Amorphous Alumina Nanoparticles: Structure, Surface Energy, and Thermodynamic Phase Stability

Tavakoli, Amir; Maram, Pardha Saradhi; Widgeon, Scarlett J.; Rufner, Jorgen F.; Benthem, Klaus van; Ushakov, Sergey V.; Sen, Sabyasachi; Navrotsky, Alexandra

doi:10.1021/jp405820g

Cited by 145 publications

(122 citation statements)

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“…S6), and MS shows that the water is removed gradually up to 450°C, which suggests that at least part of the H 2 O in this sample is strongly bonded. Assuming water in coffinite is adsorbed on the surface with an integral adsorption enthalpy of −80 kJ/mol per mole of H 2 O, similar to the values observed for water adsorption on alumina and titania (44)(45)(46) and, through proper thermochemical cycles (SI Appendix, Table S4), a value of ΔH f,ox of coffinite (24.1 ± 3.5 kJ/mol) is obtained, in agreement with the results for coffinite-F ( Table 1). The tightly bound water could originate from metaschoepite (UO 3 ·2H 2 O), which could be formed from partial oxidation of U(IV) (47) that originally was not incorporated in the coffinite structure, but rather was embedded in the gelatinous layer of excess amorphous silica (33).…”

Section: Resultssupporting

confidence: 61%

Thermodynamics of formation of coffinite, USiO ₄

Guo

Szenknect

Mesbah

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

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107

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Coffinite, USiO 4 , is an important U(IV) mineral, but its thermodynamic properties are not well-constrained. In this work, two different coffinite samples were synthesized under hydrothermal conditions and purified from a mixture of products. The enthalpy of formation was obtained by high-temperature oxide melt solution calorimetry. Coffinite is energetically metastable with respect to a mixture of UO 2 (uraninite) and SiO 2 (quartz) by 25.6 ± 3.9 kJ/mol. Its standard enthalpy of formation from the elements at 25°C is −1,970.0 ± 4.2 kJ/mol. Decomposition of the two samples was characterized by X-ray diffraction and by thermogravimetry and differential scanning calorimetry coupled with mass spectrometric analysis of evolved gases. Coffinite slowly decomposes to U 3 O 8 and SiO 2 starting around 450°C in air and thus has poor thermal stability in the ambient environment. The energetic metastability explains why coffinite cannot be synthesized directly from uraninite and quartz but can be made by low-temperature precipitation in aqueous and hydrothermal environments. These thermochemical constraints are in accord with observations of the occurrence of coffinite in nature and are relevant to spent nuclear fuel corrosion.uranium | coffinite | USiO 4 | U(IV) minerals | calorimetry I n many countries with nuclear energy programs, spent nuclear fuel (SNF) and/or vitrified high-level radioactive waste will be disposed in an underground geological repository. Demonstrating the long-term (10 6 -10 9 y) safety of such a repository system is a major challenge. The potential release of radionuclides into the environment strongly depends on the availability of water and the subsequent corrosion of the waste form as well as the formation of secondary phases, which control the radionuclide solubility. Coffinite (1), USiO 4 , is expected to be an important alteration product of SNF in contact with silica-enriched groundwater under reducing conditions (2-8). It is also found, accompanied by thorium orthosilicate and uranothorite, in igneous and metamorphic rocks and ore minerals from uranium and thorium sedimentary deposits (2,4,5,(8)(9)(10)(11)(12)(13)(14)(15)(16). Under reducing conditions in the repository system, the uranium solubility (very low) in aqueous solutions is typically derived from the solubility product of UO 2 . Stable U(IV) minerals, which could form as secondary phases, would impart lower uranium solubility to such systems. Thus, knowledge of coffinite thermodynamics is needed to constrain the solubility of U(IV) in natural environments and would be useful in repository assessment.In natural uranium deposits such as Oklo (Gabon) (4,7,11,12,14,17,18) and Cigar Lake (Canada) (5, 13, 15), coffinite has been suggested to coexist with uraninite, based on electron probe microanalysis (EPMA) (4,5,7,11,13,17,19,20) and transmission electron microscopy (TEM) (8, 15). However, it is not clear whether such apparent replacement of uraninite by a coffinite-like phase is a direct solid-state process or occurs mediated by dis...

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Section: Resultssupporting

confidence: 61%

Thermodynamics of formation of coffinite, USiO ₄

Guo

Szenknect

Mesbah

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

Self Cite

107

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“…10 Owing to the general availability and unique characteristics, such as good structural, chemical and thermal stability at elevated temperatures, high electrical resistivity, low gate leakage, and excellent behavior in optics and electronics, Al 2 O 3 in both amorphous and polymorphs (material with similar composition but different crystal structure) forms are registered among the technologically most crucial ceramic materials. [11][12][13][14][15][16][17]27,28 In this Letter, we evaluated the effects of ordered/disordered structures of Al 2 O 3 NPs, volume fraction, and temperatures on the TC enhancement in EG nanofluid for different volume concentrations. As described in a previous work, three different structures of NPs, i.e., amorphous and crystalline c-, and a-Al 2 O 3 , were synthesized by sol-gel method.…”

Section: O 3 Nanoparticlesmentioning

confidence: 99%

“…The long-range order in nano-crystalline may resist to the liquid-particle interface and resulted in the lower enhanced TC of the crystalline c-and a-Al 2 O 3 /EG nanofluids. Moreover, the amorphous structure of Al 2 O 3 has random distribution of Al 3þ and vacancies over tetrahedral (AlO 4 ), polyhedral (AlO 5 ), and octahedral (AlO 6 ) sites with the prominent tetrahedral and octahedral units; whereas the crystal structure of c-Al 2 O 3 is composed of a mixture of tetrahedral and 12,15,27,28 We infer that the predominant fractions of a-Al 2 O 3 NPs may highly interact with the base-fluid and enhance the TC of nanofluids. The lower TC enhancement achieved by the crystalline c-and a-Al 2 O 3 /EG nanofluids can be ascribed due to the presence of short-range interfacing between solid-particle and liquidphase as compared to the a-Al 2 O 3 /EG nanofluids.…”

mentioning

confidence: 99%

Strong enhancement in thermal conductivity of ethylene glycol-based nanofluids by amorphous and crystalline Al2O3 nanoparticles

Gangwar

Srivastava

Tripathi

et al. 2014

Applied Physics Letters

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In the present work, the temperature and concentration dependence of thermal conductivity (TC) enhancement in ethylene glycol (EG)-based amorphous and crystalline Al2O3 nanofluids have been investigated at temperatures ranging from 0 to 100 °C. In our prior study, nanometer-sized particles of amorphous-, γ-, and α-Al2O3 were prepared via a simple sol-gel process with annealing at different temperatures and characterized by various techniques. Building upon the earlier study, we probe here the crystallinity, microstructure, and morphology of the obtained α-Al2O3 nanoparticles (NPs) by using X-ray powder diffraction with Rietveld full-profile refinement, scanning electron microscopy, and high-resolution transmission electron microscopy, respectively. In this study, we achieved a 74% enhancement in TC at higher temperature (100 °C) of base fluid EG by incorporating 1.0 vol. % of amorphous-Al2O3, whereas 52% and 37% enhancement is accomplished by adding γ- and α-Al2O3 NPs, respectively. The amorphous phase of NPs appears to have good TC enhancement in nanofluids as compared to crystalline Al2O3. In a nutshell, these results are demonstrating the potential consequences of Al2O3 NPs for applications of next-generation efficient energy transfer in nanofluids.

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“…It is commonly called alumina. The oxides of aluminium materials are widely used in ceramics, refractories and abrasives due to their hardness, chemical inertness, high melting point, non-volatility and resistance to oxidation and corrosion [1][2][3][4][5]. Predominantly, aluminum oxide nanoparticles commonly known as alumina (Al 2 O 3 NPs) have trapped the awareness of many researchers due to its great catalytical activities.…”

Section: Introductionmentioning

confidence: 99%

“…Predominantly, aluminum oxide nanoparticles commonly known as alumina (Al 2 O 3 NPs) have trapped the awareness of many researchers due to its great catalytical activities. An alumina nanoparticles can be synthesized by using many techniques including ball milling, spray combustion, hydrothermal, sputtering, sol-gel, microwave and laser ablation [5][6][7][8][9][10]. Out of all the methods, hydrothermal method proved more helpful to obtain well shaped materials with designed texture and composition at low processing temperatures [11][12].…”

Section: Introductionmentioning

confidence: 99%

Green Synthesis of Aluminium Oxide Nanoparticles by using Aerva Lanta and Terminalia Chebula Extracts

Duraisamy¹

2018

IJRASET

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Eco-friendly synthesis of aluminium oxide nanoparticles was achieved by a novel, facile green route method using aerva lanta and terminalia chebula as a reducing agent. Aluminium oxide nanoparticles (Al 2 O 3 ) were synthesized from aluminium nitrate using extracts of aerva lanta leaves and terminalia chebula seeds. Nanoparticles produced by plants are more stable and rate of synthesis is faster than that in other organisms. The present investigation was carried out to green synthesis of alumina nanoparticles by using medicinal plants. Deionised Water was taken as solvent medium. The formations of AlNP were initially monitored by the colour changes occurring in the reaction mixture during the incubation period. The successful formation of alumina nanoparticles has been confirmed by X-ray diffraction, UV-visible, FTIR and FE-SEM analysis. The X-ray diffraction data revealed the average size of the Al-NPs as 70 nm. The AlNP were found to be spherical agglomeration in shape in case of aerva lanta leaves extract with a size of 50-70 nm and to be spherical shaped in case of terminalia chebula seed extract with an average size of 50-100 nm.

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Amorphous Alumina Nanoparticles: Structure, Surface Energy, and Thermodynamic Phase Stability

Cited by 145 publications

References 38 publications

Thermodynamics of formation of coffinite, USiO ₄

Thermodynamics of formation of coffinite, USiO ₄

Strong enhancement in thermal conductivity of ethylene glycol-based nanofluids by amorphous and crystalline Al2O3 nanoparticles

Green Synthesis of Aluminium Oxide Nanoparticles by using Aerva Lanta and Terminalia Chebula Extracts

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Amorphous Alumina Nanoparticles: Structure, Surface Energy, and Thermodynamic Phase Stability

Cited by 145 publications

References 38 publications

Thermodynamics of formation of coffinite, USiO 4

Thermodynamics of formation of coffinite, USiO 4

Strong enhancement in thermal conductivity of ethylene glycol-based nanofluids by amorphous and crystalline Al2O3 nanoparticles

Green Synthesis of Aluminium Oxide Nanoparticles by using Aerva Lanta and Terminalia Chebula Extracts

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Thermodynamics of formation of coffinite, USiO ₄

Thermodynamics of formation of coffinite, USiO ₄