Development of glasses for the vitrification of high level liquid waste (HLLW) in a joule heated ceramic melter

Luckscheiter, B.; Nesovic, M.

doi:10.1016/s0956-053x(97)88231-1

Cited by 50 publications

(29 citation statements)

References 4 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…α-cristobalite is the major crystal phase seen in heat treated samples with the Type A microstructure and has been reported to form in other borosilicate glasses [15,53,63,65,69,89,[93][94][95][96]. Dendritic and globular morphologies for α-cristobalite crystals in borosilicate HLW glasses have been reported [15].…”

Section: Sio 2 (α-Cristobalite)mentioning

confidence: 94%

“…As these Ni-rich crystals are electron beam stable in the TEM they may form in actual borosilicate HLW glasses [101]. The Ni-rich crystals are a potential host for 63 Ni (an activation product). silicate apatite [3,19,24,51,53,61,68] or stillwellite [3,59,69].…”

Section: Sio 2 (α-Cristobalite)mentioning

confidence: 98%

“…This internal cracking and voiding will continue as the crystal cools to room temperature due to the faster contraction of α-cristobalite compared to the surrounding glass matrix. The formation of cristobalite crystals would be detrimental to wasteform aqueous durability as their precipitation removes SiO 2 from the surrounding glass matrix [7,49,63,69,93,96], resulting in a glass of lower aqueous durability than the parent glass, especially around the crystals [69].…”

Section: Sio 2 (α-Cristobalite)mentioning

confidence: 99%

See 2 more Smart Citations

Crystallisation of a simulated borosilicate high-level waste glass produced on a full-scale vitrification line

Rose

Woodward

Ojovan

et al. 2011

Journal of Non-Crystalline Solids

View full text Add to dashboard Cite

A simulated (inactive) borosilicate high-level waste (HLW) glass was produced on a full-scale vitrification line with composition simulating vitrified oxide fuel (UO 2 ) reprocessing waste. As-cast samples were compositionally homogeneous (Type I microstructure) and/or compositionally inhomogeneous displaying compositional 'banding' and frequently containing 'reprecipitated calcine' (Type II microstructure).Crystal phases identified in as-cast samples were: tetragonal RuO 2 , cubic Pd-Te alloy, cubic (Cr,Fe,Ni,Ru) Sn and U). Cracking in samples was attributed to thermal expansion mismatch between the borosilicate HLW glass matrix and RuO 2 , cristobalite (both α and β), (Na,Sr,Nd,La)MoO 4 and zektzerite on cooling. There was also a contribution from the cristobalite α-β phase transition.

show abstract

Section: Sio 2 (α-Cristobalite)mentioning

confidence: 94%

Section: Sio 2 (α-Cristobalite)mentioning

confidence: 98%

Section: Sio 2 (α-Cristobalite)mentioning

confidence: 99%

See 1 more Smart Citation

Crystallisation of a simulated borosilicate high-level waste glass produced on a full-scale vitrification line

Rose

Woodward

Ojovan

et al. 2011

Journal of Non-Crystalline Solids

View full text Add to dashboard Cite

show abstract

“…Analysis of the recorded spectra showed that the substitution of the alkali-metal cations Ba 2+ and Ca 2+ for the Na + cation results in breaking of B-O-B and Si-O-Si bridges, as a result of which the fraction of oxygen end atoms increases and the degree of polymerization of the glass decreases.Matrices based on borosilicate glasses with different composition, which have the advantages of high radiation resistance and simple fabrication technology, are now widely used to immobilize radwastes [1]. Even though these glasses have long been used as a matrix material, the search for optimal compositions remains unresolved and requires continued study of the structure and properties of borosilicate glasses with a wide spectrum of compositions.…”

mentioning

confidence: 99%

“…Matrices based on borosilicate glasses with different composition, which have the advantages of high radiation resistance and simple fabrication technology, are now widely used to immobilize radwastes [1]. Even though these glasses have long been used as a matrix material, the search for optimal compositions remains unresolved and requires continued study of the structure and properties of borosilicate glasses with a wide spectrum of compositions.…”

mentioning

confidence: 99%

Borosilicate glass structure with rare-earth-metal cations substituted for sodium cations

2011

View full text Add to dashboard Cite

IR and RS spectroscopy are used to study the effect of substituting barium and calcium for the sodium cation on the structure of sodium borosilicate glass with the composition 0.25Na 2 O; 0.25B 2 O 3 ; 0.5SiO 2 . Analysis of the recorded spectra showed that the substitution of the alkali-metal cations Ba 2+ and Ca 2+ for the Na + cation results in breaking of B-O-B and Si-O-Si bridges, as a result of which the fraction of oxygen end atoms increases and the degree of polymerization of the glass decreases.Matrices based on borosilicate glasses with different composition, which have the advantages of high radiation resistance and simple fabrication technology, are now widely used to immobilize radwastes [1]. Even though these glasses have long been used as a matrix material, the search for optimal compositions remains unresolved and requires continued study of the structure and properties of borosilicate glasses with a wide spectrum of compositions.The objective of the present work was to study the effect of substituting calcium and barium for the sodium cation on the structure of sodium borosilicate glass with the composition (mole fraction) 0.25Na 2 O; 0.25B 2 O 3 ; 0.5SiO 2 . The structure of glass with this composition has been studied in detail experimentally in [2, 3] and theoretically in [4]. It has been established that the boron atoms in this glass can occupy ternary and quaternary coordination, the former are mainly flat symmetric triangles BØ 3/2 (Ø -oxygen bridge atom) in which all oxygen atoms are bridge atoms. The fraction of asymmetric triangles BØ 2/2 O -is small but measurable experimentally. The silicate component of the network of this glass is represented as Q 4 , Q 3 and, possibly, in very small amounts Q 2 units (Q n -silicon-oxygen tetrahedron with n oxygen bridge atoms). Thermodynamic modeling shows that the fraction of different types of structural units in glasses with the compositions studied is as follows [4]: BØ 4/2 (B 4 ) -0.152; BØ 3/2 (B 3 ) -0.173; BØ 2/2 O -(B 3-) -0.009; Q 4 (SiØ 4/2 ) -0.326; Q 3 (SiØ 3/2 O -) -0.336; Q 2 (SiØ 2/2 OO 2 -) -0.002.On the whole it is evident that the distribution of the sodium ions between the silicon-and boron-containing structural units is approximately proportional to the value K = SiO 2 /B 2 O 3 (2 : 1). The sodium ions compensate the charge of the borate tetrahedral and oxygen end atoms belonging to the silicate structural units. EXPERIMENTAL PARTTwo series of glasses were synthesized and studied in this work. In the first series, calcium cations were gradually substituted for sodium cations, while in the second series barium cations were substituted for the sodium cations. The glasses were synthesized from reagents: analytically pure SiO 2 , ultrapure B 2 O 3 , and chemically pure CaO, BaO, and Na 2 CO 3 . The initial reagents taken in the appropriate proportions were carefully mixed with alcohol in a porcelain mortar, dried at temperature 100 -150°C, and melted in a platinum crucible in an electric furnace with a nichrome heater at temperature...

show abstract

Immobilization by Vitrification

Donald

2010

Waste Immobilization in Glass and Ceramic Based Hosts

View full text Add to dashboard Cite

Development of glasses for the vitrification of high level liquid waste (HLLW) in a joule heated ceramic melter

Cited by 50 publications

References 4 publications

Crystallisation of a simulated borosilicate high-level waste glass produced on a full-scale vitrification line

Crystallisation of a simulated borosilicate high-level waste glass produced on a full-scale vitrification line

Borosilicate glass structure with rare-earth-metal cations substituted for sodium cations

Immobilization by Vitrification

Contact Info

Product

Resources

About