TiO<sub>2</sub>Stability Landscape:  Polymorphism, Surface Energy, and Bound Water Energetics

Levchenko, Andrey A.; Li, Guangshe; Boerio‐Goates, Juliana; Woodfield, Brian F.; Navrotsky, Alexandra

doi:10.1021/cm061183c

Cited by 204 publications

(261 citation statements)

References 36 publications

(69 reference statements)

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“…[76]. Two recent experiments [76,77] found similar enthalpy differences of 0.027 and 0.017 eV/f.u. The measurement of this quantity is a significant experimental challenge, requiring careful control of impurity concentration and synthesis conditions [76].…”

Section: Relative Stability Of Rutile and Anatase Phasesmentioning

confidence: 70%

Hubbard-Ucorrected Hamiltonians for non-self-consistent random-phase approximation total-energy calculations: A study of ZnS,TiO2, and NiO

Patrick

Thygesen

2016

Phys. Rev. B

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In non-self-consistent calculations of the total energy within the random-phase approximation (RPA) for electronic correlation, it is necessary to choose a single-particle Hamiltonian whose solutions are used to construct the electronic density and noninteracting response function. Here we investigate the effect of including a Hubbard-U term in this single-particle Hamiltonian, to better describe the on-site correlation of 3d electrons in the transition metal compounds ZnS, TiO 2 , and NiO. We find that the RPA lattice constants are essentially independent of U , despite large changes in the underlying electronic structure. We further demonstrate that the non-selfconsistent RPA total energies of these materials have minima at nonzero U . Our RPA calculations find the rutile phase of TiO 2 to be more stable than anatase independent of U , a result which is consistent with experiments and qualitatively different from that found from calculations employing U -corrected (semi)local functionals. However we also find that the +U term cannot be used to correct the RPA's poor description of the heat of formation of NiO.

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Section: Relative Stability Of Rutile and Anatase Phasesmentioning

confidence: 70%

Hubbard-Ucorrected Hamiltonians for non-self-consistent random-phase approximation total-energy calculations: A study of ZnS,TiO2, and NiO

Patrick

Thygesen

2016

Phys. Rev. B

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“…The data obtained by Navrotsky et al [11,12] , Fig. 6, give a guideline for understanding this process where two opportunities may be foreseen.…”

Section: Resultsmentioning

confidence: 93%

“…Curves are numbered according to Table 1 Int Nano Lett (2016) 6:111-117 113 structure of the samples studied would be preserved. On the other hand, both anatase and brookite are metastable against the bulk rutile, and the smaller the particle, the more heat is evolved upon the anatase-bulk rutile transformation [12]. In this case, one may anticipate that should aggregation occur upon heating, rutile would be formed as the most thermodynamically stable phase, and the greater the S sp .…”

Section: Resultsmentioning

confidence: 99%

“…Preparation of materials often includes their thermal pretreatment, and this requires the knowledge regarding their phase state. Precise calorimetric measurements by Navrotsky and co-workers have shown [11,12] that depending on the size, the thermodynamic stability of the TiO 2 polymorphs at ambient temperatures is significantly different. For the smallest particles, the anatase structure is the most stable.…”

Section: Introductionmentioning

confidence: 99%

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Hydrothermal synthesis of anatase nanoleaves and size dependence of anatase–rutile transformation upon heating

Lisnycha¹,

Kirillov

Potapenko

et al. 2016

Int Nano Lett

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Amorphous TiO 2 obtained by adding TiCl 4 to an alkaline medium crystallizes slowly and upon 3 years ageing transforms to nanosized anatase containing an admixture of brookite. The hydrothermal treatment of this sample in solutions of lithium hydroxide leads to anatase nanoleaves, and the more concentrated LiOH solution, the greater the nanoleaves and the smaller their specific surface area. The thermal treatment of nanoleaves leads to the bulk rutile, and the greater the specific surface area of anatase nanoleaves, the lower the anatase-rutile transition temperature. This is in line with conclusions based on the thermodynamic stability of nanosized anatase over the bulk rutile.

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“…1 [24]; 57,4 kJ/mol [25]). Este resultado, no entanto, é consistente com outros dados reportados para óxidos [5,26]. Nota-se ainda no gráfico que a curva tem um decaimento rápido nesta energia, mostrando alguns "degraus" nas energias.…”

Section: Energia De Superfície Do Sno 2 Purounclassified

Determinação das energias de superfície do SnO2 puro e dopado

Castro

Hidalgo²,

Gouvêa³

et al. 2009

Cerâmica

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INTRODUÇÃOO desenvolvimento de novos nanomateriais é fortemente dependente do controle da estabilização destas nanoestruturas. Quando considerando sínteses bottomtop, podem ser definidos dois métodos básicos de controle das nanoestruturas para gerar estabilização e indução de formatos e tamanhos desejados: o método termodinâmico e o cinético [1]. Particularmente centrando na síntese via líquida de nanopartículas, a aproximação termodinâmica considera que na nucleação existe um raio crítico mínimo relacionado com um balanço entre a energia de volume e a energia de superfície. Como fortemente dependente da energia de superfície, a modulação desta energia é indicada como uma forma natural de controle do tamanho mínimo das nanopartículas [1,2]. No entanto, após a nucleação, o fenômeno de crescimento ocorre espontaneamente, desde que existe uma barreira de energia para nuclear uma nova nanopartícula que, em geral, é maior que aquela para crescer a nanopartícula já nucleada. Para controlar este crescimento, adotam-se soluções usualmente cinéticas. No entanto, observando os modelos de crescimento de nanopartícula por síntese em fase líquida, verifica-se que a energia de superfície tem influência direta também no crescimento do tamanho da partícula em conjunto com o coeficiente de difusão. Isto é, para um processo controlado por difusão, o tamanho médio Mg, Fe, Cr, and Ni.

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TiO₂Stability Landscape: Polymorphism, Surface Energy, and Bound Water Energetics

Cited by 204 publications

References 36 publications

Hubbard-Ucorrected Hamiltonians for non-self-consistent random-phase approximation total-energy calculations: A study of ZnS,TiO2, and NiO

Hubbard-Ucorrected Hamiltonians for non-self-consistent random-phase approximation total-energy calculations: A study of ZnS,TiO2, and NiO

Hydrothermal synthesis of anatase nanoleaves and size dependence of anatase–rutile transformation upon heating

Determinação das energias de superfície do SnO2 puro e dopado

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TiO2Stability Landscape: Polymorphism, Surface Energy, and Bound Water Energetics

Cited by 204 publications

References 36 publications

Hubbard-Ucorrected Hamiltonians for non-self-consistent random-phase approximation total-energy calculations: A study of ZnS,TiO2, and NiO

Hubbard-Ucorrected Hamiltonians for non-self-consistent random-phase approximation total-energy calculations: A study of ZnS,TiO2, and NiO

Hydrothermal synthesis of anatase nanoleaves and size dependence of anatase–rutile transformation upon heating

Determinação das energias de superfície do SnO2 puro e dopado

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Product

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TiO₂Stability Landscape: Polymorphism, Surface Energy, and Bound Water Energetics