The Use of Atomic Force Microscopy to Study Crack Tips in Glass

Wiederhorn, Sheldon M.; Guin, Jean‐Pierre; Fett, T.

doi:10.1007/s11661-010-0411-3

Cited by 22 publications

(17 citation statements)

References 58 publications

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“…The literature showed an increase in diffusion constants of ions, specifically Na, within the cracks when compared to the bulk glass. 53,54 The diffusion of these ions also creates a condensate region at the surface of the glass around the cracks. The pH in these regions increases compared to that of the bulk solution, which can lead to regions of increased silicate ion formation due to hydrolysis.…”

Section: Effects Of Surface Cracksmentioning

confidence: 99%

Various effects of magnetite on international simple glass (ISG) dissolution: implications for the long-term durability of nuclear glasses

et al. 2017

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Understanding the effect of near-field materials, such as iron corrosion products, on the alteration of vitreous nuclear waste is essential for modeling long-term stability of these waste forms in a geological repository. This work presents experimental results for which monoliths of International Simple Glass-a six oxide borosilicate glass-, with polished and unpolished cut sides, were aged for 70 days under oxic conditions at 90°C in a solution initially saturated in 29 SiO 2 at pH 7; then magnetite was added to the leaching environment. Solution and solid analyses were performed to correlate the changes in the surface features and dissolution kinetics. It was found that magnetite primarily influences the mechanically constrained surface of the non-polished sides of the monoliths, with little to no effect on the polished surfaces. This work highlights the importance of the unique chemistry within surface cracks that invokes a drastic change in alteration of glass in environments containing iron corrosion products.

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Section: Effects Of Surface Cracksmentioning

confidence: 99%

Various effects of magnetite on international simple glass (ISG) dissolution: implications for the long-term durability of nuclear glasses

et al. 2017

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“…This article discusses recent experimental measurements and theoretical calculations relevant to the structure of crack tips in glass. The article is a follow‐up to an earlier paper on this subject . Topics discussed include surface displacements at crack tips, water diffusion into the tips of cracks during fracture, the size of the nonlinear zones at crack tips, and environmental conditions at crack tips.…”

Section: Introductionmentioning

confidence: 99%

“…The z resolution gives near atomic resolution for the AFM. For details on how the AFM may be used to study cracks in glass, reference is recommended.…”

Section: Introductionmentioning

confidence: 99%

Griffith Cracks at the Nanoscale

Wiederhorn

Fett

Guin

et al. 2013

Int J of Appl Glass Sci

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International audienceWhen Griffith presented his famous theory of crack stability in elastic materials in the early twentieth century, he was unable to provide much detail on the structure of cracks at the nanometer level of resolution. Now, almost 100years later, techniques such as transmission electron microscopy, atomic force microscope, nuclear reaction analysis, and nuclear reflection are available to achieve this level of resolution. Here, we review the kind of data obtained using these techniques and the implications of the data vis-a-vis cracks in silicate glasses. Measurements by atomic force microscopy provide information on the size of the nonlinear zone at crack tips in glass, on environmental conditions at crack tips, and on the possibility of cavity formation as a mechanism of crack growth. Examination by nuclear reaction analysis and neutron reflection of fresh fracture surfaces formed in water has yielded information on water penetration through the glass surrounding the crack tip, to a resolution of 3-5nm. Improvement of measurement techniques in the coming years should enable us to study crack tips in glasses to even higher levels of resolution and to answer more detailed questions concerning the level of stress and the size of the nonlinear zone at the crack tip

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“…To date, most fundamental research on subcritical crack growth has been conducted on silicate and multicomponent glasses. Several reviews and key papers cover the history and development of our understanding of subcritical crack growth in glass (Ciccotti, ; Freiman et al, ; Pallares et al, ; Wiederhorn, Fett, et al, ; Wiederhorn, Guin, et al, ; Wiederhorn, Fett, Guin, et al, , Wiederhorn, Fett, Rizzi, et al, ; Wiederhorn et al, ). Milligan () and Preston () recognized that both liquid water and water vapor play a role in controlling the strength of glass.…”

Section: Why Chemistry Is Important In Understanding Formation and Evmentioning

confidence: 99%

“…Nanoscale subcritical cracks in glass have been studied analytically (Wiederhorn, Guin, et al, ) using transmission electron microscopy, atomic force microscopy, nuclear reaction analysis, and nuclear reflection. These approaches provide insights into the molecular fundamentals of the fracture process and lead to a deeper understanding of the mechanisms of fatigue and subcritical growth.…”

Section: Why Chemistry Is Important In Understanding Formation and Evmentioning

confidence: 99%

The Role of Chemistry in Fracture Pattern Development and Opportunities to Advance Interpretations of Geological Materials

Laubach

Lander²,

Criscenti

et al. 2019

Reviews of Geophysics

229

106

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Fracture pattern development has been a challenging area of research in the Earth sciences for more than 100 years. Much has been learned about the spatial and temporal complexity inherent to these systems, but severe challenges remain. Future advances will require new approaches. Chemical processes play a larger role in opening‐mode fracture pattern development than has hitherto been appreciated. This review examines relationships between mechanical and geochemical processes that influence the fracture patterns recorded in natural settings. For fractures formed in diagenetic settings (~50 to 200 °C), we review evidence of chemical reactions in fractures and show how a chemical perspective helps solve problems in fracture analysis. We also outline impediments to subsurface pattern measurement and interpretation, assess implications of discoveries in fracture history reconstruction for process‐based models, review models of fracture cementation and chemically assisted fracture growth, and discuss promising paths for future work. To accurately predict the mechanical and fluid flow properties of fracture systems, a processes‐based approach is needed. Progress is possible using observational, experimental, and modeling approaches that view fracture patterns and properties as the result of coupled mechanical and chemical processes. A critical area is reconstructing patterns through time. Such data sets are essential for developing and testing predictive models. Other topics that need work include models of crystal growth and dissolution rates under geological conditions, cement mechanical effects, and subcritical crack propagation. Advances in machine learning and 3‐D imaging present opportunities for a mechanistic understanding of fracture formation and development, enabling prediction of spatial and temporal complexity over geologic timescales. Geophysical research with a chemical perspective is needed to correctly identify and interpret fractures from geophysical measurements during site characterization and monitoring of subsurface engineering activities.

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The Use of Atomic Force Microscopy to Study Crack Tips in Glass

Cited by 22 publications

References 58 publications

Various effects of magnetite on international simple glass (ISG) dissolution: implications for the long-term durability of nuclear glasses

Various effects of magnetite on international simple glass (ISG) dissolution: implications for the long-term durability of nuclear glasses

Griffith Cracks at the Nanoscale

The Role of Chemistry in Fracture Pattern Development and Opportunities to Advance Interpretations of Geological Materials

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