FACULTY OF ENGINEERING
CHEMICAL ENGINEERING
Course Name   Nanochemistry and Applications
Semester Course Code Theoretical / Practice time ECTS
5 1216522 2 / 0 5
Course Degree Bachelor's degree
Course Language Turkish
Format of Delivery: Face to Face
Course Coordinator Assist. Prof. Dr. Serpil EDEBALi
Coordinator e-mail serpilcetin gmail.com
Instructors
Asistant Instructors
Course Objectives
Basic Sciences Engineering Scinces Social Sciences Educational Sciences Artistic sciences Medical Science Agricultural sciences
40 60 0 0 0 0 0
Course Learning Methods and Techniquies
The lectures will be performed in a classroom via deions of subjects, homework and discussions.
Week Course Content Resource
1 Introduction to nanochemistry Geoffrey A Ozin Andre´ C Arsenault Ludovico Cademartiri, Nanochemistry : a chemical approach to nanomaterials, 2009. Jonathan W. Steed, David R. Turner, Karl J. Wallace, Core Concepts in Supramolecular Chemistry and Nanochemistry, 2007
2 Nanomanipulation Geoffrey A Ozin Andre´ C Arsenault Ludovico Cademartiri, Nanochemistry : a chemical approach to nanomaterials, 2009. Jonathan W. Steed, David R. Turner, Karl J. Wallace, Core Concepts in Supramolecular Chemistry and Nanochemistry, 2007
3 Molecular devices Geoffrey A Ozin Andre´ C Arsenault Ludovico Cademartiri, Nanochemistry : a chemical approach to nanomaterials, 2009. Jonathan W. Steed, David R. Turner, Karl J. Wallace, Core Concepts in Supramolecular Chemistry and Nanochemistry, 2007
4 Self-assembled monolayers Geoffrey A Ozin Andre´ C Arsenault Ludovico Cademartiri, Nanochemistry : a chemical approach to nanomaterials, 2009. Jonathan W. Steed, David R. Turner, Karl J. Wallace, Core Concepts in Supramolecular Chemistry and Nanochemistry, 2007
5 Soft-litography Geoffrey A Ozin Andre´ C Arsenault Ludovico Cademartiri, Nanochemistry : a chemical approach to nanomaterials, 2009. Jonathan W. Steed, David R. Turner, Karl J. Wallace, Core Concepts in Supramolecular Chemistry and Nanochemistry, 2007
6 Nanoparticles Geoffrey A Ozin Andre´ C Arsenault Ludovico Cademartiri, Nanochemistry : a chemical approach to nanomaterials, 2009. Jonathan W. Steed, David R. Turner, Karl J. Wallace, Core Concepts in Supramolecular Chemistry and Nanochemistry, 2007
7 Bottom-up and up-bottom approaches Geoffrey A Ozin Andre´ C Arsenault Ludovico Cademartiri, Nanochemistry : a chemical approach to nanomaterials, 2009. Jonathan W. Steed, David R. Turner, Karl J. Wallace, Core Concepts in Supramolecular Chemistry and Nanochemistry, 2007
8 Fullerens and carbon nanotubes Geoffrey A Ozin Andre´ C Arsenault Ludovico Cademartiri, Nanochemistry : a chemical approach to nanomaterials, 2009. Jonathan W. Steed, David R. Turner, Karl J. Wallace, Core Concepts in Supramolecular Chemistry and Nanochemistry, 2007
9 Dendrimers Geoffrey A Ozin Andre´ C Arsenault Ludovico Cademartiri, Nanochemistry : a chemical approach to nanomaterials, 2009. Jonathan W. Steed, David R. Turner, Karl J. Wallace, Core Concepts in Supramolecular Chemistry and Nanochemistry, 2007
10 Mid-term
11 Fibers, gels and polymers Geoffrey A Ozin Andre´ C Arsenault Ludovico Cademartiri, Nanochemistry : a chemical approach to nanomaterials, 2009. Jonathan W. Steed, David R. Turner, Karl J. Wallace, Core Concepts in Supramolecular Chemistry and Nanochemistry, 2007
12 Nanobiology and biomimetics chemistry Geoffrey A Ozin Andre´ C Arsenault Ludovico Cademartiri, Nanochemistry : a chemical approach to nanomaterials, 2009. Jonathan W. Steed, David R. Turner, Karl J. Wallace, Core Concepts in Supramolecular Chemistry and Nanochemistry, 2007
13 Risks about nanochemistry Geoffrey A Ozin Andre´ C Arsenault Ludovico Cademartiri, Nanochemistry : a chemical approach to nanomaterials, 2009. Jonathan W. Steed, David R. Turner, Karl J. Wallace, Core Concepts in Supramolecular Chemistry and Nanochemistry, 2007
14 Developments of nanochemistry in the future Geoffrey A Ozin Andre´ C Arsenault Ludovico Cademartiri, Nanochemistry : a chemical approach to nanomaterials, 2009. Jonathan W. Steed, David R. Turner, Karl J. Wallace, Core Concepts in Supramolecular Chemistry and Nanochemistry, 2007
15 Final
Assesment Criteria   Mid-term exam Final exam
  Quantity Percentage Quantity Percentage  
Term Studies : - -
Attendance / Participation : - -
Practical Exam : - -
Special Course Exam : - -
Quiz : - -
Homework : - -
Presentations and Seminars : - -
Projects : - -
Workshop / Laboratory Applications : - -
Case studies : - -
Field Studies : - -
Clinical Studies : - -
Other Studies : - -
Mid-term exam   1 30
Final exam   1 70
ECTS WORK LOAD TABLE   Number Duration
Course Duration : 15 2
Classroom Work Time : - -
Presentations and Seminars : 1 5
Course Internship : 1 3
Workshop / Laboratory Applications : - -
Field Studies : - -
Case studies : - -
Projects : 13 3
Homework : 4 5
Quiz : 2 4
Mid-term exam : 1 20
Final Exam : 1 25
ECTS 5
No COURSE LEARNING OUTCOMES CONTRIBUTION
D.Ö.Ç. 1 1. The student identifies the particles at nanoscale and their effects. 4
D.Ö.Ç. 2 2.The student understands the difference between nanochemsitry and solid state chemistry. 3
D.Ö.Ç. 3 3.The student understands basic of nanoparticle preparation and modification. 4
D.Ö.Ç. 4 4. The student covers functionalization and its performing. 4
D.Ö.Ç. 5 5.The student learns examples for nanochemistry applications and advantages. 3
D.Ö.Ç. 6 6.The student gets information about fullerens and carbon nanotubes. 3
D.Ö.Ç. 7 7.The student learns dendrimers, fibers and gels. 4
D.Ö.Ç. 8 8.The student forms a relationship between nanoscience and biological systems. 4
D.Ö.Ç. 9 9.The student recognizes the risks of nanochemistry. 4
D.Ö.Ç. 10 10.The student gets information for future developments of nanochemistry. 4
* 1: Zayıf - 2: Orta - 3: İyi - 4: Çok İyi
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