Physicochemistry of modern materials 0600-S1-W-FWM

Lecture:
In this lecture the student will learn the basic ways of systematizing engineering materials. They will learn basic information about the molecular structure and physical properties of metals, ceramics, glass and polymers. The lecture covers issues related to the description of the physicochemistry of phase transitions of I and II type on the example of crystalline and amorphous materials. Description of physical states of polymers, phenomenological description of the glassy state. Basic issues concerning the methods of investigating physicochemical properties of materials, especially polymers, will also be discussed.

Lab:
Provides independent implementation by the student of a number of exercises in the field of Application of the DSC method to the study of phase transitions in engineering materials. Investigation of basic physical properties such as density and moisture content of materials. Use of optical microscopy for thickness measurements of layered materials.

Total student workload

Hours with the participation of teachers: 35h including lecture: 10 hours; laboratory: 20 hours; consultation: 5 hours . 1. Time devoted to individual work of a student / student / participant of the course: 15 hours, 2. Time required to prepare for participation in the assessment process (e.g. in exams): 5 hours, Total: 55 h.

Learning outcomes - knowledge

W1: Graduate knows the classification of modern materials – K_W03 W2: Graduate knows the properties and structure of metals and ceramic materials – K_W03 W3: Graduate has knowledge of the methods of determinations of physicochemical properties of materials – K_W03 W4: Graduate knows the theoretical basis of glassy state and secondary phase transitions – K_W03 W5: Graduate knowledge about the secondary and tertiary overmolecular structures – K_W02

Learning outcomes - skills

U1: Graduate can determine the glass transition temperature from DSC plot – K_U05. U2: Graduate can determine polymer humidity by weight method – K_U05. U3: Graduate can perform measurements of physicochemical properties of materials – K_U11

Learning outcomes - social competencies

K1: Graduate can draw appropriate conclusions from the conducted experiments - K_K05 K2: Graduate can work in a group - K_K02 K3: Graduate can plan an experiment - K_K05

Teaching methods

- informative lecture - laboratory exercises

Expository teaching methods

- informative (conventional) lecture

Exploratory teaching methods

- seminar

Prerequisites

Basic knowledge of general, organic and physical chemistry

Course coordinators

Jacek Nowaczyk

Learning outcomes

W1: Graduate knows the classification of modern materials – K_W03
W2: Graduate knows the properties and structure of metals and ceramic materials – K_W03
W3: Graduate has knowledge of the methods of determinations of physicochemical properties of materials – K_W03
W4: Graduate knows the theoretical basis of glassy state and secondary phase transitions – K_W03
W5: Graduate knowledge about the secondary and tertiary overmolecular structures – K_W02

U1: Graduate can determine the glass transition temperature from DSC plot – K_U05.
U2: Graduate can determine polymer humidity by weight method – K_U05.
U3: Graduate can perform measurements of physicochemical properties of materials – K_U11

K1: Graduate can draw appropriate conclusions from the conducted experiments - K_K05
K2: Graduate can work in a group - K_K02
K3: Graduate can plan an experiment - K_K05

Assessment criteria

Written or oral examination - W01, W05,
Laboratory reports and activity – U1-U3, K1-K3
In-class activity - K01, K02 - only competences
Other – please specify:
NOTE:
Assessment methods and criteria applied for the achieved learning outcomes, specified for individual types of classes within the course, should be provided in Part B of this appendix.

Bibliography

Basic reading:
1. Leslie H. Speling; Introduction to physical polymer science; John Wiley & Sons, Inc. New York 2001.
2. Rabek J. F., Współczesna wiedza o polimerach: wybrane zagadnienia, Wydawnictwo Naukowe PWN, Warszawa 2008.
3. Broniewski T., Kapko J., Płaczek W., Thomalla J., Metody badań i ocena właściwości tworzyw sztucznych, WNT, Warszawa 2000.
4. Szlezyngier W., Tworzywa sztuczne: chemia, technologia wytwarzania, właściwości, przetwórstwo, zastosowanie, t. i 2., FOSZE, Rzeszów 1998, t. 3, FOSZE, Rzeszów 1999.
5. Przygocki W., Metody fizyczne badań polimerów, PWN, Warszawa 1990..

Additional information

Additional information (registration calendar, class conductors, localization and schedules of classes), might be available in the USOSweb system:

Description of 0600-S1-W-FWM in USOSweb