The effect of heating rate on sintering mechanism of alumina nanoparticles

Wang, Dangqiang; Mei, Hai; Liu, Lisheng; Zhang, Jinyong

doi:10.1111/jace.18723

Cited by 12 publications

(3 citation statements)

References 41 publications

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“…Numerous studies, reflecting on experimental outcomes like fracture tendencies in amorphous alumina, have leaned on the Matsui potential [1,73]. Moreover, recent research has employed this potential to study the sintering of Al 2 O 3 nanoparticles [16,74]. While the Vashishta and many reactive potentials showed misalignment with our databases in many areas, they have exhibited good concurrence with properties of crystalline phases [18,69].…”

Section: Resultsmentioning

confidence: 88%

Do we really need machine learning interatomic potentials for modeling amorphous metal oxides? Case study on amorphous alumina by recycling an existing ab initio database

Gramatte,

Turlo,

Politano

2024

Modelling Simul. Mater. Sci. Eng.

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In this study, we critically evaluate the performance of various interatomic potentials/force fields against a benchmark ab initio database for bulk amorphous alumina. The interatomic potentials tested in this work include all major fixed charge and variable charge models developed to date for alumina. Additionally, we introduce a novel machine learning interatomic potential constructed using the NequIP framework based on graph neural networks. Our findings reveal that the fixed-charge potential developed by Matsui and coworkers offers the most optimal balance between computational efficiency and agreement with ab initio data for stoichiometric alumina. Such balance cannot be provided by machine learning potentials when comparing performance with Matsui potential on the same computing infrastructure using a single Graphical Processing Unit. For non-stoichiometric alumina, the variable charge potentials, in particular ReaxFF, exhibit an impressive concordance with DFT calculations. However, our NequIP potentials trained on a small fraction of the ab initio database easily surpass ReaxFF in terms of both accuracy and computational performance. This is achieved without large overhead in terms of potential fitting and fine-tuning, often associated with the classical potential development process as well as training of standard deep neural network potentials, thus advocating for the use of data-efficient machine learning potentials like NequIP for complex cases of non-stoichiometric amorphous oxides.

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Section: Resultsmentioning

confidence: 88%

Do we really need machine learning interatomic potentials for modeling amorphous metal oxides? Case study on amorphous alumina by recycling an existing ab initio database

Gramatte,

Turlo,

Politano

2024

Modelling Simul. Mater. Sci. Eng.

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“…40 Therefore, the size change of the sample entirely depends on the oxidation of Al particles before it is completely converted into alumina. Between 1473 and 1673 K, the alumina particles are fully formed and the shrinkage of the sample hardly changes, because the sintering of the alumina (generally considered to be around 1773 K 41 ) has not fully started, it is expressed as hollow structure integrity in the microstructure (Figure 4A,B). When the temperature reaches 1773 K, the sample begins to shrink greatly, and the expansion of particles is offset by the shrinkage.…”

Section: Shrinkage Porosity and Compressive Strengthmentioning

confidence: 99%

A novel process to high‐strength and controlled‐shrinkage Al₂O₃ foams with open‐cell by Al powder hollowing technology

et al. 2023

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Ceramic foams with open‐cell structures have attracted extensive attention due to their unique structure and superior properties. But these materials often exhibit the weakness of high sintered shrinkage and low strength at high porosity levels. In this work, novel ceramic foams with open‐cell structures have been obtained using Al powder by combining direct foaming and gelation freezing (DF–GF). The foams are assembled by hollow Al2O3 particles resulting from the Kirkendall effect, in which expanded particles overcome the shrinkage of sintering. The influence of sintering temperature on the microstructure and properties of foams are investigated. The Al2O3 foams show near‐zero‐shrinkage at 1773 K after undergoing the process of first expansion and then shrinkage. Compared to other conventional open‐cell foam, this foam displays relatively high compressive strength of 0.35–2.19 MPa at high porosity levels of 89.45%–94.45%, attributed to hierarchical pore structure and reaction bonding between Al and O2. This method from pore structure design provides a novel route for the preparation of controlled shrinkage and high‐compressive strength alumina foam with open‐cell toward potential application.

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“…Sintering is a process driven by heat or pressure to compact and form a solid without the powder reaching its melting point [ 1 ]. This process is primarily driven by surface energy, which converts the powdered material into a dense body [ 2 ].…”

Section: Introductionmentioning

confidence: 99%

MOF-Enhanced Aluminosilicate Ceramic Membranes Using Non-Firing Processes for Pesticide Filtration and Phytochrome Removal

Zhao,

Xu,

et al. 2024

Nanomaterials

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Aluminosilicates, abundant and crucial in both natural environments and industry, often involve uncontrollable chemical components when derived from minerals, making further chemical purification and reaction more complicated. This study utilizes pure alumina and fumed silica powders as more controllable sources, enhancing aluminosilicate reactivity through room temperature (non-firing) processing and providing a robust framework that resists mechanical stress and high temperature. By embedding iron-based metal–organic frameworks (Fe-MOF/non-firing aluminosilicate membranes) within the above matrix, these ceramic membranes not only preserve their mechanical robustness but also gain significant chemical functionality, enhancing their capacity to removing phytochromes from the vegetables. Sodium hydroxide and sodium silicate were selected as activators to successfully prepare high-strength, non-firing aluminosilicate membranes. These membranes demonstrated a flexural strength of 8.7 MPa under wet-culture conditions with a molar ratio of Al2O3:SiO2:NaOH:Na2SiO3 at 1:1:0.49:0.16. The chlorophyll adsorption of spinach conducted on these membranes showed a removal rate exceeding 90% at room temperature and pH = 9, highlighting its potential for the selective adsorption of chlorophyll. This study underscores the potential of MOF-enhanced aluminosilicate ceramic membranes in environmental applications, particularly for agricultural pollution control.

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The effect of heating rate on sintering mechanism of alumina nanoparticles

Cited by 12 publications

References 41 publications

Do we really need machine learning interatomic potentials for modeling amorphous metal oxides? Case study on amorphous alumina by recycling an existing ab initio database

Do we really need machine learning interatomic potentials for modeling amorphous metal oxides? Case study on amorphous alumina by recycling an existing ab initio database

A novel process to high‐strength and controlled‐shrinkage Al₂O₃ foams with open‐cell by Al powder hollowing technology

MOF-Enhanced Aluminosilicate Ceramic Membranes Using Non-Firing Processes for Pesticide Filtration and Phytochrome Removal

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The effect of heating rate on sintering mechanism of alumina nanoparticles

Cited by 12 publications

References 41 publications

Do we really need machine learning interatomic potentials for modeling amorphous metal oxides? Case study on amorphous alumina by recycling an existing ab initio database

Do we really need machine learning interatomic potentials for modeling amorphous metal oxides? Case study on amorphous alumina by recycling an existing ab initio database

A novel process to high‐strength and controlled‐shrinkage Al2O3 foams with open‐cell by Al powder hollowing technology

MOF-Enhanced Aluminosilicate Ceramic Membranes Using Non-Firing Processes for Pesticide Filtration and Phytochrome Removal

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Product

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About

A novel process to high‐strength and controlled‐shrinkage Al₂O₃ foams with open‐cell by Al powder hollowing technology