• Turkish
  • English
Ders Kodu: 
MSN 118
Ders Tipi: 
Alan Seçmeli
Teori Saati: 
3
Uygulama Saati: 
0
Laboratuvar Saati: 
0
Kredi: 
3
AKTS: 
5
Dersin Dili: 
İngilizce
Dersin Amacı: 
Understanding the science behind the phenomena that arise when considering materials at the nanoscale.
Dersin İçeriği: 

An introduction to nano-engineering, types of nanoparticles, use of nanoparticles in various platforms including drug delivery systems, functional materials, diagnostics and biomaterials.

Dersin Öğretim Yöntemleri: 
1: Lecture by instructor, 2: Lecture by instructor with class discussion, 3: Problem solving by instructor, 4: Use of simulations, 5: Problem solving assignment, 6: Reading assignment, 8: Term research paper, 9: Presentation by guest speaker, 10: Sample P
Dersin Ölçme Yöntemleri: 
A: Written exam, B: Multiple-choice exam C: Take-home quiz, D: Experiment report, E: Homework, F: Project, G: Presentation by student, H: …

Dikey Sekmeler

Dersin Öğrenme Çıktıları

Course Learning Outcomes Detailed Program Outcomes Teaching Methods Assessment Methods
Ability to describe corrosion and wear protection, and various functionalities obtainable by coatings and surface treatments. 1a,1b,4a,9b 1, 2 A, E
Ability to describe surface coating methods. 1b, 9b 1, 2 A, E, G
Ability to describe heat treatment methods. 1b, 9b 1, 2  A, E, G
Ability to describe surface characterization 1b, 9b 1 A, E
Ability to write effective reports and, make presentation    6a, 6b,7c,7d 8,11 F, G
Ability to work efficiently in multi-disciplinary teams 6a, 6b,7c,7d 8,11 F, G

Dersin Akışı

COURSE CONTENT
Week Topics Study Materials
1 Introduction, general information on Nanoscience and Engineering, syllabus Lecture Notes
2 Exploring Nanoworld,  a brief intro to Quantum Physics, Schrodinger equation in one dimension, two dimension and three dimension Lecture Notes
3 Superposition and interference of quantumwaves, Energy eigenstates Lecture Notes
4 Distribution functions and density of states, calculation the total number of occupied states for a given system, electron transport in nanostructures Lecture Notes
5 Seeing and moving atoms, the basic principle of the STM and AFM Lecture Notes
6 Nanomaterials I, Nanostructured materials Lecture Notes
7 Midterm I  
8 Nanomaterials II, New forms of Carbon Lecture Notes
9 Functional Materials Lecture Notes
10 From Microelectronics to Nanoelectronics, Emerging Quantum Devices Lecture Notes
11 Midterm II Lecture Notes
12 Therapeutics and regenerative medicine  
13 Drug Delivery Systems, Biomimetics Lecture Notes
14 Final Lecture Notes

Kaynaklar

RECOMMENDED SOURCES
Textbook Lecture notes and suggested books
Additional Resources
  • Nanotechnology in a Nutshell: From Simple to Complex Systems 2014th Edition, Christian Ngô, Marcel Van de Voorde
  • Introduction to nanotechnology, Henrik Bruus, Department of Micro and Nanotechnology Technical University of Denmark, 2004.

 

Materyal Paylaşımı

MATERIAL SHARING
Documents Textbook and lecture notes
Assignments Quizzes, Homeworks, Term Project and Case studies
Exams Exams and solutions (excluding the Final Exam)

Değerlendirme Sistemi

ASSESSMENT
IN-TERM STUDIES NUMBER PERCENTAGE
Mid-Terms 2 30
Homework 3 30
Quiz 0 0
Case Study Presentations 0 0
Term Project 0 0
Final  1 40
Total   100
CONTRIBUTION OF FINAL EXAMINATION TO OVERALL GRADE   40
CONTRIBUTION OF IN-TERM STUDIES TO OVERALL GRADE   60
Total   100

Dersin Program Çıktılarına Katkısı

COURSE'S CONTRIBUTION TO PROGRAM OUTCOMES 
No Program Learning Outcomes check    √ 
1a Adequate knowledge in mathematics, science and engineering subjects pertaining to the relevant discipline, 
1b Ability to use theoretical and applied knowledge in these areas in complex engineering problems.
2a Ability to identify, formulate, and solve complex engineering problems,  
2b Ability to select and apply proper analysis and modeling methods for this purpose.  
3a Ability to design a complex system, process, device or product under realistic constraints and conditions, in such a way as to meet the desired result,  
3b Ability to apply modern design methods for this purpose.  
4a Ability to devise, select and use modern techniques and tools needed for analyzing and solving complex problems encountered in engineering practice. 
4b Ability to employ information technologies effectively.  
5a Ability to design experiments for investigating complex engineering problems or discipline specific research questions,   
5b Ability to conduct experiments, gather data, analyze and interpret results for investigating complex engineering problems or discipline specific research questions.  
6a Ability to work efficiently in intra-disciplinary teams, 
6b Ability to work efficiently in multi-disciplinary teams,
6c Ability to work individually.   
7a Ability to communicate effectively in Turkish, both orally and in writing,  
7b Knowledge of a minimum of one foreign language,   
7c Ability to write effective reports and comprehend written reports, 
prepare design and production reports, 
7d Ability to make effective presentations,
7e Ability to give and receive clear and intelligible instructions.   
8a Recognition of the need for lifelong learning, ability to access information, ability to follow developments in science and technology,   
8b Ability to continue to educate him/herself.  
9a Consciousness to behave according to ethical principles and professional and ethical responsibility.   
9b Knowledge on standards used in engineering practice.
10a Knowledge about business life practices such as project management, risk management, change management.   
10b Awareness in entrepreneurship and innovation.   
10c Knowledge about sustainable development.  
11a Knowledge about the global and social effects of engineering practices on health, environment, and safety,  
11b Knowledge about contemporary issues of the century reflected into the field of engineering.  
11c Awareness of the legal consequences of engineering solutions.   

ECTS

ECTS ALLOCATED BASED ON STUDENT WORKLOAD BY THE COURSE DESCRIPTION
Activities Quantity Duration
(Hour)
Total
Workload
(Hour)
Course Duration  13 3 39
Hours for off-the-classroom study (Pre-study, practice) 13 3 39
Midterm examination 2 4 8
Homework 3 5 15
Case Studies 2 5 10
Project 1 40 40
Final examination 1 2 2
Total Work Load     153
Total Work Load / 25 (h)     6.12
ECTS Credit of the Course     6