The aim of studying and bibliography

The main aim of study: Aquiring knowledge on the basic physicochemical description of polymers, required for understanding properties of polymers and polymeric materials as well as methods of their analysis and characterization

The general information about the module: The modulus provides information on physicochemical properties of polymers and polymeric materials

Teaching materials: Przeźrocza do wykładu

Bibliography required to complete the module

Bibliography used during lectures

1	H. Galina	Fizykochemia polimerów	Oficyna Wodawnicza Politechniki Rzeszowskiej.	1998
2	H. Galina (pod red.)	Fizyka materiałów polimerowych. Makrocząsteczki i ich układy	WNT Warszawa .	2008

Bibliography used during classes/laboratories/others

1

E. Hałasa, A. Żmihorska-Gotfryd

Chemia fizyczna polimerów. Laboratorium

Wyd. Polit. Rzeszowskiej, Rzeszów.

1990

Basic requirements in category knowledge/skills/social competences

Formal requirements: Completed modulus on physical chemistry

Basic requirements in category knowledge: Knowledge of principles of physical chemistry, including thermodynamics. Recommended knowledge on polymer chemistry and technology

Basic requirements in category skills: Has a laboratory skill in instrumental analysis

Basic requirements in category social competences: Capable of working in team. Knows safety and fire protection regulations in chemical laboratory

Module outcomes

MEK	The student who completed the module	Types of classes / teaching methods leading to achieving a given outcome of teaching	Methods of verifying every mentioned outcome of teaching	Relationships with KEK	Relationships with PRK
01	Have an extended knowledge on the physical properties of polymers, both in condensed state and in solution	lacture, laboratory	written and oral test, visual monitoring, written report	K_W10+++	P7S_WG
02	Has a well grounded and broaden knowlkedge on properties and methods of interpretation of polymer behaviour	lecture, laboratory	written and oral test, oral verifications, written report.	K_W12++	P7S_WG
03	Gained knowledge on analysis and solving research problems related to interpretation of results on properties of polymers and polymeric materials	lecture, laboratory	oral and written test, written report	K_U09++ K_U12++	P7S_UO P7S_UW
04	While identifying and solving research problems is capable of integrating the knowledge in chemistry, physics, physical chemistry and specialized subjects.	lecture, laboratory	oral and written test, knowledge verification	K_U11+++	P7S_UW
05	Understands the need of broadening the knowledge on new facts relating structure with properties in polymer science	lecture	skill observation	K_K01++	P7S_KK
06	Has the ability to work in a team for efficient performing of tasks in polymer science	laboratory	skill observation	K_K02+	P7S_KO

Attention: Depending on the epidemic situation, verification of the achieved learning outcomes specified in the study program, in particular credits and examinations at the end of specific classes, can be implemented remotely (real-time meetings).

The syllabus of the module

Sem.	TK	The content	realized in	MEK
2	TK01	Specific, physical properties of polymers and polymer systems	W01	MEK01
2	TK02	Relations concerning molecular mass distributions and linking mechanisms of polymer synthesis and the type of molecular mass distribution	W01, W02, L01	MEK03
2	TK03	Sizes of makromolecules in solutions and in bulk, properties of polymer solutions and blends	W03, W04, L02	MEK01 MEK05
2	TK04	Hydrodynamics of polymer solutions	W05, L02	MEK03
2	TK05	Elements of polymer viscoelasticity, rheological models	W06, W07, L07	MEK04
2	TK06	Moduli-temperature relationships; glass transition, polymer structure vs. glass transition temperature	W08, W09, L05	MEK02 MEK03
2	TK07	Rubber elasticity	W10, L03	MEK02 MEK05
2	TK08	Polymer in viscoelastic region, effect of entanglements, reptation model of stress relaxation	W11, L07	MEK02 MEK04
2	TK09	Crystalline state of polymers	W12, L04	MEK04 MEK05 MEK06
2	TK10	Specialty polymer, liquid crystallinity and polymers	W13, W14	MEK05
2	TK11	Surface properties of polymers	W15	MEK04 MEK06

The student's effort

The type of classes	The work before classes	The participation in classes	The work after classes
Lecture (sem. 2)		contact hours: 30.00 hours/sem.	complementing/reading through notes: 5.00 hours/sem. Others: 1.00 hours/sem.
Laboratory (sem. 2)	The preparation for a Laboratory: 5.00 hours/sem. The preparation for a test: 10.00 hours/sem.	contact hours: 45.00 hours/sem.	Finishing/Making the report: 5.00 hours/sem.
Advice (sem. 2)		The participation in Advice: 2.00 hours/sem.
Exam (sem. 2)	The preparation for an Exam: 30.00 hours/sem.	The written exam: 1.00 hours/sem. Others: 5.00 hours/sem.

The way of giving the component module grades and the final grade

The type of classes	The way of giving the final grade
Lecture	Positive mark of the written exam in the form of a test - W1. The grading scale is provided on the examination sheet. The evaluation depends on the percentage obtained as follows: 50,1-60%: 3.0 60,1-70%: 3.5 70,1-80%: 4.0 80,1-90%: 4.5 90,1-100%: 5.0 The mark from the second term - 0.9 of the mark obtained.
Laboratory	Student must perform all of the planed experiments, prepare and pass written reports, pass tests from theoretical information connected with laboratory lessons. Average mark from test, written report from each exercise – W2. Weighting factor: w = 1,0 first term, w = 0,9 second term.
The final grade	Final mark: W = w 0,5 W1 + w 0,5 W2; w - weighting factor: w = 1,0 first term, w = 0,9 second term.

Sample problems

Required during the exam/when receiving the credit
(-)

Realized during classes/laboratories/projects
(-)

Others
(-)

Can a student use any teaching aids during the exam/when receiving the credit : no

The contents of the module are associated with the research profile: yes

1	J. Bieniaś; Ł. Byczyński; D. Czachor-Jadacka; M. Droździel-Jurkiewic; M. Kisiel; B. Mossety-Leszczak; G. Pietruszewska; M. Włodarska; W. Zając	Nonterminal liquid crystalline epoxy resins as structurally ordered low Tg thermosets with potential as smart polymers	2024
2	K. Awsiuk; N. Janiszewska; B. Mossety-Leszczak; J. Raczkowska; A. Strachota; B. Strachota; M. Walczak; A. Zioło	Synthesis and Morphology Characteristics of New Highly Branched Polycaprolactone PCL	2024
3	M. Kisiel; B. Mossety-Leszczak	The Effect of Nonterminal Liquid Crystalline Epoxy Resin Structure and Curing Agents on the Glass Transition of Polymer Networks	2024
4	M. Kisiel; B. Mossety-Leszczak; L. Okrasa; M. Włodarska	Modification of the Dielectric and Thermal Properties of Organic Frameworks Based on Nonterminal Epoxy Liquid Crystal with Silicon Dioxide and Titanium Dioxide	2024
5	M. Kisiel; B. Mossety-Leszczak; W. Zając	Advancements in The Cross-Linking and Morphology of Liquid Crystals	2024
6	Ł. Byczyński; D. Czachor-Jadacka; M. Kisiel; B. Mossety-Leszczak; B. Pilch-Pitera; K. Pojnar; M. Walczak; J. Wojturska	Poliuretanowy lakier proszkowy oraz sposób wytwarzania poliuretanowego lakieru proszkowego	2024
7	Ł. Byczyński; E. Ciszkowicz; D. Czachor-Jadacka; M. Kisiel; B. Mossety-Leszczak; B. Pilch-Pitera; M. Walczak; J. Wojturska	Wodna dyspersja kationomerów uretanowo-akrylowych, sposób wytwarzania wodnej dyspersji kationomerów uretanowo-akrylowych oraz sposób wytwarzania fotoutwardzalnej powłoki z wykorzystaniem tej wodnej dyspersji	2024
8	M. Kisiel; B. Mossety-Leszczak; L. Okrasa; M. Włodarska; W. Zając	Changes in molecular relaxations and network properties of a triaromatic liquid crystal epoxy resin with nonterminal functional groups	2023
9	J. Karaś; M. Kisiel; B. Mossety-Leszczak; B. Pilch-Pitera; M. Włodarska; W. Zając	The application of liquid crystalline epoxy resin for forming hybrid powder coatings	2022
10	K. Byś; J. Hodan; B. Mossety-Leszczak; E. Pavlova; A. Strachota; B. Strachota	Self-Healing and Super-Elastomeric PolyMEA-co-SMA Nanocomposites Crosslinked by Clay Platelets	2022
11	M. Kisiel; B. Mossety-Leszczak	Liquid Crystalline Polymers	2022
12	B. Mossety-Leszczak; M. Włodarska	DFT Studies of Selected Epoxies with Mesogenic Units–Impact of Molecular Structure on Electro-Optical Response	2021
13	K. Byś; B. Mossety-Leszczak; E. Pavlova; M. Steinhart; A. Strachota; B. Strachota; W. Zając	Novel Tough and Transparent Ultra-Extensible Nanocomposite Elastomers Based on Poly(2-methoxyethylacrylate) and Their Switching between Plasto-Elasticity and Viscoelasticity	2021
14	M. Kisiel; B. Mossety-Leszczak; A. Strachota; B. Strachota	Achieving structural anisotropy of liquid crystalline epoxy by manipulation with crosslinking parameters	2021
15	M. Kisiel; B. Mossety-Leszczak	Development in liquid crystalline epoxy resins and composites – A review	2020
16	M. Marchel; B. Mossety-Leszczak; M. Walczak	Maize (Zea mays) reaction in response to rubber rag additive into the soil	2020
17	S. Horodecka; D. Kaňková; B. Mossety-Leszczak; M. Netopilík; M. Šlouf; A. Strachota; B. Strachota; M. Vyroubalová; Z. Walterová; A. Zhigunov	Low-Temperature Meltable Elastomers Based on Linear Polydimethylsiloxane Chains Alpha, Omega-Terminated with Mesogenic Groups as Physical Crosslinkers: A Passive Smart Material with Potential as Viscoelastic Coupling. Part I: Synthesis and Phase Behavior	2020
18	S. Horodecka; D. Kaňková; B. Mossety-Leszczak; M. Netopilík; M. Šlouf; A. Strachota; M. Vyroubalová; A. Zhigunov	Meltable copolymeric elastomers based on polydimethylsiloxane with multiplets of pendant liquid-crystalline groups as physical crosslinker: A self-healing structural material with a potential for smart applications.	2020
19	S. Horodecka; M. Kisiel; B. Mossety-Leszczak; M. Šlouf; A. Strachota; B. Strachota	Low-Temperature-Meltable Elastomers Based on Linear Polydimethylsiloxane Chains Alpha, Omega-Terminated with Mesogenic Groups as Physical Crosslinker: A Passive Smart Material with Potential as Viscoelastic Coupling. Part II—Viscoelastic and Rheological Properties	2020
20	A. Frańczak; M. Kisiel; B. Mossety-Leszczak; D. Szczęch	Quantitative analysis of the polymeric blends	2019
21	N. Buszta; M. Kisiel; J. Lechowicz; B. Mossety-Leszczak; R. Ostatek; M. Włodarska	Analysis of curing reaction of liquid-crystalline epoxy compositions by using temperature-modulated DSC TOPEM (R)	2019