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NANO

Nano Science and Technology

NANO 5100
Chemistry of Nanomaterials
[3-0-0:3]
Previous Course Code(s)
NANO 510
Co-list with
CHEM 5540
Exclusion(s)
CHEM 4220, CHEM 5540
Description
Chemistry of materials with nano-dimensional structures and advanced functionalities. Working principles of liquid-crystalline displays and organic light-emitting diodes. High-tech applications of luminescent materials in optoelectronic systems, chemical sensors and biological probes.
Intended Learning Outcomes
On successful completion of the course, students will be able to:
- 1.
  Demonstrate an understanding of the core ideas and concepts of materials science and technology.
- 2.
  Recognize the power of chemical synthesis and materials preparation and carry out investigative research work with independent judgment.
- 3.
  Apply chemical principles to formulate and analyze analytical and synthetic problems.
- 4.
  Conduct analysis and interpretation of experimental data.
- 5.
  Communicate problem solutions using correct materials chemistry terminology and good English.
NANO 5200
Physics of Nanostructured Semiconductors
[3-0-0:3]
Previous Course Code(s)
NANO 520
Co-list with
PHYS 5810
Exclusion(s)
PHYS 5810
Description
Fundamental physics on electronic, vibrational, transport, and optical properties of semiconductors and nano-scaled solid materials based on quantum mechanics. Emphasis on nanostructured heterostructures, quantum size and low-dimensional effects, and application to modern electronics and opto-electronics.
Intended Learning Outcomes
On successful completion of the course, students will be able to:
- 1.
  Apply the fundamental knowledge from Quantum Mechanics and Solid State Physics to explain new physical phenomena and new or improved device operations that low dimensional semiconductor heterostructures can offer.
- 2.
  Explain the basic principles of common experimental methods for structural, electrical and optical characterizations of low dimensional semiconductor heterostructures.
- 3.
  Demonstrate the team work, independent learning, and scientific presentation skills.
NANO 5250
Nano Beam Technology
[3-1-0:3]
Previous Course Code(s)
NANO 525
Co-list with
PHYS 5820
Exclusion(s)
PHYS 5820
Description
Basic physical principles underlying many nano-beam techniques for fabricating and characterizing nanomaterials. Introduction to nano process, e-beam and focus ion-beam lithograph, interaction between crystalline nanomaterials and electron/ion beams. Electron beam diffraction and imaging, imaging contrast mechanism, nanostructure characterization and analytical electron microscopy.
Intended Learning Outcomes
On successful completion of the course, students will be able to:
- 1.
  Apply the fundamental knowledge from crystallography and physics to explain the phenomena of high energy electron beams in diffraction and imaging of solid materials.
- 2.
  Explain the basic principles of experimental methods for determining atomic structures, interactions between electrons and solid crystalline materials and application in nanomaterials and nanotechnology.
- 3.
  Demonstrate the independent learning, scientific presentation skills and ability to solve materials science problems.
NANO 5310
Advanced Topics in Nano Biophysical Chemistry
[2-1-0:3]
Previous Course Code(s)
NANO 531
Co-list with
LIFS 5120
Exclusion(s)
LIFS 5120
Description
This course is designed for the postgraduate students majoring in Chemistry, Biochemistry, Biology and Physics. Advanced nano-related topics such as bioinformatics, peptide design, basic and biological application of NMR, protein structure and function and techniques of biophysical chemistry, etc.
Intended Learning Outcomes
On successful completion of the course, students will be able to:
- 1.
  Understand the principals of the latest technological breakthroughs.
- 2.
  Effectively use modern technologies to answer biological questions.
- 3.
  Analyze and critique scientific papers.
- 4.
  Develop essential skills in scientific communication.
- 5.
  Prepare students for conducting innovative research.
NANO 5350
Nanomaterials for Chemical Engineering Applications
[2-1-0:3]
Previous Course Code(s)
NANO 535
Co-list with
CENG 5840
Prerequisite(s)
CENG 1500, CENG 3210, CENG 3230
Exclusion(s)
CBME 5840, CENG 4540, CENG 5840
Description
Introduction to nanostructured materials and nanotechnology. Synthesis and characterization of nanostructured materials. Selected applications of nanostructured materials in chemical engineering, such as separation and catalysis.
Intended Learning Outcomes
On successful completion of the course, students will be able to:
- 1.
  Obtain knowledge about methods for preparation of nanomaterials, ranging from single nanoparticles to three-dimensional nanostructures.
- 2.
  Demonstrate understanding for important thermodynamic and kinetic theories related to such processing.
- 3.
  Understand fundamental chemistry and physics of nanomaterial.
- 4.
  Development of analytical skill for methods of characterizing the structure and properties of nanomaterials.
- 5.
  Demonstrate the knowledge of current and emerging applications for nanomaterials.
NANO 5500
Nanocomposite Science and Technology
[3-0-0:3]
Previous Course Code(s)
NANO 550
Co-list with
MECH 5480
Exclusion(s)
MECH 5480
Description
This course is designed to provide fundamental understanding of emerging nanocomposite materials science and technology. The topical areas to discuss include synthesis of various nanoscale reinforcements, such as nanowires, nanotubes, and inorganic nanoparticles; fabrication and processing techniques of nanocomposites; dispersion of nanoreinforcements; interfacial adhesion; mechanical and functional properties of nanocomposites including gas/moisture barrier characteristics, electrical and magnetic properties, thermal properties and flame retardancy; molecular dynamic simulations; design and applications of nanocomposites.
Intended Learning Outcomes
On successful completion of the course, students will be able to:
- 1.
  Identify the advantages of nanocomposites over conventional composites.
- 2.
  List common types of nanofillers, their functionalization techniques and fabrication methods for their nanocomposites.
- 3.
  Select and implement suitable nanofillers and nanocomposite fabrication techniques to achieve good dispersion and desired properties.
- 4.
  Compare and apply different characterisation techniques for nanofillers and nanocomposites.
- 5.
  Evaluate the mechanical and functional properties of nanocomposites by correlating their properties to the structure and dispersion of nanofillers and the synthesis techniques.
- 6.
  Design nanocomposites for specific functional applications.
NANO 6010
Advanced Topics in Nano Science and Technology
[0-1-0:1]
Previous Course Code(s)
NANO 601
Description
Advanced topic series presented by the professors who are listed in the Nano PG Program and guest speakers, on most updated frontier researches in nano science and nano technology. Graded P or F.
Intended Learning Outcomes
On successful completion of the course, students will be able to:
- 1.
  Understand the major issues and acquire a comprehensive set of professional skills and knowledge in nano science and nano technology.
NANO 6100
Independent Study in Nano Science and Technology
[0-3-0:3]
Previous Course Code(s)
NANO 610
Description
An individual in-depth study of a current topic in nano science and technology under the supervision of a faculty member. For students of NANO program only. The instructor's approval is required for taking this course. Graded P or F.
Intended Learning Outcomes
On successful completion of the course, students will be able to:
- 1.
  Conduct literature review.
- 2.
  Write professional researh paper or report.
- 3.
  Obtain in-depth understanding on a specific research topic in Nano Science or Technology.
- 4.
  Explain working principles or apply experimental techniques on a research topic in Nano Science and Technology.
NANO 6990
MPhil Thesis Research
Previous Course Code(s)
NANO 699
Description
Master's thesis research supervised by a faculty member. A successful defense of the thesis leads to the grade Pass. No course credit is assigned.
Intended Learning Outcomes
On successful completion of the course, students will be able to:
- 1.
  Demonstrate research contriutions in form of a thesis.
- 2.
  Demonstrate research achievements, on knowledge in advanceing a research field in Nano Science and Technology, in the form of thesis.
- 3.
  Defend the research achievements and contributions through seminar or oral examination.
NANO 7990
Doctoral Thesis Research
Previous Course Code(s)
NANO 799
Description
Original and independent doctoral thesis research. A successful defense of the thesis leads to the grade Pass. No course credit is assigned.
Intended Learning Outcomes
On successful completion of the course, students will be able to:
- 1.
  Demonstrate research contriutions in form of a thesis.
- 2.
  Demonstrate original research achievements with impact on a research field in Nano Science and Technology, in the form of thesis.
- 3.
  Defend the research achievements and contributions through seminar or oral examination.

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