Enhancing gypseous soil behavior using casein from milk wastes

Theyab, Arwa F.; Muhauwiss, Farouk M.; Alabdraba, Waleed M. Sh.

doi:10.1515/jmbm-2022-0041

Cited by 4 publications

(1 citation statement)

References 29 publications

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“…A significant gain in shear strength was detected by the direct shear results for the gypseous soil-treated xanthan gum biopolymer. The effect of casein biopolymer on gypseous soil was studied by Theyab et al [8]. Three primary gypseous soil characteristics were studied, i.e., compaction properties, shear strength, and collapse potential.…”

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confidence: 99%

Shear Strength Durability Investigation for Gypseous Soil Enhanced by Pectin Biopolymer

Muhauwiss,

Hussein,

Hussein

2024

Tikrit j. eng. sci.

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Several studies have shown that biopolymers improve soil; however, they mostly looked at how the shear strength and collapsibility improved without looking at how long the treatments would last. However, durability is an important factor that should be considered to get the most out of the treatment. This study investigates the durability and strength of gypseous soil enhanced by pectin biopolymer with periodic changes in wetting and drying. Soil with a gypsum content of 40% was mixed with 2% pectin biopolymer, and the samples were passed through successive wetting and drying cycles (1, 5, 10, and 15). The results indicated that periodic wetting and drying of pectin biopolymer-treated gypseous soil increased the shear strength of the soil until cycle 5, after which there was a slight and gradual decrease in strength until cycle 15 due to dissociation of pectin monomers under hydration and incomplete re-formation during re-drying, with a force decreasing by about 22% till ten cycles. Even beyond several cycles, some degree of strength and strength restoration could be observed. Also, the volumetric stability of the improved samples was clear until the last wetting and drying cycle.

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Section: Introductionmentioning

confidence: 99%

Shear Strength Durability Investigation for Gypseous Soil Enhanced by Pectin Biopolymer

Muhauwiss,

Hussein,

Hussein

2024

Tikrit j. eng. sci.

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Efficacy of Crustacean and Protein-Based Biopolymer Inclusion on the Strength Characteristics of Organic Soil

Rasheed,

Moghal

2024

Int. J. Geomech.

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Evaluation of Protein and Polysaccharide Biopolymers as Dust Suppressants on Mine Soils: Laboratory Experiments

2023

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Polysaccharide biopolymers have been shown to be alternatives to established dust suppressants. This study investigates the potential of 14 polysaccharides and proteins from diverse botanical (corn, pea, wheat, cellulose, potato, and fava bean) and animal (pig, chicken, and cow) sources as dust suppressants on two mine soils (medium-grained sand and fine-grained silica sand). Results of laboratory tests demonstrate that the type of biopolymer and its concentration have a significant effect on penetration resistance, moisture retention, and crust thickness. Depending on biopolymer type, concentration, and soil type, moisture retention range from 1.0 to 19.5 wt% (control, Cmedium-gr. = 2.5 and Cfine-gr. = 6.9 wt%), penetration resistance from 1.7 to 37.9 N (Cmedium-gr. = 1.5 and Cfine-gr. = 1.7 N), and crust thickness from 0.3 to 18.1 mm (Cmedium-gr. and Cfine-gr. = 0 mm). Proteins form crusts with penetration resistances similar to polysaccharides but mainly require higher concentrations than polysaccharides. Based on the test results, xanthan gum, carboxymethyl cellulose, corn starch, fava bean protein concentrate, and plasma protein exhibit the highest potential to act as dust suppressants. This research contributes to evaluating biopolymers as environmentally friendly soil amendments that may be used to control fugitive dust emissions from large, barren surfaces.

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Enhancing gypseous soil behavior using casein from milk wastes

Cited by 4 publications

References 29 publications

Shear Strength Durability Investigation for Gypseous Soil Enhanced by Pectin Biopolymer

Shear Strength Durability Investigation for Gypseous Soil Enhanced by Pectin Biopolymer

Efficacy of Crustacean and Protein-Based Biopolymer Inclusion on the Strength Characteristics of Organic Soil

Evaluation of Protein and Polysaccharide Biopolymers as Dust Suppressants on Mine Soils: Laboratory Experiments

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