Presentation is loading. Please wait.

Presentation is loading. Please wait.

I MPACT OF THE FILLER FRACTION IN NC S G. Baeza et al. Macromolecules 2013 Multi-scale filler structure in simplified industrial nanocomposite systems.

Published byLeo Cannon Modified over 9 years ago

Similar presentations

Presentation on theme: "I MPACT OF THE FILLER FRACTION IN NC S G. Baeza et al. Macromolecules 2013 Multi-scale filler structure in simplified industrial nanocomposite systems."— Presentation transcript:

1 I MPACT OF THE FILLER FRACTION IN NC S G. Baeza et al. Macromolecules 2013 Multi-scale filler structure in simplified industrial nanocomposite systems silica/SBR studied by SAXS and TEM Structural Analysis 1

2 M ULTISCALE S TRUCTURE beadsaggregates network q -2.4 Artist view Tridimensionnal network built up from aggregates made of nanoparticles R bead  10 nm R agg  40 nm  si  (Quantitative Model) -Densification of the silica network -Aggregates remain similar d branch  120 nm

3 analysis G LOBAL V IEW : 3- LEVEL O RGANIZATION High-q : Bead form factor q si  R si (R 0 = 8.55 nm  = 27%) Medium-q : q agg  R agg (35 – 40 nm) Interactions Between Aggregates Low-q : q branch  Network branches (lateral dimension  150 nm), compatible with fractal aggregates (d  2.4). The network becomes denser and denser with  si  Artist view: network built up from Aggregates made of nanoparticles beadaggregatenetwork 3

4 Q UANTITATIVE ANALYSIS : A GGREGATE R ADIUS Subtraction of the fractal law Morphology of an aggregate R agg  si  q agg Kratky Plots allow to extract R agg Distribution Hypothesis q agg 4 d  2.4

5 Q UANTITATIVE MODEL Scattering law linking structure and form (polydisperse case) 1) D ETERMINATION OF N agg distribution Working hypothesis Calculation *Oberdisse, J.; Deme, B. Macromolecules 2002, 35 (11), 4397-4405 * 5 R agg distribution

6 Semi-Empiric law from simulation Hard-Sphere Potential (PY like)  agg  Q UANTITATIVE MODEL Scattering law linking structure and form (polydisperse case) 2) D ETERMINATION OF S inter (q) app  Monte Carlo Simulation of polydisperse aggregates  Estimation of  agg : TEM  fract Same Working hypothesis 6 S app (q) depends on local  si in the branches =  agg inter

7 S ELF C ONSISTENT M ODEL  Final determination of  Results: decreases slightly  constant !  increases slightly  si (nm)   N agg 8.4%v40.20.315153 12.7%v35.90.334043 16.8%36.10.364447 21.1%35.20.384447 7 I(q) is read Experimental I(q) = f(  )  saxs

Download ppt "I MPACT OF THE FILLER FRACTION IN NC S G. Baeza et al. Macromolecules 2013 Multi-scale filler structure in simplified industrial nanocomposite systems."

Similar presentations

Nanolatex based nanocomposites: control of the filler structure and reinforcement. A. Banc 1 *, A-C. Genix 1, C. Dupas, M. Chirat 1, S.Caillol 2, and J.Oberdisse.

Nanolatex based nanocomposites: control of the filler structure and reinforcement. A. Banc 1 *, A-C. Genix 1, C. Dupas, M. Chirat 1, S.Caillol 2, and J.Oberdisse.
Metabolic theory and ecological scaling Geoffrey WestJames Brown Brian Enquist.

Metabolic theory and ecological scaling Geoffrey WestJames Brown Brian Enquist.
Nucleation and Nanoparticle Growth in Flame Aerosol Process by USAXS Nikhil Agashe, Greg Beaucage, Doug Kohls – Dept. of Chemical and Materials Engineering,

Nucleation and Nanoparticle Growth in Flame Aerosol Process by USAXS Nikhil Agashe, Greg Beaucage, Doug Kohls – Dept. of Chemical and Materials Engineering,
Approaches to Data Acquisition The LCA depends upon data acquisition Qualitative vs. Quantitative –While some quantitative analysis is appropriate, inappropriate.

Approaches to Data Acquisition The LCA depends upon data acquisition Qualitative vs. Quantitative –While some quantitative analysis is appropriate, inappropriate.
 Product design optimization Process optimization Reduced experimentation Physical system Process model Product model Product Market need Multiscale Modeling.

 Product design optimization Process optimization Reduced experimentation Physical system Process model Product model Product Market need Multiscale Modeling.
Anatoly B. Kolomeisky Department of Chemistry MECHANISMS AND TOPOLOGY DETERMINATION OF COMPLEX NETWORKS FROM FIRST-PASSAGE THEORETICAL APPROACH.

Anatoly B. Kolomeisky Department of Chemistry MECHANISMS AND TOPOLOGY DETERMINATION OF COMPLEX NETWORKS FROM FIRST-PASSAGE THEORETICAL APPROACH.
Statistical Full-Chip Leakage Analysis Considering Junction Tunneling Leakage Tao Li Zhiping Yu Institute of Microelectronics Tsinghua University.

Statistical Full-Chip Leakage Analysis Considering Junction Tunneling Leakage Tao Li Zhiping Yu Institute of Microelectronics Tsinghua University.
Scattering Experiments

Scattering Experiments
Bridging the solution divide: comprehensive structural analyses of dynamic RNA, DNA, and protein assemblies by small-angle X-ray scattering By Rambo and.

Bridging the solution divide: comprehensive structural analyses of dynamic RNA, DNA, and protein assemblies by small-angle X-ray scattering By Rambo and.
1 Hadronic In-Situ Calibration of the ATLAS Detector N. Davidson The University of Melbourne.

1 Hadronic In-Situ Calibration of the ATLAS Detector N. Davidson The University of Melbourne.
Calculation of Similarity (Chernoff et al. 1999, 2000, 2001) 1. Observed Similarity = mean of 200 random sub- samples of larger population at size of smaller.

Calculation of Similarity (Chernoff et al. 1999, 2000, 2001) 1. Observed Similarity = mean of 200 random sub- samples of larger population at size of smaller.
Homework Answers (1-2 Worksheet)

Homework Answers (1-2 Worksheet)
Measurement and Evolution of Online Social Networks Review of paper by Ophir Gaathon Analysis of Social Information Networks COMS 6998-2, Spring 2011,

Measurement and Evolution of Online Social Networks Review of paper by Ophir Gaathon Analysis of Social Information Networks COMS , Spring 2011,
L. Karklin, S. Mazor, D.Joshi1, A. Balasinski2, and V. Axelrad3

L. Karklin, S. Mazor, D.Joshi1, A. Balasinski2, and V. Axelrad3
NanotechnologyNanoscience Modeling and Simulation Develop models of nanomaterials processing and predict bulk properties of materials that contain nanomaterials.

NanotechnologyNanoscience Modeling and Simulation Develop models of nanomaterials processing and predict bulk properties of materials that contain nanomaterials.
Computational Lab in Physics: Final Project Monte Carlo Nuclear Collisions: Glauber Model.

Computational Lab in Physics: Final Project Monte Carlo Nuclear Collisions: Glauber Model.
Increased surface area on nanoparticles

Increased surface area on nanoparticles
1 Theoretical Physics Experimental Physics Equipment, Observation Gambling: Cards, Dice Fast PCs Random- number generators Monte- Carlo methods Experimental.

1 Theoretical Physics Experimental Physics Equipment, Observation Gambling: Cards, Dice Fast PCs Random- number generators Monte- Carlo methods Experimental.
STRUCTURE PECULIARITIES OF α- CRYSTALLIN STUDIED BY SMALL ANGLE NEUTRON AND X-RAY SCATTERING T.N. Murugova 1, O.I. Ivankov 1,5, A.I. Kuklin 1,3, K.O. Muranov.

STRUCTURE PECULIARITIES OF α- CRYSTALLIN STUDIED BY SMALL ANGLE NEUTRON AND X-RAY SCATTERING T.N. Murugova 1, O.I. Ivankov 1,5, A.I. Kuklin 1,3, K.O. Muranov.
Generalized Indirect Fourier Transformation (GIFT) (see B. Weyerich, J. Brunner-Popela & O. Glatter, J. Appl. Cryst. (1999) 32, 197-209. Small- angle scattering.

Generalized Indirect Fourier Transformation (GIFT) (see B. Weyerich, J. Brunner-Popela & O. Glatter, J. Appl. Cryst. (1999) 32, Small- angle scattering.

Similar presentations

Ads by Google