Damage Accumulation in Silica Glass Nanofibers

Bonfanti, Silvia; Ferrero, Ezequiel E.; Sellerio, Alessandro Luigi; Guerra, Roberto; Zapperi, Stefano

doi:10.1021/acs.nanolett.8b00469

Cited by 21 publications

(13 citation statements)

References 43 publications

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“…Despite such consistent analysis within the framework of [51], the large value of τ c is surprising. Similar values have been discussed for silica nanofibres [56], amorphous silicon [58] and in preliminary results for a short ranged silica-like model [75]. Although the details in these systems differ, we speculate that the open framework structure common to these systems may provide an explanation.…”

supporting

confidence: 86%

“…Computational investigations of yielding in amorphous solids described above have largely been performed for solids with particles interacting with spherically symmetric, short ranged interactions. In particular, relatively few studies [37,[52][53][54][55][56] have addressed the archetypal glass, silica, which is characterised by an open, tetrahedral, local geometry, and whose interaction potential includes long range Coulomb interactions (or silicon [57][58][59][60], which shares several geometric and thermodynamic characteristics). In the liquid state, the tetrahedral network structure of silica entails a rich spectrum of novel behavior, including density maxima [61,62], a liquidliquid phase transition [63,64] and a strong-to-fragile transition [65][66][67][68].…”

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confidence: 99%

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Avalanches and Structural Change in Cyclically Sheared Silica Glass

Bhaumik,

Foffi,

Sastry

2021

Preprint

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We investigate avalanches associated with plastic rearrangements and the nature of structural change in the prototypical strong glass, silica, computationally. Although qualitative aspects of yielding in silica are similar to other glasses, we find that the statistics of avalanches exhibits non-trivial behaviour. Investigating the statistics of avalanches and clusters in detail, we propose and verify a new relation between exponents characterizing the size distribution of avalanches and clusters. Across the yielding transition, anomalous structural change and densification, associated with a suppression of tetrahedral order, is observed to accompany strain localisation.

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confidence: 86%

mentioning

confidence: 99%

Avalanches and Structural Change in Cyclically Sheared Silica Glass

Bhaumik,

Foffi,

Sastry

2021

Preprint

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“…∆σ max is the maximum stress drop and it is calculated following a procedure highlighted in Ref. [36]. It consists of (i) calculating the derivative of the stress-strain curve; (ii) identifying the strain interval for which the derivative is greater than a certain threshold (here we use zero, but we checked that our results are robust using different thresholds); (iii) for each strain interval, calculate the stress drop as the difference in the stress associated to the extremal values of the interval; (iv) the maximum stress drop is ∆σ max .…”

Section: Observables Data Analysis and Additional Resultsmentioning

confidence: 99%

Athermal Fracture of Elastic Networks: How Rigidity Challenges the Unavoidable Size-Induced Brittleness

2020

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By performing extensive simulations with unprecedentedly large system sizes, we unveil how rigidity influences the fracture of disordered materials. The largest damage is observed close to rigidity points when the rupture thresholds are small. Fewer bonds are broken when the thresholds are increased. Irrespectively of network and spring properties, a more brittle fracture is observed upon increasing system size, even in sub-isostatic networks where the underlying force chains govern the mechanical response. Most of the fracture descriptors show power-law size-scaling dependent on rigidity properties. Strikingly, the maximum stress drop, a proxy for brittleness, displays a universal doubly-non-monotonic dependence on system size and can be used as a novel parameter to identify different failure regimes. Our results indicate how to tune these regimes. Finally, we speculate how the size-induced brittleness is influenced by thermal fluctuations. arXiv:1907.11466v1 [cond-mat.soft]

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“…The peak stress s p is defined as the highest measured stress, and the peak strain e p is its corresponding strain value. The maximum stress drop Ds max is calculated according to a procedure 13,32 where we (i) calculate the derivative of the stress-strain curve, (ii) make a list of consecutive data points which have a negative derivative and note the initial and final strain of each interval, (iii) calculate the stress drops by subtracting the stress at the final strain from the stress at the initial strain, (iv) identify the largest stress interval, which corresponds to maximum stress drop Ds max . For the stress distribution analysis, we make instantaneous histograms of the bond lengths c i during the simulation at every percent strain.…”

mentioning

confidence: 99%