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mat e 423

MatE 423. Thermal Expansion of Glass. 2. Thermal Expansion of Glass. Thermal expansion determines if a glass will be shock resistant, able to withstand high thermal stressesThermal expansion also determines if a glass will have low thermal shock resistanceSmall thermal expansion coefficient leads to high thermal shock resistanceLarge thermal expansion leads to low thermal shock resistance DTshock= E(1 n)/a.

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mat e 423

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    1. Mat E 423 Physical Properties of Glass 2: Thermal Expansion Coefficient Understand how the thermal expansion coefficient depends upon temperature, cooling rate, interatomic bonding, and composition Understand and be able to use relative order of magnitude values for the thermal expansion coefficient for various oxide glasses Be able to estimate thermal expansion coefficient for oxide glasses using simple additive factors models

    2. MatE 423 Thermal Expansion of Glass 2

    3. MatE 423 Thermal Expansion of Glass 3 Thermal Expansion of Glass Thermal Expansion also determines whether a glass can be thermally “tempered” to increase its strength High thermal expansion leads to high tempering ability Low thermal expansion leads to low tempering ability

    4. MatE 423 Thermal Expansion of Glass 4 Thermal Expansion of Materials Most materials expand as they are heated Some more than others Refractory metals and ceramics Expand less Polymers Expand more Some materials expand very little SiO2 glass b-spodumene, Li2O.Al2O3.4SiO2 Complex systems with more than one material must have matched or compensated thermal expansions

    5. MatE 423 Thermal Expansion of Glass 5 Typical Thermal Expansion Coefficients of Materials

    6. MatE 423 Thermal Expansion of Glass 6 Thermal Expansion Values of Materials

    7. MatE 423 Thermal Expansion of Glass 7 Thermal expansion of Crystals Polycrystalline materials under go phase transformations Thermal expansion changes at each phase transition c-SiO2 has numerous phase changes and numerous volume changes that must be accounted for during heat up of systems using SiO2

    8. MatE 423 Thermal Expansion of Glass 8 Thermal Expansion of Crystals

    9. MatE 423 Thermal Expansion of Glass 9 Measurement of the thermal expansion Expansion dilatometer Thermal mechanical analyzer Measures the length of the sample Typically a glass rod 0.5 cm x 1 cm As a function of temperature Linear Variable Differential Transducer (LVDT) accurately converts distance changes of microns into millivolts. T/C measures sample temperature Furnace provides sample heating and/or cooling Typically slow heating rate 3oC/min

    10. MatE 423 Thermal Expansion of Glass 10 Typical Pushrod Dilatometer

    11. MatE 423 Thermal Expansion of Glass 11 Thermal Expansion of Glass For isotropic materials, homogeneous in three directions,… Volume expansion coefficient is 3 times larger than linear expansion Glasses are isotropic Fine grained polycrystals are isotropic

    12. MatE 423 Thermal Expansion of Glass 12 Determination of Linear Thermal Expansion Determine aL for 100 – 200, 200 – 300, 100 – 500oC ranges

    13. MatE 423 Thermal Expansion of Glass 13 Temperature Dependence of Thermal Expansion Glass undergoes glass transition and transform to supercooled liquid at Tg Liquid has a larger ? At softening point, liquid begins to be compressed by force of applied dilatometer, “dilatometric hook” Tg measured by dilatometry is called Td and is often < than Tg measured by DTA DTA scans at 10 – 20oC/min, dilatometry is done at 3-5oC/min

    14. MatE 423 Thermal Expansion of Glass 14 Temperature Dependence of Thermal Expansion Properties of glass depend upon cooling rate Heating rate of dilatometry is slow and as such well annealed samples, or those cooled at the same slow rate must be used Fast quenched glasses will undergo “sub-Tg” relaxations, i.e., they try to relax to slower cooling rate curve Eventually, glass undergoes transition at Td(Tg)

    15. MatE 423 Thermal Expansion of Glass 15 Temperature Dependence of Thermal Expansion As fast cooled glass is reheated and approaches Tg The structure begins to “loosen” Structural relaxation time begins to shorten Time is available for the glass to try to relax “down” to the slow cooled curve As glass glass shrinks, it exhibits a negative thermal expansion The greater the mismatch between qc and qh, the greater the sub-Tg relaxation event

    16. MatE 423 Thermal Expansion of Glass 16 Thermal Expansion Coefficients for Various Glasses

    17. MatE 423 Thermal Expansion of Glass 17 Thermal Expansion of Alkali Silicate Glasses As alkali is added, thermal expansion increases Tg decreases with added modifier Lowest modifier shows anomalous ‘plateau” above Tg Liquid does not fully relax as it should Low soda silicate glasses exhibit phase separation Liquid phase separates into high silica and high alkali glasses, two glasses with different Tgs High silica liquid does not undergo Tg until higher temperatures

    18. MatE 423 Thermal Expansion of Glass 18 Thermal Expansion of Alkali Silicates Thermal Expansion coefficient increases with alkali modifier Expansion coefficient is larger for the the larger alkali's aK > aNa > aLi Taken as an average value from 150 to 300oC

    19. MatE 423 Thermal Expansion of Glass 19 Thermal Expansion of Alkali Borate Glasses Addition of alkali modifier decreases thermal expansion coefficient in alkali borate glasses Modifier in low alkali borate glasses, cross links glass structure Creation of tetrahedral borons Adding bonds to boron, increasing connectivity of network Strengthening the network Rigidity of the glassy network increases Thermal expansion decreases with modifier

    20. MatE 423 Thermal Expansion of Glass 20 Ultra-low expansion (ULE) glass

    21. MatE 423 Thermal Expansion of Glass 21 Correlation of Thermal Expansion with structure Materials expand by their average bond length increasing Glasses are disordered, so expansion is isotropic Expansion is governed by the interatomic potential well that binds the atoms and ions together Tightly bound atoms reside in deep energy wells that are only slightly affected by temperature More weakly bound atoms reside in shallow energy wells that are more affected by temperature NBOs increase thermal expansion, Bos decrease thermal expansion

    22. MatE 423 Thermal Expansion of Glass 22 Calculation of Thermal Expansion Coefficients Thermal expansion like many properties are continuous with glass composition Each oxide may have a predictable affect on the thermal expansion coefficient Assuming a linear relationship between composition and thermal expansion coefficient Thermal expansion can be calculated within limited composition ranges for many different glasses

    23. MatE 423 Thermal Expansion of Glass 23 Calculating Thermal Expansion Coefficients

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