Module also offered within study programmes:
General information:
Name:
Engineering of functional materials
Course of study:
2017/2018
Code:
CIM-2-204-FM-s
Faculty of:
Materials Science and Ceramics
Study level:
Second-cycle studies
Specialty:
Functional Materials
Field of study:
Materials Science
Semester:
2
Profile of education:
Academic (A)
Lecture language:
English
Form and type of study:
Full-time studies
Course homepage:
 
Responsible teacher:
dr hab. inż. Frączek-Szczypta Aneta (afraczek@agh.edu.pl)
Academic teachers:
prof. dr hab. inż. Błażewicz Stanisław (blazew@agh.edu.pl)
dr hab. inż. Frączek-Szczypta Aneta (afraczek@agh.edu.pl)
Module summary

The aim of this course is to define the scope of this material group, taking into account the correct naming, concepts and definitions and presenting selected issues related to fabrication.

Description of learning outcomes for module
MLO code Student after module completion has the knowledge/ knows how to/is able to Connections with FLO Method of learning outcomes verification (form of completion)
Social competence
M_K001 The student is able to provide information and opinions on the modern functional materials and their applications in universally understandable way IM2A_U06, IM2A_U05 Participation in a discussion,
Scientific paper,
Presentation,
Test,
Activity during classes
Skills
M_U001 The student knows how to propose a modern functional material for the specific application and the place where commercial materials can not meet the applicable requirements. IM2A_U13, IM2A_U11, IM2A_U15 Participation in a discussion,
Scientific paper,
Presentation,
Test,
Activity during classes
Knowledge
M_W001 The student knows the polymer, metallic, ceramic and composite functional materials IM2A_W07 Participation in a discussion,
Scientific paper,
Presentation,
Test,
Activity during classes
M_W002 The student knows the methods of selection of functional material for a specific application.. IM2A_W09 Participation in a discussion,
Test,
Activity during classes
FLO matrix in relation to forms of classes
MLO code Student after module completion has the knowledge/ knows how to/is able to Form of classes
Lecture
Audit. classes
Lab. classes
Project classes
Conv. seminar
Seminar classes
Pract. classes
Zaj. terenowe
Zaj. warsztatowe
Others
E-learning
Social competence
M_K001 The student is able to provide information and opinions on the modern functional materials and their applications in universally understandable way - - - - - + - - - - -
Skills
M_U001 The student knows how to propose a modern functional material for the specific application and the place where commercial materials can not meet the applicable requirements. + - - - - + - - - - -
Knowledge
M_W001 The student knows the polymer, metallic, ceramic and composite functional materials + - - - - + - - - - -
M_W002 The student knows the methods of selection of functional material for a specific application.. - - - - - + - - - - -
Module content
Lectures:
Tematyka wykładów

1. Introduction to functional materials engineering – definitions, material classifications.
2. Nature-derived patterns in materials engineering – biomimetism in functional materials engineering, smart and multifunctional materials.
3. Conductive and electrically active polymers (EAP) in functional materials engineering – types of polymers, mechanisms of electrical conductivity, the methods of modifying the structure and properties of polymers- based functional materials.
4. Smart materials in functional materials engineering – types of smart materials (active, passive), manufacture, sensors, actuators, smart textiles, e-textiles
5. New manufacture techniques for functional material applications – electrospun fibrous nanomaterials.
6. New manufacturing techniques for functional material applications – 3D printing, Stereolithography, Selective Laser Modeling (SLA), PolyJet methods LDM Liquid Deposition Modeling (LDM), Fused Filament Fabrication (FFF).
7. Self-repairing materials – self- healing mechanisms in synthetic materials, methods for creating self- healing mechanisms of defects in functional materials.
8. Self-organizing materials- the phenomena of self-organization, the types of interactions between system components, materials types and engineering, examples of application
9. Wood as an example of functional materials – raw material types, raw material selection and engineering for wood – derived materials, properties.
10. Wood-derived functional materials – wood and cellulose-derived processing methods , processing variables, properties, applications.
11. Magnetic functional materials- metal alloys and composites- based functional materials, magnetic and magnetorheological fluids, ferromagnetic materials, processing, properties, examples of application.
12. Functional materials in renewable energy sources – economic, technological, environmental and sociological aspects in the development of renewable energy sources, current state of knowledge and outlook for the future, technological problems, economic factors.
13. Phase-change materials (PCM) in thermal energy conversion systems.
14. Functional materials for extreme environments.

Seminar classes:
Tematyka seminariów

Trends in the development of functional materials
-Introduction to engineering design. Types of the projects. Analysis of the design process. Design tools. Material functionality/materials type relationships, analysis of the shape, final product and manufacture methods.
- Basic material characteristics (mechanical, electrical, thermal, etc.). Classifications of the known functional and structural materials, evaluation criteria, e.g. specific properties, fracture energy, strain, electrical conductivity etc. Definition of the characteristic properties of particular groups of materials, i.e. polymers, metals, ceramics, composites.
- Discussion on the possibility of classifying different properties of materials using characteristic figures for materials selection, eg. Young’s modulus – Mechanical strength, Young’s modulus – density.
- Comparison of various material groups and their properties by means of the charts for materials selection in engineering design, e.g. Young’s modulus/strength, Young’s modulus/density. Practical aspects of charts for material selection in engineering design, optimal material selection, maximization of functionality of devices/products.
- Introduction into “Functionality Index”, analysis of its meaning, examples of FI for simple shapes. Procedures for selection of materials for a specific application. Criteria maximizing functionality of a material. Examples of materials selection.
-Calculation examples of Functionality Index for the elements having cylindrical shape i.e., rods, tubes, columns together with materials selection. Determination of optimal solutions using characteristic records of different materials. Computation examples of Functionality Index and material selections for the various applications, e.g. beams, mirrors of large telescopes, springs.
– Materials selection involving shape factor of the engineering design. Shape factors. Mathematical formulas involving basic shape factors of a material . Shape factor and functionality index. Shape factor for internally cross-shaped of a device. Diagrams of materials selection involving the shape factor.
- Cumputational problems related to the determination of functionality index involving shape factor. Computational tasks related to the determination of functionality index involving optimal shape of a designed material. Determining the optimum cross-sectional shape of a device. Diagrams supporting selection of appropriate methods for materials manufacturing.
-Student presentations on selected topics referring to functional materials.

Student workload (ECTS credits balance)
Student activity form Student workload
Summary student workload 120 h
Module ECTS credits 4 ECTS
Contact hours 10 h
Examination or Final test 2 h
Realization of independently performed tasks 9 h
Preparation for classes 17 h
Preparation of a report, presentation, written work, etc. 12 h
Participation in lectures 30 h
Participation in seminar classes 30 h
Participation in auditorium classes 10 h
Additional information
Method of calculating the final grade:

final mark=30% of the seminar mark (avarage marks from tests, mark from presentation) + 70% of the exam mark

Prerequisites and additional requirements:

Prerequisites and additional requirements not specified

Recommended literature and teaching resources:

1. Zhenhai Xia, Biomimetic Principles and Design of Advanced Engineering Materials, ISBN: 978-1-118-53307-9, 2016
2. Leszek L.Dobrzański- Materiały inżynierskie i projektowanie materiałowe, wyd.Naukowo- Techniczne, 2006, Wa-wa
3. Michael F.Ashby- Dobór materiałów w projektowaniu inżynierskim, Wyd.Naukowo- Techniczne,1992, Wa-wa
4. Deborah D.L.Chung, Composite Materials: Science and Applications, Functional Materials for Modern Technologies, Springer,2002
5. Ji-Huan He, et al. Electrospun Nanofibres and Their Applications. Shawbury, Shrewsbury, Shropshire, SY4 4NR, UK, 2008
6. R.Pampuch, S.Błażewicz, G.Górny, Materiały Ceramiczne dla elektroniki, Wyd.AGH, Kraków 1993
7. Debora D.L. Chung, Functional materials (Electrical, Dielectric, Electromagnetic, Optical and Magnetic Applications), World Scientific Publishing Co. Pte. LTd. 2010.
8. Thomas J.J. Muller , Uwe H.F. Bunz. Functional Organic Materials. Wiley-vch, Weinheim 2007.
9.Charles Wilkie, Georges Geuskens, Victor Manuel de Matos Lobo. Handbook of research on functional materials, CRC Press Taylor & Francis Group, 2014
10. Lectures
11. Articles: http://www.sciencedirect.com.science-direct-elsevier.wbg2.bg.agh.edu.pl/

Scientific publications of module course instructors related to the topic of the module:

Additional scientific publications not specified

Additional information:

None