In situ characterization of foam morphology during melting of simulated waste glass using x-ray computed tomography

被引：19

作者：

Luksic, Steven A. ^{[1
]}

Pokorny, Richard ^{[2
,3
]}

George, Jaime ^{[1
]}

Hrma, Pavel ^{[4
]}

Varga, Tamas ^{[1
]}

Reno, Loren R. ^{[1
]}

Buchko, Alexander C. ^{[1
]}

Kruger, Albert A. ^{[5
]}

机构：

[1] Pacific Northwest Natl Lab, 902 Battelle Blvd,POB 999,MSIN K6-28, Richland, WA 99354 USA

[2] Univ Chem & Technol, Prague 6, Czech Republic

[3] Inst Rock Struct & Mech ASCR, Vvi, Prague 8, Czech Republic

[4] North Wind Solut LLC, US DOE, Off River Protect, Sanford, NC USA

[5] US DOE, Off River Protect, Richland, WA 99354 USA

来源：

CERAMICS INTERNATIONAL | 2020年 / 46卷 / 11期

关键词：

X-ray methods; Non-destructive methods; Nuclear applications; BUBBLE NUCLEATION; HEAT-TRANSFER; RETENTION; FEED; GROWTH; FORM;

D O I：

10.1016/j.ceramint.2020.02.215

中图分类号：

TQ174 [陶瓷工业]; TB3 [工程材料学];

学科分类号：

0805 ; 080502 ;

摘要：

During batch-to-glass conversion, a glass-forming melt connects, creating a foam layer between the batch and the glass melt. Due to its transience and opacity, investigation of this foam layer presents a formidable challenge. In this work, we use in situ x-ray computed tomography to characterize the foam morphology that evolves during batch-to-glass conversion of a simulated nuclear waste glass. Rapid 1-min scans with 38 mu m voxels were performed to capture the foam structure during heating. Geometric volume, total porosity, and bubble size distribution are reported. Using evolved gas analysis and combining the temperature-dependent melt viscosity with x-ray data, we describe the evolution of foam structure during the foam growth and subsequent collapse.

引用

页码：17176 / 17185

页数：10

共 50 条

[31] Fibre and failure characterization in long glass fibre reinforced polypropylene by X-ray computed tomography
Maurer, Julia
Salaberger, Dietmar
Jerabek, Michael
Frohler, Bernhard
Kastner, Johann
Major, Zoltan
POLYMER TESTING, 2024, 130
[32] Characterization of the morphology of primary silicon particles using synchrotron X-ray tomography
Wang, J.
Guo, Z.
Xiong, S. M.
MATERIALS CHARACTERIZATION, 2017, 123 : 354 - 359
[33] Rudist taxonomy using X-ray computed tomography
Molineux, Ann
Scott, Robert W.
Ketcham, Richard A.
Maisano, Jessica A.
PALAEONTOLOGIA ELECTRONICA, 2007, 10 (03):
[34] VIRTUAL UNROLLING USING X-RAY COMPUTED TOMOGRAPHY
Allegra, D.
Ciliberto, E.
Ciliberto, P.
Milotta, F. L. M.
Petrillo, G.
Stanco, F.
Trombatore, C.
2015 23RD EUROPEAN SIGNAL PROCESSING CONFERENCE (EUSIPCO), 2015, : 2864 - 2868
[35] Microfocus X-ray computed tomography analysis of corroded glass objects
Mees, Florias
Cornelis, Etienne
Jacobs, Patric
Domenech Carbo, Maria Teresa
Roemich, Hannelore
ENGINEERING GEOLOGY, 2009, 103 (3-4) : 93 - 99
[36] IN-SITU FRAGMENT ANALYSIS WITH X-RAY COMPUTED TOMOGRAPHY, XCT
Wells, J. M.
ADVANCES IN CERAMIC ARMOR III, 2008, 25 (05): : 181 - 192
[37] In situ compression and X-ray computed tomography of flow battery electrodes
Rhodri Jervis
Matt D.R.Kok
Tobias P.Neville
Quentin Meyer
Leon D.Brown
Francesco Iacoviello
Jeff T.Gostick
Dan J.L.Brett
Paul R.Shearing
Journal of Energy Chemistry , 2018, (05) : 1353 - 1361
[38] X-Ray Computed Tomography In Situ: An Opportunity for Museums and Restoration Laboratories
Albertin, Fauzia
Bettuzzi, Matteo
Brancaccio, Rosa
Morigi, Maria Pia
Casali, Franco
HERITAGE, 2019, 2 (03): : 2028 - 2038
[39] Effects of X-Ray Dose On Rhizosphere Studies Using X-Ray Computed Tomography
Zappala, Susan
Helliwell, Jonathan R.
Tracy, Saoirse R.
Mairhofer, Stefan
Sturrock, Craig J.
Pridmore, Tony
Bennett, Malcolm
Mooney, Sacha J.
PLOS ONE, 2013, 8 (06):
[40] On the use of in situ X-ray computed tomography for soft contact mechanics
Acito, Vito
Dancette, Sylvain
Scheibert, Julien
Oliver, Cristobal
Adrien, Jerome
Maire, Eric
Dalmas, Davy
EUROPEAN JOURNAL OF MECHANICS A-SOLIDS, 2023, 101

← 1 2 3 4 5 →