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    Poly (styrene) latex/modified na-activated bentonite nanocomposite films: a fluorescence study
    (Elsevier Science BV, 2008-12) Uğur, Şaziye; Yargı, Önder; Günister, Ebru; Pekcan, Mehmet Önder
    We studied film formation of composites of surfactant-free polystyrene (PS) nanoparticles and modified Na-activated bentonite (MLB), by steady state fluorescence (SSF) technique. The films were prepared from a mixture of pyrene (P)-labeled PS particles and MLB at various compositions at room temperature. These films were annealed at elevated temperatures above the glass transition (T(g)) temperature of polystyrene for 10 min. Scattered light (I(S)) and fluorescence intensities (I(P)) from P were measured after each annealing step to monitor the stages of film formation. Evolution of transparency of the composite films was monitored by using photon transmission intensity, I(tr) Atomic force microscopy (AFM) was used to detect the variation in physical structure of annealed composite films. The nanocomposite films exhibited a percolation threshold at 20 wt.% MLB content. Below this fraction two distinct film formation stages were observed which are known as void closure and interdiffusion and above this fraction no film formation was detected. At 0-20 wt.% MLB, minimum film formation, T(0), void closure, T(v) and healing, T(h) temperatures were determined. Void closure and interdiffusion stages were modeled and related activation energies were determined. Void closure activation energies decreased as the percent of MLB increased, no variation was observed in backbone activation energies.
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    Films formed from polystyrene latex/clay composites: A fluorescence study
    (Springer New York, 2005-07) Uğur, Şaziye; Alemdar, Ayşe; Pekcan, Mehmet Önder
    This study reports a steady-state fluorescence (SSF) technique for studying film formation from surractant-free polystyrene (PS) latex and Na-montmorillonite (SNaM) composites. The composite films were prepared from pyrene (P)-labeled PS particles and SNaM clay at room temperature and annealed at elevated temperatures in 10-min intervals above glass transition temperature (T-g) of polystyrene. During the annealing processes, the transparency of the fllm improved considerably. Scattered light (I-s) and fluorescence intensity (I-s) from P were measured after each annealing step to monitor the stages of film formation. Evolution of transparency of composite films was monitored by using photon transmission intensity, I-tr Scanning electron microscopy (SEM) was used to detect the variation in physical structure of annealed composite-films. Minimum flIm formation temperature, T-o, and healing temperatures, T-h, were determined. Void closure and interdiff-usion stages were modeled and related activation energies were determined. It was observed that both activation energies increased as the percent of SNaM was increased in composite films.
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    The effect of clay particles on film formation from polystyrene latex
    (Wiley, 2006-06) Uğur, Şaziye; Alemdar, Ayşe; Pekcan, Mehmet Önder
    Film formation from surfactant-free polystyrene (PS) latex was performed in the presence of 5% Na-montmorillonite (NaMMT). The composite films were prepared from pyrene (P)-labeled PS particles at room temperature and annealed at elevated temperatures above the glass-transition (T-g) temperature of polystyrene. Scattered light (I-s) and fluorescence intensity (I-p) from P were measured after each annealing step to monitor the stages of composite film formation. Minimum film formation temperature, T-o, and healing temperatures, T-h, were determined. Void closure and interdiffusion stages were modeled and related activation energies were measured. From these results, it was found that the presence of NaMMT in the PS latex film only affects the minimum film formation, but does not affect the void closure and backbone motion activities.
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    Industrial wastes for soil stabilization
    (CRC Press, 2026-01-01) Etminan, Ehsan
    Soil stabilization is an important geotechnical engineering method designed to enhance the engineering properties of soil, including its strength, durability, and load-bearing capacity. These improvements are essential for the effective implementation of infrastructure projects, including roadways, embankments, foundations, and airfields. Traditional methods of stabilizing soil usually involve adding materials like cement, lime, or bitumen to soft and expansive clay soils. Although effective, these traditional technologies are frequently economically unfeasible and ecologically unsustainable due to their substantial energy demands and carbon emissions. Recent studies have looked at using industrial by-products-like fly ash, blast furnace slag, red mud, bagasse ash, and cement kiln dust (CKD)-as alternative stabilizers in order to lower the environmental impact of conventional materials and cut costs. Often considered as environmental liabilities, these industrial byproducts can have major technical benefits when used for soil stabilization projects. This integration reduces landfill use and promotes recycling, so it follows ideas of the circular economy. This chapter aims to review conventional and innovative stabilization methods, evaluate industrial waste and their stabilization procedures, compile worldwide laboratory and field case studies, and offer technical and financial evaluations. It concludes with policies, research gaps, and prospective directions.