Long-term heat-storage materials based on λ-Ti<sub>3</sub>O<sub>5</sub>for green transformation (GX)

Ohkoshi, Shin‐ichi; Yoshikiyo, Marie; MacDougall, Jessica; Ikeda, Yusuke; Tokoro, Hiroko

doi:10.1039/d3cc00641g

Cited by 4 publications

(6 citation statements)

References 76 publications

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“…Recently, we developed a pressure-responsive thermal storage material that discharges stored heat when subjected to external pressure. 18,19 This material—λ-phase trititanium pentoxide (λ-Ti 3 O 5 )—is a metastable phase present only in nanoscale materials and not in bulk forms. 18,20 Furthermore, λ-Ti 3 O 5 undergoes a reversible phase transition with beta-phase trititanium pentoxide (β-Ti 3 O 5 ) under external stimuli such as light, pressure, or temperature.…”

Section: Introductionmentioning

confidence: 99%

“…18,20 Furthermore, λ-Ti 3 O 5 undergoes a reversible phase transition with beta-phase trititanium pentoxide (β-Ti 3 O 5 ) under external stimuli such as light, pressure, or temperature. 18–21 Moreover, λ-Ti 3 O 5 is an environmentally friendly material purely composed of titanium and oxygen. 18–22 To effectively use this material, scalable synthesis methods for mass production and strategies for enhancing thermal storage properties are crucial.…”

Section: Introductionmentioning

confidence: 99%

“…18–21 Moreover, λ-Ti 3 O 5 is an environmentally friendly material purely composed of titanium and oxygen. 18–22 To effectively use this material, scalable synthesis methods for mass production and strategies for enhancing thermal storage properties are crucial. Accordingly, various synthesis techniques for λ-Ti 3 O 5 have been explored.…”

Section: Introductionmentioning

confidence: 99%

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Synthesis of heat storage ceramic λ-Ti₃O₅ using titanium chloride as the starting material

Kubota,

Seiki,

Fujisawa

et al. 2024

Mater. Adv.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Synthesis of heat storage ceramic λ-Ti₃O₅ using titanium chloride as the starting material

Kubota,

Seiki,

Fujisawa

et al. 2024

Mater. Adv.

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“…To realize such a material, an effective approach is to investigate various types of first-order phase transition materials. [11][12][13][14][15] In 2015, we proposed a new concept of "long-term heat storage ceramics", in which latent heat is preserved until the material is triggered by external stimuli. [11,16] The first example is lambda-trititanium-pentoxide (λ-Ti 3 O 5 ), which exhibits a phase transition to beta-trititanium-pentoxide (β-Ti 3 O 5 ) by pressure application.…”

Section: Introductionmentioning

confidence: 99%

“…[11][12][13][14][15] In 2015, we proposed a new concept of "long-term heat storage ceramics", in which latent heat is preserved until the material is triggered by external stimuli. [11,16] The first example is lambda-trititanium-pentoxide (λ-Ti 3 O 5 ), which exhibits a phase transition to beta-trititanium-pentoxide (β-Ti 3 O 5 ) by pressure application. [11,[16][17][18][19] λ-Ti 3 O 5 has been synthesized in 2010 as a different phase from originally known Ti 3 O 5 phases (α-, β-, γ-, and δ-phases).…”

Section: Introductionmentioning

confidence: 99%

Long‐Term Heat‐Storage Ceramics based on Zr‐Substituted λ‐Ti₃O₅

Otake,

Wang,

Jia

et al. 2024

Eur J Inorg Chem

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Heat‐storage materials are important for energy saving to protect the environment. Here, we show a long‐term heat‐storage material based on zirconium‐substituted lambda‐trititanium pentoxide (λ‐ZrxTi3‐xO5, 0 < x ≤ 0.06). λ‐ZrxTi3‐xO5 exhibits a phase transition to zirconium‐substituted beta‐trititanium pentoxide (β‐ZrxTi3‐xO5) upon application of pressure. The transition pressures were 600 MPa (x = 0.04) and about 1 GPa (x = 0.06). When the pressure‐produced β‐phase is heated, the β‐phase transforms into λ‐phase. The phase transition temperatures (i.e., heat‐storage temperatures) were 185 °C (458 K) and 183 °C (453 K) for x = 0.04 and 0.06, respectively. These heat‐storage temperatures are suitable for the reuse of low‐temperature industrial waste heat, which are considered to be a difficult temperature region to be efficiently collected and reused. The present pressure‐sensitive heat‐storage ceramic, which can store the latent heat energy for a prolonged period, is effective for the sustainable reuse of heat energy that are wasted in power plants and industrial factories.

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Layer-by-layer phase transformation in Ti3O5 revealed by machine-learning molecular dynamics simulations

Liu,

Wang,

et al. 2024

Nat Commun

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Reconstructive phase transitions involving breaking and reconstruction of primary chemical bonds are ubiquitous and important for many technological applications. In contrast to displacive phase transitions, the dynamics of reconstructive phase transitions are usually slow due to the large energy barrier. Nevertheless, the reconstructive phase transformation from β- to λ-Ti3O5 exhibits an ultrafast and reversible behavior. Despite extensive studies, the underlying microscopic mechanism remains unclear. Here, we discover a kinetically favorable in-plane nucleated layer-by-layer transformation mechanism through metadynamics and large-scale molecular dynamics simulations. This is enabled by developing an efficient machine learning potential with near first-principles accuracy through an on-the-fly active learning method and an advanced sampling technique. Our results reveal that the β−λ phase transformation initiates with the formation of two-dimensional nuclei in the ab-plane and then proceeds layer-by-layer through a multistep barrier-lowering kinetic process via intermediate metastable phases. Our work not only provides important insight into the ultrafast and reversible nature of the β−λ transition, but also presents useful strategies and methods for tackling other complex structural phase transitions.

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Long-term heat-storage materials based on λ-Ti₃O₅for green transformation (GX)

Abstract: Effective reuse of waste heat energy is an important energy savings issue for green transformation. In general, phase-change heat storage materials cannot store energy for a prolonged period. If a...

Cited by 4 publications

References 76 publications

Synthesis of heat storage ceramic λ-Ti₃O₅ using titanium chloride as the starting material

Synthesis of heat storage ceramic λ-Ti₃O₅ using titanium chloride as the starting material

Long‐Term Heat‐Storage Ceramics based on Zr‐Substituted λ‐Ti₃O₅

Layer-by-layer phase transformation in Ti3O5 revealed by machine-learning molecular dynamics simulations

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Long-term heat-storage materials based on λ-Ti3O5for green transformation (GX)

Abstract: Effective reuse of waste heat energy is an important energy savings issue for green transformation. In general, phase-change heat storage materials cannot store energy for a prolonged period. If a...

Cited by 4 publications

References 76 publications

Synthesis of heat storage ceramic λ-Ti3O5 using titanium chloride as the starting material

Synthesis of heat storage ceramic λ-Ti3O5 using titanium chloride as the starting material

Long‐Term Heat‐Storage Ceramics based on Zr‐Substituted λ‐Ti3O5

Layer-by-layer phase transformation in Ti3O5 revealed by machine-learning molecular dynamics simulations

Contact Info

Product

Resources

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Long-term heat-storage materials based on λ-Ti₃O₅for green transformation (GX)

Synthesis of heat storage ceramic λ-Ti₃O₅ using titanium chloride as the starting material

Synthesis of heat storage ceramic λ-Ti₃O₅ using titanium chloride as the starting material

Long‐Term Heat‐Storage Ceramics based on Zr‐Substituted λ‐Ti₃O₅