A mathematical determination of the pore size distribution and fractal dimension of a porous sample using spontaneous imbibition dynamics theory

Amadu, Mumuni; Pegg, Michael J.

doi:10.1007/s13202-018-0477-9

Cited by 7 publications

(2 citation statements)

References 31 publications

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“…For example, Korak (1938) showed that the number of islands increased as their sizes decreased, conforming to a power law. Furthermore, this is also the case in the soil system where particles, aggregates, pores, etc., follow the same trend (Figure 3) (Pachepsky, Giménez, Crawford, & Rawls, 2000b; Ahmadi, Neyshabouri, Rouhipour, & Asadi, 2011; Amadu & Pegg, 2019; Martínez et al, 2010; Pachepsky, Crawford, & Rawls, 2000a; Posadas, Giménez, Quiroz, & Protz, 2003). Recently, Makey et al (2020) detected a “law” of self‐assembly for all types of materials and organisms from the smallest to the largest scales (with at least four orders of magnitude) irrespective of initial conditions, size, shape and function of the constituents that conform to a long tail distribution, called the Tracy‐Widom law.…”

Section: Introductionmentioning

confidence: 67%

Exploring the scaling law of geographical space: Gaussian versus Paretian thinking

Ibáñez

Ramírez‐Rosario

Fernández‐Pozo

et al. 2020

European J Soil Science

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A debate has occurred concerning the laws of scale and the fractal nature of geographical space. Biodiversity and pedodiversity studies show the emergence of fractal structures such as taxa‐area relationships. Biodiversity and pedodiversity are natural resources, although some consider pedotaxa to be artificial. The studies carried out to date emphasize that many pedodiversity and biodiversity spatial patterns converge at the same regularities. Many of these studies used natural resources maps and their digital databases. Information is extracted from the taxa types contained in each polygon and the areas covered. However, the structure of the maps (number, area, fragmentation, etc.) has rarely been a matter of study. When map structure was studied, intriguing similarities were observed in pedodiversity and biodiversity analyses. To understand whether these similarities also appear in other types of spatial entities that are more artificial, a review of geospatial analyses that studied topics such as urban maps, land system maps, etc., was undertaken. The main variables in these maps are manmade and/or combinations of natural resources data layers. Regularities detected in the geospatial information of these latter topics also seem to conform to results obtained when analysing natural resources maps such as soils, rock types, landforms, plant communities, etc. Thus, some geographers consider the idea that there are far more small things/objects than larger ones across several orders of magnitude in geographic space to be a law. Some geographers also contend that the classical “Gaussian thinking” and its statistical tools should be replaced by a “Paretian thinking” and its related statistical tools. This paper analyses the above topics as well as the lack of adequate data and types of cognitive maps we use in our modern scientific society, supporting the conjecture that that we should include Paretian thinking in our research at least in the same way we use Gaussian thinking. Highlights Long tail distributions, power laws and fractal‐like structures are ubiquitous in geospatial analysis. Scale invariance of natural and artificial map structures seem to be the rule. The Paretian approach appears to be more appropriate than the Gaussian approach for many purposes. Our cognitive maps and brain processing follow Paretian thinking in many instances.

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Section: Introductionmentioning

confidence: 67%

Exploring the scaling law of geographical space: Gaussian versus Paretian thinking

Ibáñez

Ramírez‐Rosario

Fernández‐Pozo

et al. 2020

European J Soil Science

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“…This was due to the increase in the width of pores and micro-cracks in the concrete at elevated temperature. Amadu et al [6] studied the pore structure characteristics of steel fibre concrete at 20°C, 400°C and 800°C, finding that after exposure to elevated temperature, the pores with diameter greater than 200 nm increased significantly and those with a pore diameter less than 50 nm decreased accordingly. Liu [7] divided the pores into several categories with regard to their impact on concrete performance: harmless (< 20 nm), less harmful (20 to 50 nm), harmful (50 to 200 nm) and more harmful (> 200 nm); this categorization is helpful to the present work, the purpose of which is to identify and characterize the range of pores present in SACC as the temperature increases.…”

Section: Introductionmentioning

confidence: 99%

The impact of changes in pore structure on the compressive strength of sulphoaluminate cement concrete at high temperature

Tchekwagep

Zhao

Wang

et al. 2021

Materials Science-Poland

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The internal pore structure of sulphoaluminate cement concrete (SACC) significantly affects its mechanical properties. The main purpose of this study was to establish the relationship between pore structure changes and compressive strength after exposure to elevated temperatures. SACC samples that had been cured for 12 months were dried to a constant weight and then exposed to different temperatures (100 °C, 200 °C and 300 °C), after which the compressive strength and pore structure were measured. The pore structure of SACC was quantitatively described by mercury intrusion porosimetry (MIP) and nitrogen adsorption results. The results showed that with increased temperature, the porosity of the SACC samples also increased and the pore structure was gradually destroyed. Moreover, the SACC’s compressive strength gradually decreased with increasing temperature. The relationship between compressive strength and porosity was in close agreement with the compressive strength–porosity equation proposed by Schiller. Therefore, after extensive exposure to elevated temperature, the changes in SACC’s compressive strength can be quantitatively described by the Schiller equation.

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Fractal characteristics of pore structure of hardened cement paste prepared by pressurized compact molding

Zhang

Zhou

2020

Construction and Building Materials

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A mathematical determination of the pore size distribution and fractal dimension of a porous sample using spontaneous imbibition dynamics theory

Cited by 7 publications

References 31 publications

Exploring the scaling law of geographical space: Gaussian versus Paretian thinking

Exploring the scaling law of geographical space: Gaussian versus Paretian thinking

The impact of changes in pore structure on the compressive strength of sulphoaluminate cement concrete at high temperature

Fractal characteristics of pore structure of hardened cement paste prepared by pressurized compact molding

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