Graphene Synthesis & Graphene/Polymer Nanocomposites
Ken-Hsuan (Kirby) Liao Advisors: Dr. Chris Macosko
Dr. Andre Mkhoyan
Department of Chemical Engineering & Materials Science University of Minnesota
Ph.D. Defense Minneapolis MN
September 19th, 2012
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• University of Minnesota - Ph.D. Materials Science, 2008~Present Graphene Synthesis & Graphene/Polymer Nanocomposites
• Double Bond Chemical Co - Research & Development Engineering, 2008 Polymeric Materials
• Taiwan Army, 2007~2008
• National Taiwan University - M.S. Polymer Science & Engineering, 2005~2007 MS Thesis: Thermoplastic polyurethane composites for dental materials - B.S. Chemical Engineering, 2001~2005 BS Thesis: Mechanical & thermal properties of thermoplastic polyurethane
Biography
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Graphene
0-D: Bucky Ball, 1986
1-D: Carbon Nanotube, 1991
3-D: Graphite, 1500
2-D: Graphene, 2004
Graphene Properties
Modulus 1 TPa
Strength 130 GPa
Electrical Conductivity 6000 S/cm
Surface Area 2600 m2/g
Graphene: monolayer of carbon atoms packed in 2D hexagonal manner
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Why Graphene/Polymer Nanocomposites?
Light-weight stiff materials
BMW i8, a car made with composites.
Boeing 787, contains 70,000 lb composites.
Food packaging
From Brown Machine LLC
Conductive coating
From Thermal Spray Technology Inc 4
Picture From Mission Impossible 4 From Boeing
Challenge of Graphene/Polymer Nanocomposites: Dispersion
Bicerano, Polymer, 2002, 43, 369 5
aspect ratio
>> <<
material needed
Motivation of Novel Graphene Synthesis
Criteria of Graphene Synthesis Process for Nanocomposites:
1. Massive production 2. Low cost 3. Environmental friendly process 4. Easy to transport
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Graphene Precursor: Graphite Oxide
• Hydrophilic (Carbon/Oxygen=2/1) • Electrical insulator
GO/water hydrophilic
Graphene/water hydrophobic
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Gao, W. et al, Nature Nanotechnology 2011, 6, 496
Approaches to Produce Graphene
2000oC/s Scotch tape surfactant
Li et al, Nature Nanotechnology 2008, 3, 101
Schniepp et al, J. Phys. Chem. B 2006, 110, 8535
Novoselov et al, Science 2004, 306, 666
Lotya et al, JACS 2009 131, 3611
hydrazine
Oxidation
H2SO4
KMnO4
4 weeks cleaning up
• Advantages: Pristine graphene • Disadvantages: Low Production
• Advantages: High Production • Disadvantages: Slow process Low bulk density Hard to transport Safety issue
Graphite Scotch Tape Nobel Prize
• Advantages: High Production Higher bulk density • Disadvantages: Hazard chemicals Slow process 8
Process & Mechanism of Aqueous Graphene
0.95 nm 0.34 nm
XRD:
Liao, K.-H. et al, ACS Nano, 2011, 5, 1253-1258 9
Process & Mechanism of Aqueous Graphene
0.95 nm 0.34 nm
AFM topography:
1. Liao, K.-H. et al, ACS Nano, 2011, 5, 1253-1258 2. Liao, K.-H. et al, ACS Applied Materials & Interfaces, 2011, 3, 2607-2615
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Process & Mechanism of Aqueous Graphene
Liao, K.-H. et al, ACS Nano, 2011, 5, 1253-1258
ARG Surface Area:
~400m2/g by BET
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Elemental Composition of Aqueous Graphene (ARG)
GO/water hydrophilic
ARG/water hydrophobic
FTIR: XPS: C/O=2/1
C/O=7/1
1. Liao, K.-H. et al, ACS Nano, 2011, 5, 1253-1258 2. Liao, K.-H. et al, ACS Applied Materials & Interfaces, 2011, 3, 2607-2615
TEM: HR-TEM: Dispersion in water:
ARG
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Electrical Conductivity of Aqueous Graphene
C/O Electrical Conductivity(S/cm)
GO Film 2/1 ~10-5
GS Film 7/1 ~101
Graphene Paper
Liao, K.-H. et al, ACS Nano, 2011, 5, 1253-1258
• Advantages: High production High bulk density
• Disadvantages: Slow process Hazard chemicals
Chemically Reduced Graphene: Aqueous Reduced Graphene:
• Advantages: High production High bulk density Fast process No hazard chemicals involved
Single-layer graphene yield: 65% Single + double layer yield: > 90%
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Dispersion of ARG in TPU
Single solvent blending process: Co-solvent blending process:
Percolation concentration 1.75 wt% Percolation concentration 0.5 wt% Modulus improved by ~300% (3.0 wt%) Modulus improved by ~650% (3.0 wt%)
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Resistance Modulus
Graphene/Poly-Urethane-Acrylate (PUA) Nanocomposite
ano2
Idea: Disperse graphene in flowable oligomer instead of polymer for better dispersion Graphene: Vorbeck’s thermally reduced graphene (TRG)
15 Liao, K.-H. et al, Polymer, 2012, 53, 3756
Electrical Percolation & Aspect Ratio
Percolation concentration: 0.15 wt% Af of dispersed TRG: ~750 reported Af of free standing TRG: 750
Af : aspect ratio of dispersed filler σc : conductivity of nanocomposites σf : conductivity of filler r : particle radius t : particle thickness Φsphere : volume fraction of interpenetrating spheres (= 0.29) Φperc : percolation volume concentration
σc = σf (φ-φperc)t
16 Liao, K.-H. et al, Polymer, 2012, 53, 3756
Mechanical Properties of Graphene/PUA Nanocomposites
Polymerization heat & Tg by DSC:
DMA : Polymerized Graphene/Poly-urethane-acrylate Nanocomposites:
TRG Load (wt%) Hp (J/g) Tg (°C) 0 245±16
14±4
0.10 244±13 0.25 256±22 0.50 243±15
Mori-Tanaka model simulated results (black dash lines) & real modulus (spots):
17 Liao, K.-H. et al, Polymer, 2012, 53, 3756
Electrical Percolation Concentration : Literature Summary
18 Liao, K.-H. et al, Polymer, 2012, 53, 3756
Motivation: Egraphene/Ematrix literature summary
Kim, Abdala, Macosko Macromolecules 2010
0.05 wt% in PMMA Brinson et al Nature Nano 2008
Theoretical Maximum
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Glass Transition Temperature of Graphene/PMMA Nanocomposites
Ramanathan et al, Nat. Nanotech. 2008 3, 327
Control Groups: As Received PMMA (PMMA) As Precipitate PMMA (P-PMMA)
0.05 wt% percolation concentration? Too low! 30 oC of Tg increase? Too high!
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Glass Transition Behavior of Graphene/PMMA Nanocomposites
• Glass transition temperature (Tg ) changed obviously even without incorporation of graphene!!
• Coagulation process removed surfactant, which significantly decrease the Tg of PMMA.
The authors did not operate coagulation process for control groups!!
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Tg of Graphene/Polymer Nanocomposites – Physical Blending
Solvent Blending Matrix
Polymer ∆Tg (°C) Filler Technique Filler Load
PVDF[98] 0 TRG DSC 4 wt% PBS[138] 0 CRG DMA 2 wt%
LLDPE[139] 0 EG DMA 20 wt% PVDF[140] 3.5 TRG DMA 0.5 wt% TPU[122] -2 TRG DSC 7 wt%
PαMSAN/PMMA[141] 0 TRG DMA 1 wt%
Rubber[142] 0 GO DSC 10 wt% TPU[143] -5 EG DSC 10 vol% TPU[144] 0 TRG DMA 6 wt% PS[108] 0 CRG DMA 1.94 vol% PI[107] 2.6 γ-ABA-GO DMA 0.4 wt%
PVA[132] -4.5
TRG
DSC
1 wt% PMMA[132] 0.3 0.2 wt%
PEI[132] 0 0.1 wt% TPU[145] 0 TRG DMA 4.4 wt%
Melt Blending PE[146] 0 CRG DMA 2 wt%
PA12[147] 0 CRG DSC 2 wt% PET[148] < 2 TRG DMA 7 wt% PTT[149] 0 TRG DSC 7 wt% PC[111] 0 GO DMA 3 wt% PP[110] 0 GO DMA 5 wt%
GO: Graphene oxide CRG: chemically reduced graphene TRG: thermally reduced graphene EG: Expanded graphite 22
Solvent-Blending: Melt-Blending:
Tg of Graphene/Polymer Nanocomposites – Chemical Blending
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In situ Polymerize monomer in the presence of dispersed graphene
Tg of Graphene/Polymer Nanocomposites – Chemical Blending
In situ Polymerization Matrix Polymer ∆Tg (°C) Filler Technique Filler load
PBI[133] 1.8 Pristine graphene DMA 0.2 wt% NIPAA[134] 0 Pristine graphene DSC 0.13 wt% Epoxy[152] 7 TRG DSC 0.05 wt% PMMA[77] 20 CRG DMA 4 wt% PMMA[128] 9 CRG DMA 1 wt%
PMMA[129] 3 GO
DMA 1 wt% 8 CRG
PMMA[76]
14 GO
DSC
6 wt% 19 DMA 7 AIBN-GO DSC & DMA
Vinyl Ester[155] 7 TRG -- 0.2 phr
PUA[156] 4 GO
DSC 0.5 wt%
3.4 Isocyanate-GO 1 wt% PUA[157] 0 TRG DSC & DMA 0.5 wt% PUA[158] 7 CRG DMA 1 wt% PS[159] 8 PS-modified CRG DSC 2.5 wt%
Commonly Tg change was reported for chemical blending process 24
Tg of Graphene/Polymer Nanocomposites – Aqueous Blending
Aqueous Blending (solvent blending with water as solvent) Matrix Polymer ∆Tg (°C) Filler Technique Filler load
PVA[104] 12 CRG DSC 7.5 wt% PVA[170] 4 CRG DSC 0.5 wt% PVA[105] 14 CRG DSC 3.5 wt% PVA[171] 9 GO DSC 0.72 vol% PVA[172] 4 GO DSC 0.7 wt%
Chitosan[135] 5 GO DSC 1 wt% Gelatin[173] 10 GO DSC 2 wt%
PEO[174] 9 TRG DMA 4 wt%
Commonly Tg change was reported for aqueous blending process
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Tg of Nanocomposites & Polymer Nano-confinement
Mayes A, Nature Materials 2005, 4, 651
Grohens Y et al. Langmuir 1998, 14, 2929
Nanoconfinement & nanocomposites
Tacticity effect of nanoconfinement
Dispersion of TRG/PMMA Nanocomposites
Samples: TRG/syndiotactic-rich-PMMA (a-PMMA) TRG/isotactic-PMMA (i-PMMA) in situ TRG/PMMA
Resistance: (by 11-Probe) Modulus:
Dispersion levels of TRG are similar 27
Af ~200
Tacticity Effect on Tg of TRG/PMMA Nanocomposites
Samples: TRG/a-PMMA TRG/i-PMMA
tanδ [tan(E”/E’)] by DMA of: TRG/a-PMMA i-PMMA
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Tacticity Effect on Tg of TRG/PMMA Nanocomposites
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Interaction Density: i-PMMA > a-PMMA
Interaction Intensity: i-PMMA > a-PMMA
Noro, Matsushita, Lodge Macromolecules 2008, 41, 5839-5844
n(T): number of H-bonds per P2VP block
Process Effect on Tg of TRG/PMMA Nanocomposites
Samples: in situ TRG/PMMA TRG/a-PMMA
tanδ [tan(E”/E’)] by DMA of: TRG/atactic-PMMA in situ TRG/PMMA
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Possible Reactions during in situ Polymerization
~1 % of PMMA covalently grafted on TRG
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Process of separating filler and matrix polymer for in situ system
dissolve in THF filtration
dry rinse Tg by DSC:
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In situ TRG/PMMA nanocomposites film
Process of separating filler and matrix polymer for in situ system
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Finding holes perfectly covered by single-layer GO:
TEM:
AFM:
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Oxygen Effect on Graphene Oxide
Hole size: 2.5µm in diameter
TEM grid
Lee, C. et al Science 2008, 321, 385
Force = (TM Deflection) × (Cantilever Spring Constant)
Atomic structure of single-layer GO:
Force = (TM Deflection) × (Cantilever Spring Constant)
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Mkhoyan, K. A. et al, Nano Letters, 2011, 9, 1058
Bridge (C-O-C) bonds were removed after chemical reduction
Hole size: 2.5µm in diameter
TEM grid
Oxygen Effect on Graphene Oxide
Lee, C. et al Science 2008, 321, 385
Conclusion
In situ Polymerization Melt Blending Solvent Blending
Fast, scalable, green process with massive production
• Mechanical Properties: Elastic modulus increase 100% with 0.5 wt% of graphene
• Thermal Properties: Glass transition temperatures affected by process and tacticity
• Electrical Properties: Surface resistance decrease 1010 times with 1 wt% of graphene
• Techniques used: AFM, Rheometer, DMA, XRD, SAXS, TEM, SEM, XPS, FTIR, GPC, TGA, DSC, universal tensile testing instrument.
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Acknowledgement • Dr. Chris Macosko (CEMS) • Dr. Andre Mkhoyan (CEMS) • Dr. Greg Haugstad • Steven Maslo, Jerry Yeh • Group Members
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