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BIOBIO--BASED NANOCOMPOSITES:BASED NANOCOMPOSITES:CHALLENGES AND OPPORTUNITIESCHALLENGES AND OPPORTUNITIES
John SimonsenJohn SimonsenDepartment of Wood Science & EngineeringDepartment of Wood Science & Engineering
Oregon State UniversityOregon State University
OutlineOutline•• What is the difference between composites What is the difference between composites
and nanocomposites?and nanocomposites?•• Nanocrystalline cellulose (NCC, CNXL)Nanocrystalline cellulose (NCC, CNXL)•• Experimental resultsExperimental results
•• PolyhydroxyoctanoatePolyhydroxyoctanoate•• PVOHPVOH•• PURPUR•• Polysulfone (PSf)Polysulfone (PSf)•• CMCCMC
•• Challenges and opportunitiesChallenges and opportunities•• AcknowledgementsAcknowledgements
Polymer CompositesPolymer Composites
Generally consists of a polymer Generally consists of a polymer ““matrixmatrix””and a particulate and a particulate ““fillerfiller””Filler (dispersed phase) is dispersed in Filler (dispersed phase) is dispersed in matrix (continuous phase)matrix (continuous phase)Can also have continuous filler (graphite Can also have continuous filler (graphite fiber pultrusion, used for aerospace, etc.), fiber pultrusion, used for aerospace, etc.), but not yet used in nanocompositesbut not yet used in nanocomposites
Wood flour in HDPE
0.1 mm
Synergism in Polymer Synergism in Polymer CompositesComposites
Function of matrix:Function of matrix:Disperse fibersDisperse fibersTransfer load to fillerTransfer load to fillerLoad sharing between broken and intact filler Load sharing between broken and intact filler particlesparticlesIncreases toughnessIncreases toughness
Function of fillerFunction of fillerCarry load, increase propertiesCarry load, increase propertiesLower costLower cost
What makes a nanocomposite What makes a nanocomposite different?different?
Reduced impuritiesReduced impurities
As the size of a particle is reduced, the As the size of a particle is reduced, the number of defects per particle is also number of defects per particle is also reducedreducedMechanical properties rise proportionatelyMechanical properties rise proportionately
Properties of fibers and nanoparticlesProperties of fibers and nanoparticles
materialmaterial Density, Density, g/cmg/cm33
ρρ
Theoretical Theoretical strength, strength, GPaGPa
Whisker Whisker strength (S),strength (S),GPaGPa
Bulk Bulk strength,strength,GPaGPa
Specific Specific whisker whisker strengthstrengthS/ S/ ρρ
ironiron 7.687.68 2020 1313 4.14.1 1.681.68
Carbon Carbon (graphite)(graphite)
1.381.38 9898 2121 1.71.7 12.412.4
An historical nanoAn historical nano--example:example:
Carbon blackCarbon black
http://www.degussa.com/downloads/en/pictures/product_stories/2004_06_15_carbon_black.Par.0006.posterImage.jpg
http://www.degussa.com/downloads/en/pictures/product_stories/2004_06_15_carbon_black.Par.0006.posterImage.jpg
Addition of nanoAddition of nano--sized carbon to rubbersized carbon to rubber
Particle size 10Particle size 10--75 nm75 nmStrength can increase 1000 XStrength can increase 1000 XStiffness increases 7 X (in accordance with Stiffness increases 7 X (in accordance with modified Einstein equation)modified Einstein equation)Abrasion resistance 4Abrasion resistance 4--5 X5 XWithout carbon black, tires would not be Without carbon black, tires would not be made from rubber!made from rubber!
Surface AreaSurface AreaEE--glass fibersglass fibers** ~1~1
Paper fibersPaper fibers 44
GraphiteGraphite 2525--300300
Fully exfoliated clayFully exfoliated clay ~ 500~ 500Cellulose nanocrystalsCellulose nanocrystals**** 250250
Fumed silicaFumed silica 100100--400400
Carbon nanotubes***Carbon nanotubes*** ~ 100 ~ 100 -- ??
m2/g
*http://www.jm.com/engineered_products/filtration/products/microfiber.pdf** Winter, W. presentation at ACS meeting, San Diego, March 2005***http://www.ipme.ru/e-journals/RAMS/no_5503/staszczuk/staszczuk.pdf.
PolymerPolymer--clay nanocompositesclay nanocomposites
mechanical and barrier propertiesmechanical and barrier properties
The step-assist on the 2002 GMC Safari (shown) and Chevrolet Astro vans is the automotive industry's first exterior applications for thermoplastic polyolefin-based nanocomposites. The part won General Motors the 2001 Grand Award for plastics innovation from the SPE's Automotive Division. (Photo courtesy of Wieck Photo Database).
http://www.specialchem4polymers.com/resources/articles/article.aspx?id=579
NanoNano--PA6 PA6 Using Nanomer 1.24 TL Using Nanomer 1.24 TL -- In Situ In Situ PolymerizationPolymerization
intercalation
exfoliation
U. Southern Miss. Macrogalleria http://www.psrc.usm.edu/macrog/mpm/composit/nano/struct2_1.htm
Aspect ratio > 100
Confined polymer
Barrier PlatformBarrier PlatformMitsubishi gas chemical and Nanocor Alliance ImpermMitsubishi gas chemical and Nanocor Alliance Imperm®®NanoNano--Nylon MXD6Nylon MXD6
Barrier Film for packagingBarrier Film for packagingNanoNano--PA6 using Nanomer 1.24 TL PA6 using Nanomer 1.24 TL -- In situ polymerizationIn situ polymerization
PercolationPercolation
I. Chodak, I Krupa. J. Mat. Sci. Lttrs. 1999 18:1457-1459
Relative electrical conductivity (Relative electrical conductivity (ρρcc//ρρmm) of the ) of the carbon black filled LDPE (circles) or HDPE carbon black filled LDPE (circles) or HDPE (squares) as a function of the filler content ((squares) as a function of the filler content (NN).).
Garboczi, et. al. Phys. Rev. Ltrs. E, 1995, 52(1): 819-828
Aspect ratio = 70
Percolation threshold ~ 1%
Nanocomposite ConceptsNanocomposite Concepts
Reduced defectsReduced defects
Surface areaSurface area
PercolationPercolation
Interphase volumeInterphase volumePolymer morphologyPolymer morphology
Cellulose
Crystalline regions
Amorphous region
Acid hydrolysis
Individual nanocrystals
Individual cellulose polymer
Cellulose Nanocrystal (CNXL) ProductionCellulose Nanocrystal (CNXL) Production
Native cellulose
Sources of nanocrystalline celluloseSources of nanocrystalline cellulose
Microcrystalline cellulose (wood)Microcrystalline cellulose (wood)Bacteria (Bacteria (NataNata de coco) de coco) CottonCottonAg wastesAg wastesTunicatesTunicates
Cellulose nanocrystalsCellulose nanocrystalsCellulose Cellulose sourcesource
LengthLength Cross Cross sectionsection
Aspect ratioAspect ratio
TunicateTunicate 100 nm 100 nm ––micronsmicrons
1010--20 nm20 nm 5 to > 1005 to > 100(high)(high)
Algal Algal ((ValoniaValonia))
> 1000 nm> 1000 nm 10 to 20 nm10 to 20 nm 50 to > 10 nm50 to > 10 nm(high)(high)2 to > 1002 to > 100(medium)(medium)20 to 7020 to 70(low)(low)20 to 5020 to 50(low)(low)
BacterialBacterial 100 nm 100 nm ––micronsmicrons
55--10 x 3010 x 30--50 50 nmnm
CottonCotton 200200--350 nm350 nm 5 nm5 nm
WoodWood 100 100 –– 300 nm300 nm 3 3 –– 5 nm5 nm
Beck-Candanedo, et. al. Biomacromol. (2005) 6:1048-1054
COST OF CELLULOSE NANOCRYSTALSCOST OF CELLULOSE NANOCRYSTALS
Microcrystalline cellulose (MCC) Microcrystalline cellulose (MCC) ~ $7/kg~ $7/kgHCl based processHCl based process
Nanocrystalline Cellulose (CNXL) Nanocrystalline Cellulose (CNXL) Target ~ $10/kgTarget ~ $10/kgHH22SOSO44 based processbased process
Do you need the purity of MCC starting material?Do you need the purity of MCC starting material?Can acid be recovered?Can acid be recovered?Uses for byproduct (sugar in acid)?Uses for byproduct (sugar in acid)?
TEM image of cellulose nanocrystalsTEM image of cellulose nanocrystals
Polymer systemsPolymer systems
Battery Separator, CNXL in Battery Separator, CNXL in PolyhydroxyoctanoatePolyhydroxyoctanoate
M. Samir, F. Alloin, J-Y Sanchez, A. Dufresne, 2004. Macromol. 37:4839-4844
Fuel cell operating temp
BACTERIAL CELLULOSE/BACTERIAL CELLULOSE/POLYVINYLALCOHOLPOLYVINYLALCOHOL
Slide from Wankei Wan, U. W. Ontario, London, ON, Canada
x
Slide from Wankei Wan, U. W. Ontario, London, ON, Canada
Slide from Wankei Wan, U. W. Ontario, London, ON, Canada
Slide from Wankei Wan, U. W. Ontario, London, ON, Canada
Slide from Wankei Wan, U. W. Ontario, London, ON, Canada
Cellulose nanocrystalCellulose nanocrystal--filled filled polyurethanepolyurethane
Slide from Mirta Aranguren, UNMdP-CONICET, Buenos Aires, Argentina
Polysulfone/cellulose Polysulfone/cellulose nanocompositesnanocomposites
Sweda NooraniSweda NooraniJohn SimonsenJohn Simonsen
TGATGA--16% CNXL16% CNXL
11.52%(0.2281mg)
38.88%(0.7699mg)
40
60
80
100
Wei
ght (
%)
0 100 200 300 400 500 600
Temperature (°C)
Sample: sample2_dec 30_tgaSize: 1.9800 mgMethod: Ramp
TGAFile: C:\Data\sweda\sample2_dec30_tga.001Operator: swedaRun Date: 30-Dec-04 12:02Instrument: 2950 TGA HR V6.0E
Universal V3.3B TA Instruments
TGATGA--11% CNXL11% CNXL
7.710%(0.1496mg)
48.43%(0.9396mg)
20
40
60
80
100
120
Wei
ght (
%)
0 100 200 300 400 500 600
Temperature (°C)
Sample: sample1_dec 30_tgaSize: 1.9400 mgMethod: Ramp
TGAFile: C:\Data\sweda\sample1_dec30_tga.001Operator: swedaRun Date: 30-Dec-04 10:41Instrument: 2950 TGA HR V6.0E
Universal V3.3B TA Instruments
TGA (Psf film with 2% CC)TGA (Psf film with 2% CC)
49.83%(1.024mg)
40
60
80
100
120
Wei
ght (
%)
0 100 200 300 400 500 600
Temperature (°C)
Sample: psf film (ncc)nov 17, 04Size: 2.0540 mgMethod: Ramp
TGAFile: C:...\sweda\psf film(ncc) nov 17,04.001Operator: swedaRun Date: 17-Nov-04 17:07Instrument: 2950 TGA HR V6.0E
Universal V3.3B TA Instruments
20x70 nm
% NCC (w/w)0 2 4 6 8 10 12
MO
E (G
Pa)
0.0
0.5
1.0
1.5
2.0
2.5
3.0
Nanocrystalline cellulose in PSfNanocrystalline cellulose in PSf
WVTR of CNXLWVTR of CNXL--filled PSffilled PSf
0
50
100
150
200
250
300
350
400
-2 3 8 13%NCC
Flux
(g/m
2 dy)
CELLULOSE NANOCRYSTAL-FILLED CARBOXYMETHYL CELLULOSE
YongJae ChoiYongJae ChoiJohn SimonsenJohn Simonsen
Comparison of Microcrystalline Comparison of Microcrystalline Cellulose (MCC) to NCC in CMCCellulose (MCC) to NCC in CMC
10% MCC 10% NCC10% glycerin plasticizer10% glycerin plasticizer200X optical (crossed polars)200X optical (crossed polars)
CROSS SECTION OF FILMCROSS SECTION OF FILM
90%CMC/10%Gly 80%CMC/10%NCC/10%Gly
Mechanical properties Mechanical properties
15
20
25
30
35
40
-5 0 5 10 15 20 25 30 35
CNXL or MCC content ( % w/w)
Tens
ile S
tren
gth
(MPa
)
Control
CNXL
MCC
30% increase
Mechanical properties Mechanical properties
85% increase
11.2
1.41.6
1.82
2.22.4
2.62.8
3
-5 0 5 10 15 20 25CNXL or MCC content (% w/w)
Tens
ile m
odul
us (G
Pa)
Contro lCNXLM CC
Extension at failureExtension at failure60% increase
0
1
2
3
4
5
6
7
-5 5 15 25 35CNXL or MCC content (% w/w)
Elon
gatio
n (%
)
controlCNXLMCC
HEAT TREATMENTHEAT TREATMENT
5% NCC in CMC (H form)5% NCC in CMC (H form)No plasticizerNo plasticizer
HEAT TREATMENTHEAT TREATMENT
78
80
82
84
86
88
90
92
94
0 20 40 60 80 100 120 140Heat treatment, 0C for 3 h, 5% NCC-filled CMC
Tens
ile s
tren
gth,
MPa
0
1
2
3
4
5
6
MO
E, G
Pa o
r % e
long
atio
n
MORMOEElongation
16% increase
Water DissolutionWater Dissolution
0
10
20
30
40
50
60
-5 15 35 55 75
Water immersion Time (hr)
Wei
ght l
oss
(%)
120C
100C
80C
No heat
Water vapor transmission rateWater vapor transmission rate
0
500
1000
1500
2000
control heat treated
WVT
R, g
/m2 d
y
11% reduction
CHALLENGESCHALLENGESDispersion of nanoparticlesDispersion of nanoparticlesProduction scaleProduction scale--up of nanoparticlesup of nanoparticlesCoupling of filler to matrixCoupling of filler to matrixWhere are the high stiffness, high Where are the high stiffness, high strength composites we should have?strength composites we should have?Improving knowledge base to allow Improving knowledge base to allow intelligent design of products which intelligent design of products which capture the advantages of this exceptional capture the advantages of this exceptional nanomaterialnanomaterial
OPPORTUNITIES OPPORTUNITIES -- APPLICATIONSAPPLICATIONS
MembranesMembranesFuel cells Fuel cells Kidney dialysis Kidney dialysis Reverse osmosis Reverse osmosis Protein separationProtein separationPervaporationPervaporation
Barrier filmsBarrier films
APPLICATIONSAPPLICATIONS
Advanced textiles Advanced textiles –– fibersfibersIf properties of CNXLs can be accessed If properties of CNXLs can be accessed efficientlyefficiently
BiomedicalBiomedicalTissue engineeringTissue engineering
Heart valvesHeart valvesbone replacement materialsbone replacement materialsSkin graftsSkin grafts
APPLICATIONSAPPLICATIONS
AdvantagesAdvantagesBiocompatibleBiocompatibleBiodegradableBiodegradableExceptional mechanical propertiesExceptional mechanical propertiesChemical modification straightforwardChemical modification straightforwardSelfSelf--assembling?assembling?
AcknowledgementsAcknowledgements
This project was supported by a grant from the USDA National Research Initiative Competitive Grants Program
QUESTIONS?QUESTIONS?
![Bio-Assembled Nanocomposites in ... - Photonics Laboratory Zhao/P2.pdf · glued together by biopolymers. [8–12 ] Although the strength and toughness of the nanocomposites in seashells](https://img.pdfslide.us/doc/110x75/5f1c1e5f523e415bc51828c7/bio-assembled-nanocomposites-in-photonics-laboratory-zhaop2pdf-glued-together.jpg)
