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Journal of Materials Science

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26.02.2019 | Computation and theory

Landau–Devonshire thermodynamic potentials for displacive perovskite ferroelectrics from first principles

verfasst von: Krishna Chaitanya Pitike, Nasser Khakpash, John Mangeri, George A. Rossetti Jr., Serge M. Nakhmanson

Erschienen in: Journal of Materials Science | Ausgabe 11/2019

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Abstract

A general approach for fitting Landau–Devonshire thermodynamic potentials directly from first principles is developed for simple displacive ferroelectric perovskite materials. As the first step, a \(\hbox {PbTiO}_3\) potential is parameterized completely from density functional theory calculations as a test case, under the only assumption that the transition between the non-polar and polar phases is of first order. The utility of this approach is assessed by comparing quantities characterizing the phase transition, dielectric and piezoelectric properties and equibiaxial strain–temperature phase diagrams with the predictions of several thermodynamic potentials parameterized from experimental data. In the second step, a similar parameterization is generated for a fictitious polar perovskite \(\hbox {SnTiO}_{3}\), enabling us to predictively evaluate an approximate ‘equibiaxial strain–temperature–spontaneous polarization’ phase diagram for its thin films.

Vorheriger Artikel Data-enabled structure–property mappings for lanthanide-activated inorganic scintillators

Nächster Artikel Application of radial basis neural network to transform viscoelastic to elastic properties for materials with multiple thermal transitions

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See also BESAC report “From Quanta to the Continuum: Opportunities for Mesoscale Science” available from http://science.energy.gov/ as well as the complete volume 40 of the MRS Bulletin from November 2015.

There is no reason why this need be the case. If the Landau polynomial is convergent, the temperature-dependent terms play a minor role near the phase transition where the polynomial becomes asymptotically accurate. At lower temperatures, however, these terms may become important. This is the case, for example, in barium titanate.

Laughlin RB, Pines D, Schmalian J, Stojković BP, Wolynes P (2000) The middle way. PNAS 97:32

Crabtree G, Sarrao J (2012) Opportunities for mesoscale science. MRS Bull. 37:1079

Sarrao J, Crabtree G (2015) Progress in mesoscale science. MRS Bull. 40:919

Provatas N, Elder K (2010) Phase-Field methods in materials science and engineering. Wiley, New York

Mangeri J et al (2017) Topological phase transformations and intrinsic size effects in ferroelectric nanoparticles. Nanoscale 9:1616

Mangeri J, Alpay SP, Nakhmanson S, Heinonen OG (2018) Electromechanical control of polarization vortex ordering in an interacting ferroelectric-dielectric composite dimer. Appl Phys Lett 113:092901

Pitike KC et al (2018) Metastable vortex-like polarization textures in ferroelectric nanoparticles of different shapes and sizes. J Appl Phys 124:064104

Weiss CV et al (2009) Compositionally graded ferroelectric multilayers for frequency agile tunable devices. J Mater Sci 44:5364. https://doi.org/10.1007/s10853-009-3514-8

Sun F-C, Kesim MT, Espinal Y, Alpay SP (2016) Are ferroelectric multilayers capacitors in series? J Mater Sci 51:499. https://doi.org/10.1007/s10853-015-9298-0

10.

Misirlioglu IB, Sen C, Kesim MT, Alpay SP (2016) Low-voltage ferroelectric-paraelectric superlattices as gate materials for field-effect transistors. J Mater Sci 51:487. https://doi.org/10.1007/s10853-015-9301-9

11.

Landau L, Lifshitz E (1959) Statistical physics. Pergamon Press, Oxford

12.

Devonshire A (1954) Theory of ferroelectrics. Adv Phys 3:85

13.

Strukov BA, Levanyuk AP (1998) Ferroelectric phenomena in crystals, physical foundations. Springer, Berlin

14.

Chen L-Q (2007) Appendix A—Landau free-energy coefficients. Springer, Berlin, pp 363–372

15.

Salje E (1990) Phase transitions in ferroelastic and co-elastic crystals. Ferroelectrics 104:111

16.

Amin A, Haun MJ, Badger B, McKinstry H, Cross LE (1985) A phenomenological Gibbs function for the single cell region of the \(\text{ PbZrO }_{3}:\text{ PbTiO }_{3}\) solid solution system. Ferroelectrics 65:107

17.

Rossetti GA Jr, Cline JP, Navrotsky A (1998) Phase transition energetics and thermodynamic properties of ferroelectric \(\text{ PbTiO }_3\). J Mater Res 13:3197

18.

Rossetti GA Jr, Maffei N (2005) Specificheat study and Landau analysis of the phase transition in\(\text{ PbTiO }_3\) single crystals. J Phys Condens Matter 17:3953

19.

Haun MJ, Furman E, Jang SJ, McKinstry HA, Cross LE (1987) Thermodynamic theory of \(\text{ PbTiO }_3\). J Appl Phys 62:3331

20.

Heitmann AA, Rossetti GA Jr (2014) Thermodynamics of ferroelectric solid solutions with morphotropic phase boundaries. J Am Ceram Soc 97:1661

21.

Li YL, Hu SY, Liu ZK, Chen LQ (2001) Phase-field model of domain structures in ferroelectric thin films. Appl Phys Lett 78:3878

22.

Li Y, Hu S, Liu Z, Chen L (2002) Effect of substrate constraint on the stability and evolution of ferroelectric domain structures in thin films. Acta Mater 50:395

23.

Wang J, Shi S-Q, Chen L-Q, Li Y, Zhang T-Y (2004) Phase-field simulations of ferroelectric/ferroelastic polarization switching. Acta Mater 52:749

24.

Hong L, Soh A (2011) Unique vortex and stripe domain structures in \(\text{ PbTiO }_3\) epitaxial nanodots. Mech Mater 43:342

25.

Marton P, Klíč A, Paściak M, Hlinka J (2017) First-principles-based Landau–Devonshire potential for \(\text{ BiFeO }_3\). Phys Revs B 96:174110

26.

Hlinka J, Petzelt J, Kamba S, Noujni D, Ostapchuk T (2006) Infrared dielectric response of relaxor ferroelectrics. Phase Transit 79:41

27.

Nakhmanson SM, Naumov I (2010) Goldstone-like states in a layered perovskite with frustrated polarization: A first-principles investigation of \(\text{ PbSr }_{2}\text{ Ti }_{2}\text{ O }_{7}\). Phys Rev Lett 104:097601

28.

Mangeri J, Pitike KC, Alpay SP, Nakhmanson S (2016) Amplitudon and phason modes of electrocaloric energy interconversion. npj Comput Mater 2:16020

29.

Zhang J, Heitmann AA, Alpay SP, Rossetti GA (2009) Electrothermal properties of perovskite ferroelectric films. J Mater Sci 44:5263. https://doi.org/10.1007/s10853-009-3559-8

30.

Epstein RI, Malloy KJ (2009) Electrocaloric devices based on thin-film heat switches. J Appl Phys 106:064509

31.

Alpay SP, Mantese J, Trolier-McKinstry S, Zhang Q, Whatmore RW (2014) Next-generation electrocaloric and pyroelectric materials for solid-state electrothermal energy interconversion. Mater Res Bull 39:1099

32.

Khassaf H, Patel T, Alpay SP (2017) Combined intrinsic elastocaloric and electrocaloric properties of ferroelectrics. J Appl Phys 121:144102

33.

Matar S, Baraille I, Subramanian M (2009) First principles studies of \(\text{ SnTiO }_3\) perovskite as potential environmentally benign ferroelectric material. Chem Phys 355:43

34.

Fix T, Sahonta S-L, Garcia V, MacManus-Driscoll JL, Blamire MG (2011) Structural and dielectric properties of \(\text{ SnTiO }_3\), a putative ferroelectric. Cryst Growth Des 11:1422

35.

Parker WD, Rondinelli JM, Nakhmanson SM (2011) First-principles study of misfit strain-stabilized ferroelectric \(\text{ SnTiO }_3\). Phys Rev B 84:245126

36.

Pitike KC, Parker WD, Louis L, Nakhmanson SM (2015) First-principles studies of lone-pair-induced distortions in epitaxial phases of perovskite \(\text{ SnTiO }_{3}\) and \(\text{ PbTiO }_{3}\). Phys Rev B 91:035112

37.

Chang S et al (2016) Atomic layer deposition of environmentally benign \(\text{ SnTiO }_x\) as a potential ferroelectric material. J Vac Sci Technol A 34:01A119

38.

Wang T et al (2016) Chemistry, growth kinetics, and epitaxial stabilization of \(\text{ Sn }^{2+}\) in Sn-doped \(\text{ SrTiO }_3\) using \((\text{ CH }_3)_{6}\text{ Sn }_2\) tin precursor. APL Mater 4:126111

39.

Agarwal R et al (2018) Room-temperature relaxor ferroelectricity and photovoltaic effects in tin titanate directly deposited on a silicon substrate. Phys Rev B 97:054109

40.

Cao W (1994) Polarization gradient coefficients and the dispersion surface of the soft mode in perovskite ferroelectrics. J Phys Soc Jpn 63:1156

41.

Hlinka J, Marton P (2006) Phenomenological model of a \(90^\circ \) domain wall in \(\text{ BaTiO }_3\)-type ferroelectrics. Phys Rev B 74:104104

42.

Pertsev NA, Zembilgotov AG, Tagantsev AK (1998) Effect of mechanical boundary conditions on phase diagrams of epitaxial ferroelectric thin films. Phys Rev Lett 80:1988

43.

Nye J (1985) Physical properties of crystals: their representation by tensors and matrices. Oxford Science Publications, Clarendon Press

44.

Kresse G, Furthmüller J (1996) Efficiency of ab-initio total energy calculations for metals and semiconductors using a plane-wave basis set. Comput Mater Sci 6:15

45.

Kresse G, Furthmüller J (1996) Efficient iterative schemes for ab initio total-energy calculations using a plane-wave basis set. Phys Rev B 54:11169

46.

Giannozzi P et al (2009) QUANTUM ESPRESSO: a modular and open-source software project for quantum simulations of materials. J Phys Condens Matter 21:395502

47.

Perdew JP, Zunger A (1981) Self-interaction correction to density-functional approximations for many-electron systems. Phys Rev B 23:5048

48.

Blöchl PE (1994) Projector augmented-wave method. Phys Rev B 50:17953

49.

Kresse G, Joubert D (1999) From ultrasoft pseudopotentials to the projector augmented-wave method. Phys Rev B 59:1758

50.

Vanderbilt D (1990) Soft self-consistent pseudopotentials in a generalized eigenvalue formalism. Phys Rev B 41:7892

51.

Monkhorst HJ, Pack JD (1976) Special points for Brillouin-zone integrations. Phys Rev B 13:5188

52.

Baroni S, de Gironcoli S, Dal Corso A, Giannozzi P (2001) Phonons and related crystal properties from density-functional perturbation theory. Rev Mod Phys 73:515

53.

Gajdoš M, Hummer K, Kresse G, Furthmüller J, Bechstedt F (2006) Linear optical properties in the projector-augmented wave methodology. Phys Rev B 73:045112

54.

Baroni S, Resta R (1986) Ab initio calculation of the macroscopic dielectric constant in silicon. Phys Rev B 33:7017

55.

Nakhmanson SM, Rabe KM, Vanderbilt D (2005) Polarization enhancement in two- and three-component ferroelectric superlattices. Appl Phys Lett 87:102906

56.

King-Smith RD, Vanderbilt D (1993) Theory of polarization of crystalline solids. Phys Rev B 47:1651

57.

Resta R (1994) Macroscopic polarization in crystalline dielectrics: the geometric phase approach. Rev Mod Phys 66:899

58.

Yuk SF et al (2017) Towards an accurate description of perovskite ferroelectrics: exchange and correlation effects. Sci Rep 7:43482

59.

Perdew JP et al (1992) Atoms, molecules, solids, and surfaces: applications of the generalized gradient approximation for exchange and correlation. Phys Rev B 46:6671

60.

Perdew JP, Burke K, Ernzerhof M (1996) Generalized gradient approximation made simple. Phys Rev Lett 77:3865

61.

Perdew JP et al (2008) Restoring the density-gradient expansion for exchange in solids and surfaces. Phys Rev Lett 100:136406

62.

Dion M, Rydberg H, Schröder E, Langreth DC, Lundqvist BI (2004) Van der Waals density functional for general geometries. Phys Rev Lett 92:246401

63.

Thonhauser T et al (2007) Van der Waals density functional: self-consistent potential and the nature of the van der Waals bond. Phys Rev B 76:125112

64.

Cooper VR (2010) Van der Waals density functional: an appropriate exchange functional. Phys Rev B 81:161104

65.

Bilc DI et al (2008) Hybrid exchange-correlation functional for accurate prediction of the electronic and structural properties of ferroelectric oxides. Phys Rev B 77:165107

66.

Sepliarsky M, Phillpot SR, Wolf D, Stachiotti MG, Migoni RL (2000) Atomic-level simulation of ferroelectricity in perovskite solid solutions. Appl Phys Lett 76:3986

67.

Sepliarsky M, Wu Z, Asthagiri A, Cohen RE (2004) Atomistic model potential for \(\text{ PbTiO }_3\) and PMN by fitting first principles results. Ferroelectrics 301:55

68.

Sepliarsky M, Asthagiri A, Phillpot S, Stachiotti M, Migoni R (2005) Atomic-level simulation of ferroelectricity in oxide materials. Curr Opin Solid State Mater Sci 9:107

69.

Sepliarsky M, Cohen RE (2011) First-principles based atomistic modeling of phase stability in PMN-\(x\)PT. J Phys Condens Matter 23:435902

70.

Gindele O, Kimmel A, Cain MG, Duffy D (2015) Shell model force field for lead zirconate titanate \(\text{ Pb }(\text{ Zr }_{{\rm 1x}}\text{ Ti }_{{\rm x}})\text{ O }_{3}\). J Phys Chem C 119:17784

71.

Cao W (2008) Constructing Landau–Ginzburg–Devonshire type models for ferroelectric systems based on symmetry. Ferroelectrics 375:28

72.

Zheludev I, Shuvalov L (1956) Ferroelectric phase transitions and symmetry of crystals. Kristallografiya 1:681

73.

Vanderbilt D, Cohen MH (2001) Monoclinic and triclinic phases in higher-order Devonshire theory. Phys Rev B 63:094108

74.

Rignanese G-M, Gonze X, Pasquarello A (2001) First-principles study of structural, electronic, dynamical, and dielectric properties of zircon. Phys Rev B 63:104305

75.

Rignanese G-M, Detraux F, Gonze X, Pasquarello A (2001) First-principles study of dynamical and dielectric properties of tetragonal zirconia. Phys Rev B 64:134301

76.

Zhao X, Vanderbilt D (2002) Phonons and lattice dielectric properties of zirconia. Phys Rev B 65:075105

77.

Fennie CJ, Rabe KM (2003) Structural and dielectric properties of \(\text{ Sr }_2\text{ TiO }_{4}\) from first principles. Phys Rev B 68:184111

78.

Liu Z, Mei Z, Wang Y, Shang S (2012) Nature of ferroelectric-paraelectric transition. Philos Mag Lett 92:399

79.

Pedregosa F et al (2011) Scikit-learn: machine learning in python. J Mach Learn Res 12:2825

80.

Shirane G, Jona F (1962) Ferroelectric crystals. Pergamon Press, Oxford

81.

Nishimatsu T, Iwamoto M, Kawazoe Y, Waghmare UV (2010) First-principles accurate total energy surfaces for polar structural distortions of \(\text{ BaTiO }_3\), \(\text{ PbTiO }_3\), and \(\text{ SrTiO }_3\) : Consequences for structural transition temperatures. Phys Rev B 82:134106

82.

Le Page Y, Saxe P (2002) Symmetry-general least-squares extraction of elastic data for strained materials from ab initio calculations of stress. Phys Rev B 65:104104

83.

Piskunov S, Heifets E, Eglitis RI, Borstel G (2004) Bulk properties and electronic structure of \(\text{ SrTiO }_3\), \(\text{ BaTiO }_3\), \(\text{ PbTiO }_3\) perovskites: an ab initio HF/DFT study. Comput Mater Sci 29:165

84.

Taib MFM, Yaakob MK, Hassan OH, Yahya MZA (2013) Structural, electronic, and lattice dynamics of \(\text{ PbTiO }_{3}\), \(\text{ SnTiO }_{3}\), and \(\text{ SnZrO }_{3}\): a comparative first-principles study. Integr Ferroelectr 142:119

85.

Jiang Z et al (2016) Electrostriction coefficient of ferroelectric materials from ab initio computation. AIP Adv 6:065122

86.

Samara GA (1971) Pressure and temperature dependence of the dielectric properties and phase transitions of the ferroelectric perovskites: \(\text{ PbTiO }_3\) and \(\text{ BaTiO }_3\). Ferroelectrics 2:277

87.

Wójcik K (1989) Electrical properties of \(\text{ PbTiO }_3\) single crystals doped with lanthanum. Ferroelectrics 99:5

88.

Bhide V, Deshmukh K, Hegde M (1962) Ferroelectric properties of \(\text{ PbTiO }_3\). Physica 28:871

89.

Bhide VG, Hegde MS, Deshmukh KG (1968) Ferroelectric properties of lead titanate. J Am Ceram Soc 51:565

90.

Shirasaki S-I (1971) Defect lead titanates with diverse curie temperatures. Solid State Commun 9:1217

91.

Shirane G, Hoshino S (1951) On the phase transition in lead titanate. J Phys Soc Jpn 6:265

92.

Amin A, Cross LE, Newnham RE (1981) Calorimetric and phenomenological studies of the \(\text{ PbZrO }_{3}:\text{ PbTiO }_{3}\) system. Ferroelectrics 37:647

93.

Remeika J, Glass A (1970) The growth and ferroelectric properties of high resistivity single crystals of lead titanate. Mater Res Bull 5:37

94.

Chen L-Q (2008) Phase-field method of phase transitions/domain structures in ferroelectric thin films: a review. J Am Ceram Soc 91:1835. https://doi.org/10.1111/j.1551-2916.2008.02413.x

95.

Janolin P-E (2009) Strain on ferroelectric thin films. J Mater Sci 44:5025. https://doi.org/10.1007/s10853-009-3553-1

96.

Sun F, Khassaf H, Alpay SP (2014) Strain engineering of piezoelectric properties of strontium titanate thin films. J Mater Sci 49:5978. https://doi.org/10.1007/s10853-014-8316-y

97.

Reznitskii LA, Guzei AS (1978) Thermodynamic properties of alkaline earth titanates, zirconates, and hafnates. Russ Chem Rev 47:99

98.

Wood EA (1951) Evidence for the noncubic high temperature phase of \(\text{ BaTiO }_3\). J Chem Phys 19:976

99.

Yamada T, Kitayama T (1981) Ferroelectric properties of vinylidene fluoride-trifluoroethylene copolymers. J Appl Phys 52:6859

100.

Lovinger AJ (1983) Ferroelectric polymers. Science 220:1115

101.

Nalwa H (1995) Ferroelectric polymers: chemistry: physics, and applications, plastics engineering. Marcel Dekker Inc., New York

102.

Wang F, Landau D (2001) Efficient, multiple-range random walk algorithm to calculate the density of states. Phys Rev Lett 86:2050

103.

Wang F, Landau D (2001) Determining the density of states for classical statistical models: a random walk algorithm to produce a flat histogram. Phys Rev E 64:056101

104.

Landau DP, Tsai S-H, Exler M (2004) A new approach to Monte Carlo simulations in statistical physics: Wang-Landau sampling. Am J Phys 72:1294

105.

Bin-Omran S, Kornev IA, Bellaiche L (2016) Wang-Landau Monte Carlo formalism applied to ferroelectrics. Phys Rev B 93:014104

106.

Tibshirani R (1996) Regression shrinkage and selection via the lasso. J R Stat Soc B 58:267

Titel: Landau–Devonshire thermodynamic potentials for displacive perovskite ferroelectrics from first principles
verfasst von: Krishna Chaitanya Pitike
Nasser Khakpash
John Mangeri
George A. Rossetti Jr.
Serge M. Nakhmanson
Publikationsdatum: 26.02.2019
Verlag: Springer US
Erschienen in: Journal of Materials Science / Ausgabe 11/2019
Print ISSN: 0022-2461
Elektronische ISSN: 1573-4803
DOI: https://doi.org/10.1007/s10853-019-03439-2

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