2012
DOI: 10.1029/2012jb009590
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Effects of interfacial energy on compaction creep by intergranular pressure solution: Theory versus experiments on a rock analog (NaNO3)

Abstract: [1] Pressure solution plays an important role in compaction and lithification of sediments and fault gouges, but the effects of interfacial energy on this process are generally neglected. Here, microphysical models for densification of solid/liquid systems by pressure solution are derived, accounting for interfacial energy besides stress-related driving forces. They predict that densification by pressure solution creep will slow down at very fine grain sizes, where opposing interfacial energy driving forces be… Show more

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Cited by 14 publications
(16 citation statements)
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“…Time-independent volumetric compaction of sands (i.e., instantaneous compaction for which creep effects are negligible), by mechanisms such as grain rearrangement, grain rotation, intergranular sliding, elastic deformation, and grain breakage, plays an important role in determining porosity and permeability reduction during burial of clastic sediments [Antonellini et al, 1994;Burley, 1986;Chester et al, 2004;Chuhan et al, 2002Chuhan et al, , 2003Donaldson et al, 1995;Wilson and McBride, 1988]. In general, these mechanisms operate alongside time-dependent processes like pressure solution [Groshong, 1988;Milliken, 1994;Niemeijer et al, 2002;Onasch, 1994;Schutjens, 1991;Visser et al, 2012].…”
Section: Introductionmentioning
confidence: 99%
“…Time-independent volumetric compaction of sands (i.e., instantaneous compaction for which creep effects are negligible), by mechanisms such as grain rearrangement, grain rotation, intergranular sliding, elastic deformation, and grain breakage, plays an important role in determining porosity and permeability reduction during burial of clastic sediments [Antonellini et al, 1994;Burley, 1986;Chester et al, 2004;Chuhan et al, 2002Chuhan et al, , 2003Donaldson et al, 1995;Wilson and McBride, 1988]. In general, these mechanisms operate alongside time-dependent processes like pressure solution [Groshong, 1988;Milliken, 1994;Niemeijer et al, 2002;Onasch, 1994;Schutjens, 1991;Visser et al, 2012].…”
Section: Introductionmentioning
confidence: 99%
“…This will further reduce the porosity and permeability of the Ca(OH) 2 produce and whole sample until healing of the grain contacts occurs by internal or contact margin precipitation, i.e. via contact asperity or neck growth phenomena [122,123]. As indicated above, grain growth involving grain boundary migration, driven by surface energy reduction in the fine product phase, could also disconnect pores and reduce permeability simply by overgrowing and isolating pores [69].…”
Section: Transport Path Shutdown Mechanismsmentioning
confidence: 99%
“…These generally low stress exponents differ from the classic aggregate models, which predict n = 1 [e.g., Rutter , ; Paterson , ], and from those found in many experimental studies, which often are much larger than unity. For example, Niemeijer et al [] found stress exponents of 3 to 3.6 during compaction of quartz sand packs at temperatures of 400–600°C and lithostatic effective pressures of 50–150 MPa (a slightly lower value of 2.5 was obtained by Fitzenz et al [], who used a more accurate Bayesian inference method to reinterpret Niemeijer et al's data).In contrast, low apparent stress exponents were observed in experiments by Visser et al [], who compacted sodium nitrate sphere packs at low loads. The conditions in these tests were almost identical to that assumed in the simulations.…”
Section: Discussionmentioning
confidence: 99%
“…Following Visser et al . 's [, Figures 6–7] graphic approach, we plotted the simulated strain rates (measured at constant strain levels) versus p c , 1/ T , or r and interpreted them in terms of apparent values of n , H , and m (Figures and ). The results can be summarized as follows: Stress exponentIn all simulations, the effective stress exponents increased with increasing strain (or time) assuming values about 0.3 at strains less than 1%, to about 1 for strains approaching 15% (Figure a).…”
Section: Discussionmentioning
confidence: 99%
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