Synthetic Rubber. For HIPS, MBS and Mass-ABS. Mitsubishi International Corporation

Synthetic Rubber For HIPS, MBS and Mass-ABS Mitsubishi International Corporation 1

Classification of Diene Rubber Polybutadiene (BR) High Cis BR Butadiene Rubber Styrene-Butadiene Copolymer (SBR) Low Cis BR High Trans BR High Vinyl BR Emulsion-SBR Solution-SBR Styrene-Butadiene-Styrene block Copolymer (SBS:Thermoplastic Elastomer) Hydrogenated SBS-SEBS Isoprene Rubber Natural Rubber (NR) Polyisoprene (IR) 2

Control of Microstructure Control of Macrostructure Characteristics of Solution Polymerization Technique Butadiene Catalyst Terminator Stabilizer Polybutadiene (BR) Styrene Styrene-butadiene copolymer (SBR) R-Li H 2 C H C C H CH 2 H H 2 H R C C CH C C C CH C- Li+ H 2 H2 H2 + H H H 2 C CH R C C CH C C C C CH Li + H 2 H2 H 2 H 2 - Molecular Weight MWD (Mw/Mn) Branch Controllable by ratio between Feed Monomer/Catalyst because of living anionic polymerization Narrow due to living anionic polymerization. Changeable according to polymerization conditions and reactions Little during polymerization. Easily controlled by adding coupling agent Microstructure ( polybutadiene parts) Bound Styrene Content Block Styrene Content Hydrogenated (Bd) 1,4-Cis; 1,4-Trans; 1,2-Vinyl Vinyl content easily controlled by adding modifier (polar compounds) Easily controlled by butadiene/styrene feed ratio Random, block, tapered Controlled by polymerizations conditions 1,2-Vinly.Butylene 1,4-Cis Trans.Ethylene 3

Relationship between Low Cis, High Cis Rubber Low Cis Rubber High Cis Rubber Polymerization Anionic polymerization (Solution) Rli catalyst Radical polymerization (Emulsion) Potassium peroxodisulfate Coordinate polymerization (Solution) Ni catalyst Co-Al catalyst MWD narrow, Little branching Microstructure: Cis 35%, Trans 52%, Vinyl 13% Tg: -98 degree C Tm: nil Broad MWD, Much branching Microstructure: Cis 12%, Trans 70%, Vinyl 18% Control of polymer structure Little variation -- Styrene content -- Molecular weight Polymer Structure Control of polymer structure Large variation -- Vinyl content -- Block SBR, Random SBR -- Coupling reaction, Terminal modification, etc. Broad MWD (Mw/Mn 3), Much branching Microstructure: Cis 96%, Vinyl 4% Tg: -105 degrees C Tm: 10 degrees C No copolymerization of styrene 4

Microstructure of Polybutadiene Polymer structure Homopolymer Tg, Tm Tg (Elasticity) Tm (Crystallization) Cis Bond CH 2 HC H 2 C CH -110 C -10 0 C (YES) Trans Bond CH 2 HC H 2 C CH -100 C 50 100 (YES) Vinyl Bond C H 2 H C HC CH 2-7 C Nil (NIL) Styrene C H 2 H C 100 C Nil (NIL) 5

Microstructure of Polybutadiene (2) Catalyst Cis Microstructure (%) Trans Vinyl Styrene Copolymerizable RLi 35 52 13 RLi / Polar solvent ~30 ~50 ~70 Ni Ni(Naphtanate) AlR 3 BF 3 (C2H5) 2 96 ~ 98 1 ~ 2 1 ~ 2 Co Co(Octanate) 2 AlR 2 Cl H 2 O 96 ~ 98 1 ~ 2 1 ~ 2 Radical K 2 S 2 O 4 10 ~ 20 60 ~ 80 15 ~ 20 = Copolymerizable with styrene = Not copolymerizable with styrene 6

Comparison of Batch Polymerized Rubber with Continuous Polymerized Rubber: Molecular weight Distribution 100 Fraction (%) 90 80 70 60 50 Continuous Polymerization Asadene 5 5 A E Mw/Mn=2.2 Batch polymerization Asaprene 730AX Mw/Mn=1.2 High Cis Rubber Mw/Mn=3.5 40 30 20 10 0 12 13 14 15 16 17 18 19 High Molecular Weight Retention Time (min) Low Molecular Weight 7

Synthetic Rubber for HIPS Use Acquired Characteristics Ability to crosslink/graft during HIPS polymerization Styrene insolubles (gel) Impurity Colorless Handling flow Extremely low Extremely low Improved cold 8

Synthetic Rubber for HIPS Use Commercial Rubber for HIPS Use Polybutadiene rubber: Low Cis BR, High Cis BR Comparison of Low Cis BR with High Cis BR as rubber for HIPS: Low Cis BR High Cis Br Graft High reactivity Low reactivity Crosslinking High reactivity Low reactivity Styrene-butadiene copolymer Random SBR Block SBR Special grade: Super high gloss HIPS, Transparent HIPS, etc. 9

Synthetic Rubber for HIPS (Mass-ABS) General Low SV Low Modulus PH-BR SBR Grade Asadene 55AE Asadene 35AE Asaprene 720AX Asaprene 730AX Asaprene 760AX H300A Asaprene 610A Asaprene 625A Asaprene 670A Styrene (%) 0 0 0 0 0 0 15 35 39 ML 50 33 40 47 55 - - - SV (CPS) 170 85 25 35 77 75 10 20 34 CIS 35 35 33 33 33 Partially hydrogenated BR 35 35 35 Microstructure (%) TRANS S 52 52 49 49 49 51 51 51 VINYL L 13 13 18 18 18 14 14 14 General purpose High Gloss High Impact Thermal Stability High Gloss Mass-ABS Transparent Super High Gloss 10

Relationship between Mooney and Solution Viscosities 1000 Solution Viscosity [5wt% in Styrene] 100 55AE High Cis Difference 35AE in branch by coupling 760AX 730AX 720AX 10 1 10 20 30 40 50 60 70 80 Mooney Viscosity [ML1+4, 100 C] 11

Cold Flow of Asaprene, Asadene, Other Rubbers Cold Flow %) 80 70 60 50 40 30 20 10 1 Kg. Rubber Ht. Sample size (mm): LXWXH=40X40X50 Cold flow %) = HO Ht HO HO=Initial height of sample X 100 Ht= Height of sample after t min. 720AX 35AE 55AE 730A X 760AX 0 0 20 40 60 80 100 120 Time (min.) 12

Relationship between Solution Viscosity and Rubber Particle Size (Using Polybutadiene rubber) 6.0 5.0 1.5L Glass bottle Rubber/SM = 595 (wt%) 55AE Agitation speed: 25 rpm R.P.S. (µm) 4.0 3.0 2.0 730AX 35AE 35AE 55AE Agitation speed: 75 rpm 1.0 730AX 0.0 0 50 100 150 200 Solution viscosity (cps) 13

Molecular Distribution of Weight for Asadene 55AE/35AE 70 Fraction (%) 60 50 40 30 20 10 Asadene 55AE Asadene 35AE 0 12 13 14 15 16 17 18 19 20 High molecular weight Retention time (min.) Low molecular weight 14

Distribution of Molecular Weight in Asaprene Series 100 Fraction (%) 90 80 70 60 50 40 30 Asaprene 730AX Asaprene 760AX 20 10 0 12 13 14 15 16 17 18 19 20 High molecular weight Retention time (min.) Low molecular weight 15

Relationship between Rubber Particle Size and Izod, Gloss (Using polybutadiene rubber) 16 14 100 90 Asaprene Series 720AX, 730AX Izod impact (kg cm/cm) 12 10 8 6 4 2 Asaprene Series 720AX, 730AX Asadene Series 55Ae, 35AE Gloss (%) 80 70 60 50 40 30 20 10 Asadene Series 55AE, 35AE 0 0.4 0.8 1.2 1.6 2 2.4 2.8 3.2 0 0.4 0.8 1.2 1.6 2 2.4 2.8 3.2 Rubber particle size (µm) Rubber particle size (µm) 16

Asaprene 760AX Rubber for super high-impact PS Molecular structure Polybutadiene rubber Branched structure Vinyl/cis/trans: 18/33/49 Solution viscosity: 77cps 17

Asaprene 760AX Characteristics By using low-modulus Asaprene rubber, impact energy can be absorbed easily Izod impact strength (kg cm/cm) 12 11 10 9 8 7 Constantrubber particle size 760AX 55AE 6 10 15 20 25 30 M odulus (kg/c m) 18

Asaprene 670A (1) Rubber for Super high-gloss HIPS Transparent HIPS Molecular structure Styrene-butadiene rubber (39% styrene) Vinyl/cis/trans: 14/36/50 Solution viscosity: 34 cps C H 2 H C CH2 C C H2 H C Ph Styrene unit O CH 3 C OR 1 Methacrylic ester unit O C OR 2 Acrylic ester unit 19

Asaprene 670A (2) Characteristics Allows for easy formation of core-shell rubber particles Makes it easy to obtain transparent HIPS Corresponds to refractive Index of Styrene/Methacrylic copolymer and rubber phase Core-shell particles (thermal polymerization) Refractive Index SP SBR PMMA PBA 1.59 1.54 1.49 1.46 20

Asaprene 625A (1) Rubber for transparent HIPS Molecular structure Styrene-butadiene rubber (35% styrene) Vinyl/cis/trans: 14/36/50 Solution viscosity: 20 cps Matrix Resin CH 3 Rub. C H 2 H C CH2 C C H2 H C Ph O C O C Grafted Copolymer Styrene unit OR 1 Methacryric ester unit OR 2 Acrylic ester unit 21

Asaprene 625A (2) Characteristics Transparency HIPS are easily obtained compared with other styrene-butadiene block copolymers Easier to handle: Bale is Easier to cut Less likely to crack Bites into cutter more easily Refractive Index PS SBR PMMA PBA 1.59 1.54 1.49 1.46 22

1R.P.S.(µm) Asaprene 720AX Rubber for high-gloss mass ABS Characteristics: Easier to obtain small rubber particles Molecular structure: Polybutadiene rubber Vinyl/cis/trans: 18/33/49 Solution Viscosity: 25 cps 730AX 720AX 0.1 0 5 10 15 20 25 30 35 40 Solution Viscosity (cps) Relationship between Solution viscosity and R.P.S. Mass ABS with Asaprene720AX 23

R.P.S.(µm) Asaprene 610A Rubber for high-gloss mass ABS Characteristics: Easier to obtain small rubber particles Molecular structure Styrene-butadiene rubber (15% styrene) Vinyl/cis/trans: 14/36/50 Solution viscosity: 10 cps 1 720AX 730AX 610A 0.1 0 5 10 15 20 25 30 35 40 Solution Viscosity (cps) Relationship between Solution viscosity and R.P.S. Mass ABS with Asaprene 610A 24

H300A (1) Rubber for HIPS with excellent thermal stability Molecular structure: 1,4-cis/trans: 63% 1,2-vinyl: 1% Tetramethylene: 26% Butylene: 10% Solution viscosity: 75 cps C C C C ) C H 2 H H H2 H2 H H C ) C C C C ) C C ) H2 H2 H2 H2 H2 ( ( ( ( HC CH 2 H 2 C CH 3 1,4-cis/trans 1,2-vinyl Tetramethylene Butylene 25

H300A (2) Characteristics HIPS and styrenic copolymer (e.g. masspolymerized ABS) with PHBR have excellent thermal stability. As a result, the decline in impact strength is very small when molding at high temperatures Outstanding capabilities for recycling applications Izod (kg cm/cm) 14 12 10 8 6 4 2 0 PHBR 35AE (89 %) (73 %) (78 %) (58 %) Original Heat-aged Heat-aged 270 C X 30 290 C X 30 min min 26

Asaprene 630A (1) Rubber for translucent (high-gloss) HIPS Molecular structure Styrene-butadiene rubber (22% styrene) Vinyl/cis/trans: 14/36/50 Solution viscosity: 33cps 100 90 Core-shell particle HIPS Good Gloss (%) 80 70 60 50 40 Cell particle HIPS 30 20 2 4 6 8 10 12 14 16 Izod Impact (kg cm/cm) 27

Asaprene 630A (2) Characteristics Core-shell rubber particles can be obtained easily Comparison with other styrene-butadiene block copolymers: Less rubber content Easier to handle: Bale is Easier to cut Less likely to crack Bites into cutter more easily Dissolving time is shorter Core-shell particles 28

Asaprene 610A, 720AX (1) Rubber used for mass ABS Molecular structure 610A Styrene-butadiene rubber (15% styrene) Vinyl/cis/trans: 14/36/50 Solution viscosity: 10cps 720AX Polybutadiene rubber Vinyl/cis/trans: 18/33/49 Solution viscosity: 25cps 29

Asaprene 610A, 720AX (2) Characteristics Small rubber particles the size of ABS are easily obtained, making it possible to obtain a high-gloss ABS 10 R.P.S. (µm) 1 720AX 730A 700A 610A 0.1 0 10 20 30 40 50 60 Solution viscosity (CPS) Relationship between Solution Viscosity and R.P.S. Polymerization Condition Apparatus : 1.5L glass bottle Composition : SM/AN/Rub.=65/25/10 (wt%) Initiator:150ppm Chain Transfer:1200ppm 30

Next Steps Mitsubishi International offers a variety of outstanding synthetic rubbers for HIPS and Mass-ABS applications To learn more about how MIC can meet your product needs, please contact us at (212) 605-2440, or email rafi.khan@mitsubishicorp.com Thank you. 31