Two angiotensin-converting enzyme-inhibitory peptides from almond protein and the protective action on vascular endothelial function

The influence of nano SiO2(NS) and CaCO3(NC) particles on the properties of class F fly ash based geopolymer mortar activated with different sodium ion concentrations have been investigated. Mortar mixture proportions were 1:3:0.3 for binder, sand, and water, respectively. Nano SiO2 and CaCO3 particles were replaced with a binder by weight basis at the ratios of 1, 2, and 3% in the mixtures. Sodium concentrations amount used were 8, 10, and 12% Na+ of binder content. Geopolymer mortar samples were cured at 60, 75, and 90°C in a furnace for 24, 48, and 72 hr. After the heat curing process, flexural, and compressive strength tests were performed. The changes in the microstructure of geopolymer due to influence of nanoparticles were examined by utilizing isothermal calorimetric studies on geopolymer paste, and field‐emission scanning electron microscopy (FESEM). Based on laboratory work results, it was concluded that for all sodium ion concentrations, the addition of nano SiO2 and CaCO3 particles improved the flexural and compressive strengths after 24 hr heat curing. However, the favorable effects of nanoparticles on strength properties tend to disappear after 48 and 72 hr heat curing. The results of isothermal calorimetric studies showed that nano SiO2 and CaCO3 particles accelerated the geopolymeric reactions at an early age. FESEM results showed that additions of nanoparticles made the microstructure of geopolymer products more intense and compact.

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Effects of chemical admixtures and curing conditions on some properties of alkali-activated cementless slag mixtures

Bilim

Karahan

Atiş

et al. 2015

KSCE J Civ Eng

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Influence of waste marble powder as a replacement of cement on the properties of mortar

Yamanel

Durak

İlkentapar

et al. 2019

rdlc

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Influence of duration of heat curing and extra rest period after heat curing on the strength and transport characteristic of alkali activated class F fly ash geopolymer mortar

İlkentapar

Atiş

Karahan

et al. 2017

Construction and Building Materials

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Resistance of polypropylene fibered mortar to elevated temperature under different cooling regimes

Karahan

Durak

İlkentapar

et al. 2019

rdlc

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Strength properties of slag/fly ash blends activated with sodium metasilicate

Luga¹,

Atiş²,

Karahan³

et al. 2017

JCE

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Strength properties of slag/fly ash blends activated with sodium metasilicateThe alkali activation of mortar blends containing Ground Granulated Blast Furnace Slag and Fly Ash, with activation based on sodium metasilicate, is investigated in this study. Two series are investigated, and compressive strength is measured. The results of the first series show that the compressive strength decreases considerably with a decrease in the slag and fly ash ratio. The 3-day compressive strength of mortar cured at the temperature of 100°C increases slightly up to the ratio of 60/40, but decreases considerably at the 40/60 ratio.

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Serhan İlkentapar

Very high strength (120MPa) class F fly ash geopolymer mortar activated at different NaOH amount, heat curing temperature and heat curing duration

Influence of admixtures on the properties of alkali-activated slag mortars subjected to different curing conditions

Influence of nano SiO₂ and nano CaCO₃ particles on strength, workability, and microstructural properties of fly ash‐based geopolymer

Effects of chemical admixtures and curing conditions on some properties of alkali-activated cementless slag mixtures

Influence of waste marble powder as a replacement of cement on the properties of mortar

Influence of duration of heat curing and extra rest period after heat curing on the strength and transport characteristic of alkali activated class F fly ash geopolymer mortar

Resistance of polypropylene fibered mortar to elevated temperature under different cooling regimes

Strength properties of slag/fly ash blends activated with sodium metasilicate

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Serhan İlkentapar

Very high strength (120MPa) class F fly ash geopolymer mortar activated at different NaOH amount, heat curing temperature and heat curing duration

Influence of admixtures on the properties of alkali-activated slag mortars subjected to different curing conditions

Influence of nano SiO2 and nano CaCO3 particles on strength, workability, and microstructural properties of fly ash‐based geopolymer

Effects of chemical admixtures and curing conditions on some properties of alkali-activated cementless slag mixtures

Influence of waste marble powder as a replacement of cement on the properties of mortar

Influence of duration of heat curing and extra rest period after heat curing on the strength and transport characteristic of alkali activated class F fly ash geopolymer mortar

Resistance of polypropylene fibered mortar to elevated temperature under different cooling regimes

Strength properties of slag/fly ash blends activated with sodium metasilicate

Contact Info

Product

Resources

About

Influence of nano SiO₂ and nano CaCO₃ particles on strength, workability, and microstructural properties of fly ash‐based geopolymer