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1 Polymers Macromolecule that is formed by linking of repeating units through covalent bonds in the main backbone Properties are determined by molecular.

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Presentation on theme: "1 Polymers Macromolecule that is formed by linking of repeating units through covalent bonds in the main backbone Properties are determined by molecular."— Presentation transcript:

1 1 Polymers Macromolecule that is formed by linking of repeating units through covalent bonds in the main backbone Properties are determined by molecular weight, length, backbone structure, side chains, crystallinity Resulting macromolecules have huge molecular weights

2 2 Polymers Terminology: –mer: a unit –monomer: one unit –dimer: two units –trimer: three units –tetramer: four units –polymer: many units –pre-polymer: growing towards being a polymer –oligomer: few units fixed in size –homopolymer: polymer of fixed mer type HOMOPOLYMER

3 3 Polymers Terminology (contn): –copolymer: polymers of two mer types random · · ·-B-A-B-A-B-B-A-· · · alternating· · ·-A-B-A-B-A-B-A-· · · block · · ·-A-A-A-A-B-B-B-· · · –heteropolymer: polymers of many mer types COPOLYMER

4 4 Polymers: Molecular Weight i: degree of polymerization (# of monomer units) M i = i x M m M i : molar mass of polymer molecule i M m : molecular weight of monomer Typically all chains are not equally long but display a variation –monodisperse: equal chain lengths is specific to proteins –polydisperse: unequal length specific to most synthetic molecules Therefore we need to define an “average” molecular weight –number average, M n –weight average, M w

5 5 Polymers: Molecular Weight number average, M n weight average, M w N i : # of molecules with degree of polymerization of i M i : molecular weight of i

6 6 Polymers: Molecular Weight Ratio of M w to M n is known as the polydispersity index (PI) PI is a measure of the breadth of the molecular weight PI = 1 indicates M w = M n, i.e. all molecules have equal length (monodisperse) PI = 1 is possible for natural proteins whereas synthetic polymers have 1.5 < PI < 5 At best PI = 1.1 can be attained with special techniques EXERCISE: Draw the molecular weight distribution for PI = 1, PI = 2, and PI = 4

7 7 Polymers: Molecular Weight Biomedical applications: 25,000<M n <100,000 and 50,000<M w <300,000 Increasing molecular weight increases physical properties; however, decreases processibility

8 8 Polymers Types of polymers: –Thermoplastic: Polymers that flow when heated; thus, easily reshaped and recycled. This property is due to presence of long chains with limited or no crosslinks. (polyethylene, polyvinylchloride) –Thermosetting: Decomposed when heated; thus, can not be reformed or recycled. Presence of extensive crosslinks between long chains induce decomposition upon heating and renders thermosetting polymers brittle. (epoxy and polyesters) –Elastomers: Intermediate between thermoplastic and thermosetting polymers due to presence of some crosslinking. Can undergo extensive elastic deformation (natural rubber, silicone)

9 9 Polymers StructureSource-Based NameApplication R = -HPolyethylenePlastic R = -CH 3 PolypropyleneRope R = -ClPoly(vinyl chloride)"Vinyl" X = -H, R = -C 2 H 5 Poly(ethyl acrylate)Latex paints X = -CH 3, R = -CH 3 Poly(methyl methacrylate)Plastic R = -HPolybutadieneTires R = -CH 3 PolyisopreneTires X = -F, R = -FPolytetrafluoroethyleneTeflon® —C—C— H H R —C—C— H H R —C—C— H H R

10 10 Polymers

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12 12 Polymers Polymers can be either amorphous or semi-crystalline Tacticity, i.e. arrangements of substituents around the backbone, determines the degree of crystallinity Atactic polymers are amorphous Isotactic and syndiotactic may crystallize Crytallinity depends on: –size of side groups (smaller, ↑crystallinity) –regularity of chain Increased crystallinity enhances mechanical properties

13 13 Polymer Synthesis Two common methods of polymerization –Condensation polymerization (or stepwise addition) –Addition reaction (or chain polymerization) Condensation: Two monomers react to form a covalent bond usually with elimination of a small molecule such as water, HCl, methanol, or CO 2. Reaction continues until one type of reactant is used up. Addition: Monomers react through stages of initiation, propagation, and termination. –initiators such as free radicals, cations, anions opens the double bond of the monomer which becomes active and bonds with other such monomers –rapid chain reaction propagates in this fashion –reaction is terminated by another free radical or another polymer

14 14 Polymer Synthesis: Condensation phenol-formaldehyde: results in condensation of a water molecule nylon (polyamide): an organic acid reacts with an amine to form an amide. HCl condenses

15 15 Polymers Synthesis: Addition Termination may occur by: two radicalized polymers reacting another radicalized monomer one initiator (alkoxy radical, OR, in this case)

16 16 Condensation vs. Addition Addition: –Difficult to control molecular weight –Undesirable branching products Condensation: –Molecular weight closely controlled –Polydispersity ratios close to unity can be obtained

17 17 Polymers: Deformation I. Chain unfolding, unwinding, unwrapping or uncoupling (low energy) II. Chain sliding(low energy) III. Bond stretching, side group ordering (high energy) IV. Bond breaking (high energy) I II IIIIV Stress Strain

18 18 Polymers: Deformation Lower elastic modulus, yield and ultimate properties Greater post-yield deformability Greater failure strain Stress Strain Polymers Metals Ceramics

19 19 Polymers: Viscoelasticity Dependency of stress-strain behavior on time and loading rate Due to mobility of chains with each other Crosslinking may affect viscoelastic response Stress Strain increasing loading rate

20 20 Polymers: Thermal Properties In the liquid/melt state enough thermal energy for random motion (Brownian motion) of chains Motions decrease as the melt is cooled Motion ceases at “glass transition temperature” Polymer hard and glassy below T g, rubbery above T g Stress Strain decreasing temperature or increasing crystallinity linear amorphous log(Modulus) Temperature semicrystalline crosslinked TmTm TgTg

21 21 Viscoelastic Deformation Glassy Materials and Tg Rigid Brittle Solid below Tg Viscous Deformable liquid above Tg η is the viscosity of the fluid

22 22 Viscoelastic Modulus versus Temperature

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26 26 Fracture of Polymers Thermoset and Thermoplastic materials below Tg behave as brittle solids and fail by cracking. The cracks are sharp. Crystalline Thermoplastic Resins above Tg yield and undergo ductile failure. Noncrystalline Thermoplastic resins above Tg undergo Crazing and Cracking. Crazing - Orientation of polymer chains across the opening of a “crack- like” feature. The work of crazing is 1000 times larger than the surface work to create a crack. Cracking then occurs down the middle of the craze.

27 27 Craze Formation

28 28 Crack Propagation Through Crazed Area

29 29 Cracking Example in Polymers


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