2020 Advanced Polymer Design for Energy Materials

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Academic unit or major
Graduate major in Energy Science and Engineering
Instructor(s)
Saito Reiko 
Course component(s)
Lecture
Mode of instruction
ZOOM
Day/Period(Room No.)
Fri3-4(H117)  
Group
-
Course number
ENR.H503
Credits
1
Academic year
2020
Offered quarter
1Q
Syllabus updated
2020/3/24
Lecture notes updated
-
Language used
English
Access Index

Course description and aims

This course focuses on polymers, and covers the fundamentals of energy materials and the design of effective functionality of polymers for metergy materials. Synthetic strategy of polymer emergy materials by bottom-up and top-down methods, basic theory of novel or enhanced physical properties resulted in miniaturization, and the concept of combination of materials are essential in the field of materials science to develop fine and novel functionalities. These approaches are not only useful for nanomaterials, but are applicable to design energy devices and other materials. This course introduces polymer materials used ofr lithium ion battery, , inclusion compounds and fine polymer particles as organic nanocomposite. Students will have the chance to tackle practical problems by applying knowledge acquired through this course. This course facilitates students’ understanding materials and ability to develop novel materials.

Student learning outcomes

At the end of this course, students will be able to: 1)Explain architecural control and fine polymerization of polymers for energy materials and the specific limitation and problems on the synthesis of energy materilas. 2) Explain nanomaterials. . 3) Explain specific properties and features of nanomaterials, and the difference from bulk materials. 4) Design novel materials and solve the prospective problems for the system design.

Keywords

Nanomaterials, supramolecular chemistry, polymer particles, composites. lithium ion battery, secondary battery, energy conversion materials, binder, separator

Competencies that will be developed

Specialist skills Intercultural skills Communication skills Critical thinking skills Practical and/or problem-solving skills

Class flow

Before coming to class, students should read the course schedule and check what topics will be covered. Required learning should be completed outside of the classroom for preparation and review purposes.
Attendance is taken in every class.

Course schedule/Required learning

  Course schedule Required learning
Class 1 Overview of polymerization and polymers as energy materials Explain the definition of polymerizaton and energy materials. Students must make sure they understand what significance the course holds for them by checking their learning portfolio.
Class 2 Polymer binders for lithium ion battery Understand and describe the effect of nanostructures of polymer on lithium ion battery
Class 3 polymer electrolyte and separators Understand and describe the desing concept of polymer electrolytes and separators in battery.
Class 4 Nanomaterials for energy science and enginnering Explain the concept of nanocomposites.
Class 5 Properties of polymer particles and polymer-inorganic nanoparticles Explain and describe the sysnthesis and properties of polymer-inorganic particles
Class 6 Emulsion polymerization (Smith-Ewart theory) Explain the definition of Preparation of emulsion. Nucleation of initiation on emulsion polymerization. Smith-Ewart theory. Cases 1,2, and 3.
Class 7 Synthesis of Nanocomposites Explain the definition of Synthesis of organic-silica composites with TEOS, POSS, perhydropolysilazane.

Textbook(s)

None required.

Reference books, course materials, etc.

1) P.A.Lovell, M. S. El-Aasser, "Emulsion polymerization and emulsion polymers", Wiley ISBN: 978-0-471-96746-0
2) Some materials used in class can be found on OCW-i.

Assessment criteria and methods

1) Students will be assessed on their understanding of synthesis and propertis of nanomaterials, and their ability to apply them to solve problems. 2) Students’ course scores are based on midterm and final exams (80%) and exercise problems (20%). 3) The weights for learning outcomes 1 us 40, and 2 and 3 are 30 units each. 4) Full attendance and completion of all experiments are compulsory. 5) The instructor may fail a student if he/she repeatedly comes to class late or resubmits reports too often.

Related courses

  • ENR.A405 : Interdisciplinary Energy Materials Science 1
  • ENR.A406 : Interdisciplinary Energy Materials Science 2

Prerequisites (i.e., required knowledge, skills, courses, etc.)

No prerequisites are necessary, but enrollment in the related courses is desirable.

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