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Correlation between compressive strengths and water absorption of fly ash cement mortar immersed in water

Qian Huang Liang Zhao
Archives of Civil Engineering | 2019 | Vol. 65 | No 3 | 141-152
Keywords Water Immersion fly ash cement compressive strength water absorption correlation
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Abstract

The compressive strength and water absorption of cement mortars with different water-binder ratio (0.35, 0.45 and 0.55) and fly ash content (0, 10%, 20% and 30%) under water immersion were investigated, and the correlation between them was further analyzed. The internal microstructure and phase composition of mortar was studied by scanning electron microscopy (SEM) and X-ray diffraction (XRD), respectively. The results show that the inside of mortar mixed with fly ash displayed the loose and porous microstructure. Therefore, the incorporation of fly ash reduced the compressive strength of mortar, especially the early strength, and the strength decreased with the increase of fly ash content, and the water absorption of mortar also increased. There was a linear correlation between the compressive strength and water absorption of mortar with the equation: fc = -3.838β + 62.332, where fc and β represented the compressive strength and water absorption, respectively. Therefore, when the water absorption of mortar immersed in water was measured, its corresponding compressive strength could be preliminarily inferred through this equation, which was of great significance for detecting and identifying the stability and safety of hydraulic structures.

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Authors and Affiliations

Qian Huang
Liang Zhao

Molecular Cloning and Expression Analysis of CML27 in Brassica oleracea Pollination Process

Xiao Ping Lian Jing Zeng He Cui Zhang Xiao Hong Yang Liang Zhao Li Quan Zhu
Acta Biologica Cracoviensia s. Botanica | 2018 | vol. 60 | No 2 | 15–23 | DOI: 10.24425/118054
Keywords Brassica oleracea pollination CML27 LC-MS-MS (Q-TOF) assays
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Abstract

To keep genetic diversity, flowering plants have developed a self-incompatibility system, which can prevent self-pollination.

It has been reported that calcium concentration in pistil papilla cells was increased after self-pollination

in transformed self-incompatible Arabidopsis thaliana. In this study, we found that CML27 changed its expression

level for both mRNA and protein when compared to transcriptome and proteome. At the same time, CML27 was

expressed in the anther and pistil at a high level and reached up to 5-fold up-regulated expression in the pistil

at 1 h post-pollination when compared to 0 min. In order to find out potential proteins that may interact with

BoCML27, BoCML27 was expressed in and isolated from E. coli. After its co-incubation with Brassica oleracea

pistil proteins, the products were separated on SDS-PAGE gels. We found a specific band at the position between

130–180 kDa. Through LC-MS-MS (Q-TOF) analysis, eight proteins were identified from the band. The proteins

include 26S proteasome non-ATPase regulatory (26S), Phospholipase D, alpha 2 (PLDα2) involved in Ca2+ binding

and Coatomer subunit alpha-2-like (Coatomer) involved in vesicle mediated transport. All of these identified

proteins provide new insights for the self-incompatibility response in B. oleracea, specific for increasing Ca2+

concentration in pistil papilla cells.

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Authors and Affiliations

Xiao Ping Lian
Jing Zeng
He Cui Zhang
Xiao Hong Yang
Liang Zhao
Li Quan Zhu

Influence of kaolinite crystallinity and calcination conditions on the pozzolanic activity of metakaolin

Yuanyuan Liu Qian Huang Liang Zhao Shaomin Lei
Gospodarka Surowcami Mineralnymi - Mineral Resources Management | 2021 | vol. 37 | No 1 | 39-56 | DOI: 10.24425/gsm.2021.136295
Keywords kaolin crystallinity calcination conditions pozzolanic activity
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Abstract

Two kaolin ores with the almost same fineness and purity of original kaolinite but possessing different kaolinite crystallinity (Hinckley Index) were selected to study the influence of crystallinity and calcination conditions on the pozzolanic activity of metakaolin after dehydroxylation. The different calcination conditions were conducted by altering the calcination temperature and holding time to obtain different metakaolin samples with different degrees of dehydroxylation. Then pozzolanic activities of metakaolin samples were tested by the modified Chapelle test, Frattini test and strength evaluations. Additionally, the apparent activation energies of two kaolin ores were calculated to study the thermal properties of kaolinite by isoconversional methods followed by iterative computations. The results showed that pozzolanic activities were dependent on the degree of dehydroxylation, except for the metakaolins calcined at 900℃ due to the fact that recrystallization and high pozzolanic activity was conducted by complete dehydroxylation (degree of dehydroxylation ≥ 90%). Moreover, the lower crystallinity of original kaolinite favored the removal of the structural hydroxyls, leading to a reduction of apparent activation energy and increase of pozzolanic activity, indicating that the higher calcination temperature or longer holding time was required during calcination to reach the same degree of dehydroxylation and finally highly ordered kaolinite converted into the less active metakaolinite, which was confirmed by the lower Ca(OH)2 consumption in the modified Chapelle test, higher [CaO] and [OH] in the Frattini test and weaker compressive strength.
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Authors and Affiliations

Yuanyuan Liu
1
ORCID: ORCID
Qian Huang
1
Liang Zhao
1
Shaomin Lei
2
  1. Yangtze Normal University, Chongqing Engineering Research Center for Structure Full-Life-Cycle Health Detection and Disaster Prevention, China
  2. Wuhan University of Technology, China

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