1 / 23

Physics and Chemistry of Hybrid Organic-Inorganic Materials Lecture 3: Properties of Hybrids

Physics and Chemistry of Hybrid Organic-Inorganic Materials Lecture 3: Properties of Hybrids. Key points. Mechanical properties are strength, modulus, toughness, hardness, elasticity. Thermal properties of interest include onset of degradation, glass transition temperature, and melting point.

lena
Download Presentation

Physics and Chemistry of Hybrid Organic-Inorganic Materials Lecture 3: Properties of Hybrids

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Physics and Chemistry of Hybrid Organic-Inorganic MaterialsLecture 3: Properties of Hybrids

  2. Key points • Mechanical properties are strength, modulus, toughness, hardness, elasticity. • Thermal properties of interest include onset of degradation, glass transition temperature, and melting point. • Optical properties include transparency, absorption, scattering, refractive index, etc. • Electric properties include conductivity and dielectric.

  3. What properties of hybrids are of interest? • strength • modulus • toughness • transparency • conductivity • Stability • special properties Do not forget baseline (control) measurements.

  4. Strength of Materials Force vs. extension • Tensile (Shown) is force used to pull a sample apart. • Compressive strength is the force used to crush. • Flexural strength is the force used to bend and break. • Work or energy per cross-sectional area (kJ/m or Pa) or force per distance (kN/m) • theoretical strength = bond strength/cross sectional area • real strength = function of defects

  5. Stress-Strain Analysis

  6. Properties: Strength

  7. Modulus of Materials • Rigidity of material (kJ/m2 or Pa) • Related to Morse potential • Slope of elastic zone of stress strain curve MPa ΔLength/initial Length

  8. Modulus of hybrid materials changes less with temperature than organics °°°°°°° •••••• B. K. Coltrain, C. J. T. Landry, J. M. O’Reilly, A. M. Chamberlain, G. A. Rakes, J. S. Sedita, L. W. Kelts, M. R. Landry and V. K. Long, Chem. Mater., 1993, 5, 10, 1445–1455.

  9. Toughness • Energy required to break (Pa or kJ/m2). • Integral of stress strain curve MPa ΔLength/initial Length

  10. Mechanical characterization of polymers • Stress-strain curves: • Young’s modulus (brittleness) • Tensile strength-pull sample appart • Flexural strength- bend until it breaks • Compressive strength-crush sample • Dynamic mechanical analyses (same info as above but with cyclic application of stress or strain. • Generate modulus temperature curves • Fatigue studies to predict failure under cyclic stress

  11. Properties of Hybrids: high specific strength Ashby plot Organics are considerably less dense than inorganics (glasses, ceramics & metals). Hybrids (composites) are also less dense than inorganics because of their organic component

  12. Why hybrid organic inorganic materials: They are stronger than the organic by itself Ashby plot Inorganics (glasses, ceramics & metals) are stronger than organics . Hybrids (composites) are also stronger than inorganics because of their organic component

  13. What is the origin of mechanical properties? • Theoretically, mechanical properties depend on bond strengths • In practice, mechnical properties are ruled by defects, morphological features, and non-bonding interactions that give rise to ductility, flexibility, viscoelasticity and limit the ultimate strength.

  14. Bonding (& non-bonding)interactions • London forces < 1 kJ/mole • Dipole-dipole 10 kJ/mole • Hydrogen Bonding 20-40 kJ/mole • Charge-charge interactions 0-100 kJ/mole • Covalent bonds 150-600 kJ/mole 1 kJ mol-1 = 0.4 kT per molecule at 300 K

  15. Covalent Bond Dissociation Energies Two electrons per bonding molecular orbital Si-Si 221 kJ/mole Si-C 300 kJ/mole C-C 350 kJ/mole C-O 375 kJ/mole C-H 415 kJ/mole Al-O 480 kJ/mole Si-O 531 kJ/mole Ti-O 675 kJ/mole Zr-O 750 kJ/mole BDE = potential energy, -dU Force (N or kgms-2) to break a bond = -dU/dr Strength of a bond (Nm-2 or Pa) = Force/cross section area

  16. Origin of strength and modulus: Modulus~ curvature at bottom of well (and strength ~ depth of well) The reality: defects in materials, lower strength by more than 10X

  17. For example, Polymers are weaker than predicted Linear Macromolecules under tension causes polymers to disentangle • Entanglements & non-bonding interactions in linear polymers • Covalent bonds only break with short time scale • Cross-linking with covalent bonds makes materials stronger but more brittle

  18. Transparency • No absorptions due to electronic or vibrational transitions • Scattering from interfaces between phases with large differences in refractive index • 784 × 100 Rayleigh Scattering Two phase system with dispersed phase much smaller in dimension than wavelengths of light. Blue is scattered more than red.

  19. Mie scattering scattering from non-absorbing interfaces with roughness similar to wavelengths of light

  20. Douglas A. Loy, J. Non-Crystal. Solids 2013, 362, 82-94.

  21. Conductivity • electrical • ionic • thermal • Flame resistant ThermobloK

  22. Stability PEHS • thermal • chemical • radiation • biological Polymer 2010, 51, 2296

  23. Conclusions • Properties of hybrid organic-inorganic materials are often better than either organic or inorganic • Addition of Inorganic improves strength, stability, hardness, abrassion resistance compared with organic • Addition of organic polymer, improves flexibility, elasticity, toughness, and transparency compared with theinorganic

More Related