro/ nanometer
scale. Technologies impacted by this area include sensors, nanoelectronics, nanooptoelectronics,
nanomachines, and designer materials.
9.
教学方
Teaching Methods
讲授 lecture
10.
教学内
Course Contents
Section 1
Atomic force microscopy (AFM) (3hrs)
Section 2
Nanoindentation (3hrs)
Section 3
In situ SEM experimentation (3hrs)
Section 4
Advanced nanomaterials (4hrs)
Section 5
Mechanics of biomaterials (3hrs)
Section 6
Multifunctional materials (4hrs)
Section 7
Processing and manufacturing techniques (4hrs)
Section 8
Midterm exam1hrs
Section 9
Overview of experimental fracture mechanics (3hrs)
Section 10
Overview of fatigue experiments (3hrs)
Section 11
small scale polymeric, and composite materials (4hrs)
Section 12
Spectroscopic methods (4hrs)
Section 13
Characterization techniques (4hrs)
Section 14
Mechanics in emerging applications (2hrs)
Section 15
Overview of industrial applications (2hrs)
11.
课程考
Course Assessment
1 Form of examination
2 . grading policy
3
区分内容。 If the course is open to undergraduates, please indicate the difference.)
1.no final exam
2. 出勤 Attendance 10%
平时作业 Assignments 30%
期中考试 Midterm exam 30%
期末报告 Final Presentation 30%
3.There is no difference between undergraduate and graduate students.
12.
教材及其它参考资料
Textbook and Supplementary Readings
CLELAND, A N. Foundations of Nanomechanics: From Solid-State Theory to Device Applications. Berlin :
Springer Verlag, 2003. 436 p. ISBN 3-540-43661-8.
LI, S. -- WANG, G. Introduction to Micromechanics and Nanomechanics. New Jersey : World Scientific, 2008.
500 p. ISBN 978-981-281-413-5.