Porous bioactive glass microspheres prepared by flame synthesis process

Kraxner, Jozef; Michálek, Martin; Romero, Acacio Rincon; Bernardo, Enrico; Boccaccını, Aldo R.; Galusek, Dušan

doi:10.1016/j.matlet.2019.126625

Cited by 25 publications

(20 citation statements)

References 11 publications

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“…This paper was cited in publications on the preparation of glass-containing foams from geopolymers [122] and vitrified MSWI bottom ash [123] in which the formation of wollastonite and the freezing of the microstructural evolution were mentioned. Other papers cited this publication with respect to the recycling of glass waste into foam glass [124][125][126][127][128][129], porous waste glass for lead removal in wastewater treatment [130], lead stabilization through alkali activation and sintering of Pb-bearing sludge [131], utilization of waste glass for the production of sulphuric acid resistant concrete [132], mechanical and alkali activation of MSWI fly and bottom ashes for the production of low-range alkaline cement [133] and foam glass-ceramics [134], inorganic gel casting for manufacturing of boro-alumino-silicate glass foams [135], porous glass-ceramics derived from MgO-CuO-TiO 2 -P 2 O 5 glasses [136], alkali activation of coal and biomass fly ashes [137], nickel-based catalysts for steam reforming of naphthalene utilizing MSW gasification slag as support [138], production of porous glass ceramics from titanium mine tailings and waste glass [139], porous bioactive glass microspheres [140], Al-SiO 2 composites [141], glass-ceramic foams from alkali-activated vitrified MSWI bottom ash and waste glasses [142]. Another study used vitrified MSWI bottom ash as input material to obtain similar porous glass ceramics [143] and was cited by some of the publications that also cited the first study.…”

Section: Sintering Of Glass-ceramicsmentioning

confidence: 99%

The EU Training Network for Resource Recovery through Enhanced Landfill Mining—A Review

2021

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The “European Union Training Network for Resource Recovery Through Enhanced Landfill Mining (NEW-MINE)” was a European research project conducted between 2016 and 2020 to investigate the exploration of and resource recovery from landfills as well as the processing of the excavated waste and the valorization of the obtained waste fractions using thermochemical processes. This project yielded more than 40 publications ranging from geophysics via mechanical process engineering to ceramics, which have not yet been discussed coherently in a review publication. This article summarizes and links the NEW-MINE publications and discusses their practical applicability in waste management systems. Within the NEW-MINE project in a first step concentrates of specific materials (e.g., metals, combustibles, inert materials) were produced which might be used as secondary raw materials. In a second step, recycled products (e.g., inorganic polymers, functional glass-ceramics) were produced from these concentrates at the lab scale. However, even if secondary raw materials or recycled products could be produced at a large scale, it remains unclear if they can compete with primary raw materials or products from primary raw materials. Given the ambitions of transition towards a more circular economy, economic incentives are required to make secondary raw materials or recycled products from enhanced landfill mining (ELFM) competitive in the market.

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Section: Sintering Of Glass-ceramicsmentioning

confidence: 99%

The EU Training Network for Resource Recovery through Enhanced Landfill Mining—A Review

2021

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“…[42][43][44] Recently GM have proven to be versatile biomaterials. [45][46][47] GM are favorable for the manufacture of complexshaped glass articles by additive manufacturing (AM) technologies. The replacement of glass frit by GM leads to lower friction during feeding, and increased packing density of product.…”

Section: Introductionmentioning

confidence: 99%

“…GM are also considered for hydrogen storage, 30,38‐41 energy‐saving applications (thermal insulation), and also as luminescent or reflective materials 42‐44 . Recently GM have proven to be versatile biomaterials 45‐47 …”

Section: Introductionmentioning

confidence: 99%

Low‐alkali borosilicate glass microspheres from waste cullet prepared by flame synthesis

Hujova

Michalková³

et al. 2021

Int J of Appl Glass Sci

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“…29,30 The physics of resin under pressure is similar to the seepage pr lar approaches have been used also to mod into a mold containing fiber mats. 23,[31][32][33][34][35][36][37][38] T in these cases to determine the resin flow ing times corresponding to different infilt Preceramic polycarbosilane polymers as precursors to make ceramic fibers 10,3 trix. [7][8][9]40,41 The chemical and volume ch pany ceramization of the polymer during documented in several studies.…”

Section: Introductionmentioning

confidence: 99%

“…[27][28][29][30] However, the disadvantages of the sol-gel process are the limited yield and high costs. 31 In contrast, flame-spraying of irregular particles into non-porous spheres provides a relatively fast and cheap method that can be easily scaled-up for commercialization purposes. The first non-porous bioactive glass microspheres were successfully manufactured via flame-spraying of glass 13-93.…”

Section: Introductionmentioning

confidence: 99%

In vitrodissolution of bioactive glass S53P4 microspheres

2021

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Static and dynamic in vitro dissolution studies showed large differences for various size-fractions of non-porous, flame-sprayed commercial microspheres (45-500 µm) of bioactive glass S53P4.The smaller the spheres, the more their composition deviated from the nominal glass. The dissolution studies were carried out in simulated body fluid and tris(hydroxymethyl) aminomethane buffer for seven days. The ion concentrations in solutions were analyzed using inductively coupled plasma optical emission spectrometry, and the pH was measured as a function of time. Also, changes in the sphere size distribution and mass losses were determined. The calcium phosphate and the silica-rich layers at the sphere surfaces were investigated using scanning electron microscopy after several immersion times. The smallest (45-90 µm) spheres appeared almost inert. In contrast, typical silica-rich and calcium phosphate layers were identified at the largest spheres after three days of static and dynamic dissolutions. During the past years, bioactive glass microspheres have been added to paste-like injectable bone grafting materials, putties to enhance their molding properties. The obtained results provide a better understanding of the dissolution patterns of bioactive glass microspheres.

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Porous bioactive glass microspheres prepared by flame synthesis process

Cited by 25 publications

References 11 publications

The EU Training Network for Resource Recovery through Enhanced Landfill Mining—A Review

The EU Training Network for Resource Recovery through Enhanced Landfill Mining—A Review

Low‐alkali borosilicate glass microspheres from waste cullet prepared by flame synthesis

In vitrodissolution of bioactive glass S53P4 microspheres

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