In an extension of our current studies of volume-based thermodynamics and thermoelasticity (VBT), we here consider the parameters at ambient temperature of the dimensionless Gruneisen ratio (or Gruneisen parameter), γth, which is a standard descriptor of the thermophysical properties of solids: γth=αKTVm/Cv=αVm/ βCv. It has earlier been established that the isothermal volume compressibility, β (which is the reciprocal of the bulk modulus, KT), and the ambient-temperature heat capacity, Cp, are strongly linearly correlated with the molar volume, Vm, among groups of materials with similar structures. Here, we examine possible correlations between the volumetric thermal expansion coefficient, α (the remaining Gruneisen parameter), and molar volume. Using the high-temperature limiting value, α°, as a surrogate for α, we find that α is essentially uncorrelated with volume among a range of materials. As a consequence of the lack of correlation through volume of α with the other Gruneisen parameters, we conclude that the dimensionless Gruneisen ratio at ambient temperatures itself is thereby poorly constant across materials and cannot be reliably used for predictive purposes. It is noted that, for thermodynamic reasons, the values of γth generally range from about 0.5 to 3, clustering around 2

Glasser, Leslie

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NOTICE: this is the author’s version of a work that was accepted for publication in Journal of Physics and Chemistry of Solids. Changes resulting from the publishing process, such as peer review, editing, corrections, structural formatting, and other quality control mechanisms may not be reflected in this document. Changes may have been made to this work since it was submitted for publication. A definitive version was subsequently published in Journal of Physics and Chemistry of Solids, 73, 1 (2012).  DOI http://dx.doi.org/10.1016/j.jpcs.2011.10.008  1     Volume-Based Thermoelasticity: Thermal expansion coefficients and the Grüneisen Ratio  Leslie Glasser* Nanochemistry Research Institute, Department of Applied Chemistry Curtin University, GPO Box U1987, Perth, WA 6845, Australia E-mail: l.glasser@curtin.edu.au  2 Figures 1 Supplementary Table  *Corresponding author  L. Glasser:  Telephone: + 61 8 9266-3126 Fax: + 61 8 9266-4699 2  Abstract  In an extension of our current studies of volume-based thermodynamics and thermoelasticity (VBT), we here consider the parameters at ambient temperature of the dimensionless Grűneisen ratio (or Grűneisen parameter), γth, which is a standard descriptor of the thermophysical properties of solids:  / /th T m v m vK V C V C      It has earlier been established that the isothermal volume compressibility, β (which is the reciprocal of the bulk modulus, KT), and the ambient-temperature heat capacity, Cp, are strongly linearly correlated with the molar volume, Vm, among groups of materials with similar structures. Here, we examine possible correlations between the volumetric thermal expansion coefficient, α (the remaining Grűneisen parameter), and molar volume. Using the high-temperature limiting value, ao, as a surrogate for α, we find that α is essentially uncorrelated with volume among a range of materials. As a consequence of the lack of correlation through volume of α with the other Grűneisen parameters, we conclude that the dimensionless Grűneisen ratio at ambient temperatures itself is thereby poorly constant across materials and cannot be reliably used for predictive purposes. It is noted that, for thermodynamic reasons, the values of γth generally range from about 0.5 to 3, clustering around 2.    3  1. Introduction Thermodynamics is fundamental to understanding of the behaviour of materials, both chemical and physical.  Experimental thermodynamics is, however, not much practised because it is demanding and difficult; as a consequence, thermodynamic data is unavailable for many materials. This data absence can, at least partially, be filled by theoretical methods but these, too, are demanding and require specialist expertise. This provides the opportunity for the use of empirical predictive methods based upon extrapolations from the behaviour of related materials.  While the resulting values may be approximate, they fill important data gaps.  Over recent years, colleagues and I have developed empirical volume-based thermodynamic (VBT) correlations by which thermodynamic quantities, such as entropies, heat capacities, lattice enthalpies and formation enthalpies, may be reliably estimated by linear correlation with molar (or formula unit) volume, Vm, across ranges of generally ionic materials, independent of structural details.[1-4] Extending beyond standard chemical thermodynamics, we have lately also examined thermoelastic relations, observing that compressibility, β, is proportional to formula volume within groups of materials of similar structure and with a common anion (for example, silicate clinopyroxenes (ABSi2O6), chalcopyrites (ABX2) and perovskites (ABO3)).[5, 6]   The thermodynamic and thermoelastic parameters of a solid are conveniently related through the dimensionless Grűneisen ratio (or Grűneisen parameter):[7-10] / /th T m v m vK V C V C      4  where Cv = heat capacity under conditions of constant volume and    2 2 /v p m T p mC C V K T C V T       with Cp = heat capacity under conditions of constant pressure α, the coefficient of cubic thermal expansion, = 1 mm pVV T    while the compressibility, β or κ, is defined by 1 1 1, ,mTTVV p B K        Here, the bulk modulus, B or KT, which is the reciprocal of the coefficient of isothermal compressibility, represents the resistance to bulk compression of the material (also known as the incompressibility) and is the form generally favoured by geophysicists.  The Grűneisen ratio, which relates thermophysical constants of solid ionic materials, sets limitations on the thermophysical properties of materials.[7, 10]  It is variously defined: in particular it has definitions both in the microscopic domain and in the macroscopic domain. In the microscopic domain it relates to vibrational frequencies within the solid while in the macroscopic version (which is the form under consideration here), γth measures the change in pressure resulting from an increase in energy density at constant volume. In its macroscopic form, it enters into equations of state (EoS) for matter in condensed phases and thus is of particular value in respect of high-temperature and -pressure conditions, for example in the study of the earth’s interior and, more generally, in the study of the extra-terrestrial planets. Its value at ambient pressure is generally close to 2, lying roughly between 0.5 and 3. It is very approximately independent of 5  temperature and generally decreases in value as the volume decreases under pressure.[7-9]  Since the linear relations between β and Vm and between Cp and Vm under ambient conditions have previously been established,[1, 5, 6] it becomes worthwhile to consider whether a further relation can be established between the thermal quantities, α and Vm, which would then illuminate the behaviour of the Grűneisen ratio across materials. (Note: the difference between Cp and Cv is small for solids and graphs of Cp and Cv versus Vm show very similar behaviour, so that they will be considered to be equivalent for present purposes.)   There are established thermodynamic reasons (which are noted elsewhere[11, 12]) which explain the clustering of the Grűneisen ratio around a value of 2, as follows:  1 11 (5 1) 22 2TthKp        using the relation [13]: 5TKp    2. Results In the extensive compilation of Holland and Powell,[14] the cubic thermal expansion coefficient, αT, is represented by a thermal expansion parameter, ao (with the equivalent units, K-1), which corresponds to its high-temperature limit.  While this is not the exact quantity required for the Grűneisen ratio, it will serve as a suitable surrogate and, indeed, 6  has the useful feature that it provides values at the equivalent corresponding state for all the materials here considered.  Fig. 1 is a plot of this thermal expansion parameter, ao, versus Vm for a wide range of inorganic materials. There is no reasonable correlation discernible. It may be observed in Fig. 2 that ao ranges in value from about 1 to 10, centred quite strongly around 5 and 6.   Figure 1: Plot of the thermal expansion parameter, ao, versus formula unit volume, Vm, for a wide range of inorganic materials.  No reasonable correlation can be discerned.    02468100.0 0.1 0.2 0.3 0.4ao / K-1 Vm / nm3 ortho-ring pyrox amphibole other chain micas chlorite other sheet frame oxides 7   Figure 2: Frequency distribution of the thermal expansion parameter, ao. The ten materials with the lowest values of ao are quartzes (classified as framework structures) and 6-member ring magnesium aluminium cyclosilicates (cordierites and osumilites).[14]  3. Discussion and Conclusion Since the cubic thermal expansion parameter, ao, does not show any reasonable correlation with volume, in contrast with the compressibility, β, and heat capacity, Cv or Cp, we can conclude that the Grűneisen ratio itself is thereby poorly correlated with volume across different materials. The small variability which is observed may be ascribed to the range in values of the thermal expansion parameter seen in Fig. 1, from about 1 to 10, quite strongly centred around 5 and 6.  As a consequence of these observations, we may conclude that simple empirical relations will be unsuitable for prediction of values of the Grűneisen ratio among ionic solids. 0102030401 2 3 4 5 6 7 8 9 10 11ao / K-1 8  References [1] L. Glasser, H.D.B. Jenkins, Ambient Isobaric Heat Capacities, Cp,m, for ionic solids and liquids: an Application of Volume-Based Thermodynamics (VBT), Inorg. Chem., 50 (2011) 8565-8569. [2] L. Glasser, H.D.B. Jenkins, Predictive thermodynamics for condensed phases, Chem. Soc. Rev., 34 (2005) 866-874. [3] L. Glasser, H.D.B. Jenkins, Volume-Based Thermodynamics: A Prescription for Its Application and Usage in Approximation and Prediction of Thermodynamic Data, J. Chem. Eng. Data, 56 (2011) 874-880. [4] H.D.B. Jenkins, L. Glasser, Thermodynamic Difference Rules: A Prescription for their Application and Usage to Approximate Thermodynamic Data, J. Chem. Eng. Data, 55 (2010) 4231-4238. [5] L. Glasser, Volume-Based Thermoelasticity: Compressibility of Inorganic Solids, Inorg. Chem., 49 (2010) 3424-3427. [6] L. Glasser, Volume-Based Thermoelasticity: Compressibility of Mineral-Structured Materials, J. Phys. Chem. C, 114 (2010) 11248-11251. [7] J.-P. Poirier, Introduction to the Physics of the Earth's Interior, 2nd Edition ed., Cambridge University Press, Cambridge, U.K., 2000. [8] O.L. Anderson, Equations of State of Solids for Geophysics and Ceramic Science, Oxford Univ. Press, Oxford, 1995. [9] O.L. Anderson, The Grűneisen ratio for the last 30 years, Geophys. J. Intl., 143 (2000) 279-294. [10] L. Vočadlo, J.-P. Poirier, G.D. Price, Grüneisen parameters and isothermal equations of state, Am. Miner., 85 (2000) 390-395. [11] J. Ledbetter, S. Kim, Handbook of Elastic Properties of Solids, Liquids and Gases, Vol. II, Chap. 8 ed., Academic Press, San Diego, 2001. [12] Y. Chang, On the temperature dependence of the bulk modulus and the Anderson-Grüneisen parameter δ of oxide compounds, J. Phys. Chem. Solids, 28 (1967) 697-701. [13] I.C. Sanchez, J. Cho, W.-J. Chen, Compression of liquids and solids: universal aspects, J. Phys. Chem., 97 (1993) 6120-6123. [14] T.J.B. Holland, R. Powell, An internally consistent thermodynamic data set for phases of petrological interest, J. metamorphic Geol., 16 (1998) 309-343.    Volume-Based Thermoelasticity: Thermal expansion coefficients and the Grüneisen Ratio Leslie Glasser* Nanochemistry Research Institute, Department of Applied Chemistry Curtin University, GPO Box U1987, Perth, WA 6845, Australia E-mail: l.glasser@curtin.edu.au Table S1:  Thermal expansion parameter, ao, versus formula unit volume, Vm, for a wide range of inorganic materials, from the extensive compilation of Holland and Powell.1   V ao End-membera / nm3 / K-1 Ortho-Ring   akermanite 0.1537 5.08 almandine 0.1911 4.03 andalusite 0.0856 4.11 andradite 0.2193 3.93 clinohumite 0.3278 5.00 clinozoisite 0.2263 4.60 epidote 0.2310 5.05 fayalite 0.0769 5.05 Fe-chloritoid 0.1159 5.42 Fe-cordierite 0.3937 0.76 Fe-epidote 0.2356 5.05 Fe-staurolite/3 0.2484 1.20 ferrosumilite 0.6363 0.80 forsterite 0.0725 6.13 gehlenite 0.1499 4.17 grossular 0.2082 3.93 hydrous cordierite 0.3873 0.76 kyanite 0.0733 4.04 larnite 0.0857 5.05 lawsonite 0.1682 5.82 merwinite 0.1635 6.15 Mg-chloritoid 0.1142 5.42 Mg-cordierite 0.3873 0.76 Mg-staurolite/3 0.2450 1.20 Mn-chloritoid 0.1191 5.42 Mn-cordierite 0.3990 0.76 Mn-staurolite/3 0.2516 1.20 monticellite 0.0855 5.63 osumilite(1) 0.6292 0.76 osumilite(2) 0.6383 0.76 phase A 0.2564 8.26 pumpellyite 0.4907 5.00 pyrope 0.1879 4.36 rankinite 0.1603 6.50 sillimanite 0.0828 2.21 spessartine 0.1958 4.62 sphene 0.0924 4.20 spurrite 0.2441 6.50 tephroite 0.0814 5.05 tilleyite 0.2829 6.50 hydroxytopaz 0.0887 4.04 vesuvianite/10 0.1415 5.00 zircon 0.0652 2.22 zoisite 0.2254 6.70 Pyroxenes   acmite 0.1073 4.66 Ca-schermak pyroxene 0.1055 4.43 diopside 0.1099 5.70 enstatite 0.1040 5.05 ferrosilite 0.1095 6.32 hedenbergite 0.1128 5.70 jadeite 0.1003 4.66 Mg-schermak pyroxene 0.0978 5.08 pseudowollastonite 0.0666 5.39 pyroxmangite 0.0577 5.08 rhodonite 0.0580 5.08 wollastonite 0.0663 4.60 Amphiboles   anthophyllite 0.4407 5.00 cummingtonite 0.4372 5.00 Fe-glaucophane 0.4415 5.30 Fe-anthophyllite 0.4628 5.00 ferroactinolite 0.4696 5.34 gedrite 0.4284 4.80 glaucophane 0.4326 5.30 grunerite 0.4623 5.00 pargasite 0.4515 5.34 riebeckite 0.4565 5.30 tremolite 0.4528 5.34 tschermakite 0.4450 5.34 Other   deerite/10 0.0926 5.00 Fe-carpholite 0.1775 5.00 Fe-sapphirine 0.3386 4.90 Mg-carpholite 0.1759 5.00 sapphirine(221) 0.3300 4.90 sapphirine(793) 0.3284 4.90 Micas   annite 0.2563 5.79 celadonite 0.2331 5.96 eastonite 0.2450 5.79 Fe-celadonite 0.2366 5.96 margarite 0.2153 4.87 Mn-biotite 0.2535 5.79 muscovite 0.2339 5.96 Na-phlogopite 0.2400 5.79 paragonite 0.2194 7.74 phlogopite 0.2485 5.79 Chlorites 0.0000  Al-free chlorite 0.3597 3.98 amesite 0.3408 3.98 clinochlore 0.3502 3.98 daphnite 0.3544 3.98 Fe-sudoite 0.3388 3.98 Mn-chlorite 0.3751 3.98 sudoite 0.3371 3.98 Other 0.0000  antigorite/10 0.2914 4.70 chrysotile 0.1784 4.70 Fe-talc 0.2362 3.70 kaolinite 0.1650 5.10 prehnite 0.2329 5.10 pyrophyllite 0.2127 5.10 talc 0.2263 3.70 tschermaks talc 0.2243 3.70 Oxides   baddeleyite 0.0351 3.76 corundum 0.0425 4.19 geikielite 0.0512 4.95 hematite 0.0503 5.99 hercynite 0.0677 3.95 ilmenite 0.0526 4.95 lime 0.0278 6.65 magnesioferrite 0.0740 6.96 magnetite 0.0739 6.96 manganosite 0.0220 6.30 nickel oxide 0.0182 6.20 periclase 0.0187 6.20 pyrophanite 0.0546 4.95 rutile 0.0313 4.43 spinel 0.0661 4.31 ulvospinel 0.0777 6.90 Hydroxides   brucite 0.0409 13.00 diaspore 0.0295 7.97 goethite 0.0346 7.97 Framework   albite 0.1662 4.56 analcite 0.1617 5.00 anorthite 0.1674 2.38 coesite 0.0343 1.80 cristobalite 0.0433 0.81 heulandite 0.5281 2.38 high albite 0.1679 4.56 kalsilite 0.1003 5.76 laumontite 0.3383 2.38 leucite 0.1466 3.67 meionite 0.5643 3.16 microcline 0.1809 3.35 nepheline 0.0900 8.10 quartz 0.0377 0.65 sanidine 0.1810 3.35 stilbite 0.5458 2.38 stishovite 0.0233 2.50 tridymite 0.0448 0.50 wairakite 0.3162 2.38  a The formulae of very complex materials have been divided by an appropriate factor, for example vesuvianite/10, in order that their weighting in fitting processes is not excessive. 1. Holland, T. J. B.; Powell, R. J. metamorphic. Geol. 1998, 16, 309-343.   

Volume-based thermoelasticity: Thermal expansion coefficients and the Gruneisen ratio

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Volume-based thermoelasticity: Thermal expansion coefficients and the Gruneisen ratio

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