How to search?
advanced search

Search results

Filters

  • Journals
  • Authors
  • Keywords
  • Date
  • Type

Search results

Number of results: 6
items per page: 25 50 75
Sort by:

Crystalline cones from eyes of Euphausia superba Dana

Stanisław Rakusa-Suszczewski
Polish Polar Research | 1994 | vol. 15 | No 3-4 | 131-134
Keywords Antarctica krill size crystalline cones
Download PDF Download RIS Download Bibtex

Abstract

The length of crystalline cones (cc) is proportional to krill body length and this proportion can be described by the equation L cc = L krill x 1.679 + 52.032 ( cc — μm; L krill - mm). By measuring cc one can determine the size of krill with the precision of 2—3 mm. The structure of crystalline cones is not crystal, and the elemental composition includes much of S and Ca. Crystalline cones are often found in the stomach and feces of animals feeding on krill.

Go to article

Authors and Affiliations

Stanisław Rakusa-Suszczewski

The influence of chitin structure on its enzymatic deacetylation

Małgorzata M. Jaworska George A.F. Roberts
Chemical and Process Engineering | 2016 | vol. 37 | No 2 June | 261-267 | DOI: 10.1515/cpe-2016-0021
Keywords chitin chitin deacetylase enzymatic deacetylation structure crystallinity conformation
Download PDF Download RIS Download Bibtex

Abstract

The possibility of producing chitosan by enzymatic deacetylation of chitin has been the subject of numerous investigations over the last twenty years, but to date no satisfactory method has been developed. In this paper the influence of chitin chain conformation and chitin particle crystallinity on the enzymatic deacetylation of chitin is investigated to determine the relative importance of these two factors on the process. It is shown that the high crystallinity of chitin is the main obstacle to converting chitin to chitosan by enzymatic deacetylation.

Go to article

Authors and Affiliations

Małgorzata M. Jaworska
George A.F. Roberts

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
Download PDF Download RIS Download Bibtex

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.
Go to article

Bibliography

1. Akahira, T. and Sunose, T. 1969. Trans. Joint Convention of Four Electrical Institutes. Paper No. 246. Research Report, Chiba Institute of Technology (Science Technology) 16, pp. 22.
2. ASTM C618:2013. Standard Specification for Fly Ash and Raw or Calcined Natural Pozzolan for Use as a Mineral Admixture in Portland Cement Concrete.
3. Badogiannis et al. 2005 – Badogiannis, E, Kakali, G. and Tsivilis, S. 2005. Metakaolin as supplementary cementitious material: Optimization of kaolin to metakaolin conversion. Journal of Thermal Analysis and Calorimetry 81(2), pp. 49–79.
4. Bich et al. 2009 – Bich, C., Ambroise, J. and Péra, J. 2009. Influence of degree of dehydroxylation on the pozzolanic activity of metakaolin. Applied Clay Science 44(3), pp. 194–200.
5. Cao et al. 2016 – Cao, Z., Cao, Y., Dong, H., Zhang, J. and Sun, C. 2016. Effect of calcination condition on the microstructure and pozzolanic activity of calcined coal gangue. International Journal of Mineral Processing 146, pp. 23–28.
6. Cyr et al. 2006 – Cyr, M., Lawrence, P. and Ringot, E. 2006. Efficiency of mineral admixtures in mortars: quantification of the physical and chemical effects of fine admixtures in relation with compressive strength. Cement and Concrete Research 36, pp. 264–277.
7. Donatello et al. 2010 – Donatello, S., Freeman-Pask, A., Tyrer, M. and Cheeseman, C.R. 2010. Effect of milling and acid washing on the pozzolanic activity of incinerator sewage sludge ash. Cement and Concrete Composites 32, pp. 54–61.
8. EN 196-1:2005. Methods of Testing Cement. Part 1: Determination of strength.
9. EN 196-5:2005. Methods of Testing Cement. Part 5: Pozzolanicity Test for Pozzolanic Cement.
10. Ferraz et al. 2015 – Ferraz, E., Andrejkovičová, S., Hajjaji, W., Velosa, A.L., Silva, A.S. and Rocha, F. 2015. Pozzolanic activity of metakaolins by the french standard of the modified chapelle test: a direct methodology. Acta Geodynamica et Geomaterialia 179, pp. 289–298.
11. Frías et al. 2000 – Frías, M., Sánchez de Rojas, M.I. and Cabrera, J. 2000. The effect that the pozzolanic reaction of metakaolin has on the heat evolution in metakaolin-cement mortars. Cement and Concrete Research 30, pp. 209–216.
12. Galos, K. 2011. Composition and ceramic properties of ball clays for porcelain stoneware tiles manufacture in Poland. Appled Clay Science 51(1), pp. 74–85.
13. Gao et al. 2001 – Gao, Z., Nakada, M. and Amasaki, I. 2001. A consideration of errors and accuracy in the isoconversional methods. Thermochimica Acta 369, pp. 137–142.
14. Janotka et al. 2010 – Janotka, I., Puertas, F., Palacios, M., Kuliffayová, M. and Varga, C. 2010. Metakaolin sand- -blended-cement pastes: rheology, hydration process and mechanical properties. Construction and Building Materials 791, pp. 802–24.
15. Kakali et al. 2001 – Kakali, G., Perraki, T., Tsivilis, S. and Badogiannis, E. 2001. Thermal treatment of kaolin: the effect of mineralogy on the pozzolanic activity. Applied Clay Science 20, pp. 73–80.
16. Kissinger, HE. 1957. Reaction Kinetics in Differential Thermal Analysis. Analytical Chemistry 29(11), pp. 1702–1706.
17. Liu et al. 2000 – Liu, Q, Xu, H. and Zhang, P. 2000. Crystallinity difference for various origin of kaolinites in coal measures. Journal of China Coal Society 25(6), pp. 576–580 (in Chinese).
18. Murat, M. 1983. Hydration reaction and hardening of calcined clays and related minerals I. Preliminary investigation on metakaolinite. Cement and Concrete Research 13, pp. 259–266.
19. NF P18-513:2010. Metakaolin. Pozzolanic addition for concrete. Definitions, specifications and conformity criteria.
20. Ozawa, T. 1965. A New Method of Analyzing Thermogravimetric Data. Bulletin of the Chemical Society of Japan 38(11), pp. 1881–1886.
21. Qiu et al. 2014 – Qiu, X., Lei, X., Alshameri, A., Wang, H. and Yan, C. 2014. Comparison of the physicochemical properties and mineralogy of Chinese (Beihai) and Brazilian kaolin. Ceramics International 40, pp. 5397–5405.
22. Sabir et al. 2001 – Sabir, B.B., Wild, S. and Bai, J. 2001. Metakaolin and calcined clays as pozzolans for concrete: a review. Cement and Concrete Composites 23, pp. 441–454.
23. Saikia et al. 2002 – Saikia, N., Sengupta, P., Gogoi, P.K. and Borthakur, P.C. 2002. Kinetics of dehydroxylation of kaolin in presence of oil field effluent treatment plant sludge. Applied Clay Science 22, pp. 93–102.
24. Samet et al. 2007 – Samet, B., Mnif, T. and Chaabouni, M. 2007. Use of a kaolinitic clay as a pozzolanic material for cements: Formulation of blended cement. Cement and Concrete Composites 29(10), pp. 741–749.
25. Sinthaworn, S. and Nimityongskul, P. 2011. Effects of temperature and alkaline solution on electrical conductivity measurements of pozzolanic activity. Cement and Concrete Composites 33, pp. 622–627.
26. Tironi et al. 2012 – Tironi, A., Trezza, M.A., Irassar, E.F. and Scian, A.N. 2012. Thermal treatment of kaolin: effect on the pozzolanic activity. Procedia Materials Science 1, pp. 343–350.
27. Tironi et al. 2013 – Tironi, A., Trezza, M.A., Scian, A.N. and Irassar, E.F. 2013. Assessment of pozzolanic activity of different calcined clays. Cement and Concrete Composites 37, pp. 319–327.
28. Tironi et al. 2014 – Tironi, A., Trezza, M.A., Scian, A.N. and Irassar, E.F. 2014. Thermal analysis to assess pozzolanic activity of calcined kaolinitic clays. Journal of Thermal Analysis and Calorimetry 117, pp. 547–556.
29. Wild et al. 1996 – Wild, S., Khatib, J.M. and Jones, A. 1996. Relative strength, pozzolanic activity and cement hydration in superplasticised metakaolin concrete. Cement and Concrete Research 26, pp. 1537–1544.
30. Zhang et al. 2015 – Zhang, Y., Xu, L., Seetharaman, S., Liu, L., Wang, X. and Zhang, Z. 2015. Effects of chemistry and mineral on structural evolution and chemical reactivity of coal gangue during calcination: towards efficient utilization. Materials and Structures 48, pp. 2779–2793.

Go to article

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

The Influence of the Processing Conditions on Changes in Physical and Structural Properties of Injection Moulded Parts Made of Polypropylene

P. Palutkiewicz A. Kalwik T. Jaruga
Archives of Metallurgy and Materials | 2023 | vol. 68 | No 4 | 1513-1518 | DOI: 10.24425/amm.2023.146217
Keywords injection moulding polypropylene shrinkage degree of crystallinity
Download PDF Download RIS Download Bibtex

Abstract

The injection moulding conditions may change the degree of crystallinity of the plastic to some extent, which affects the mechanical properties such as tensile strength and hardness. Moreover, the cooling conditions of the moulded parts may contribute to changes in their shrinkage. The paper presents the results of determination of the melting enthalpy of a polypropylene. The melting enthalpy ∆ Hm was determined by differential scanning calorimetry. It was found, that the value of the melting enthalpy depends on the physical conditions prevailing during the sample production process, such as the temperature of the liquid material, the cooling rate of the plastic (related to the mould temperature Tm) and the flow rate of the plastic in the mould. The degree of crystallinity of the obtained samples was also determined, which, depending on the measured enthalpy of fusion, influences the degree of structural order of the polymer. Standardized test samples were also analysed in terms of transversal shrinkage and longitudinal shrinkage. The shrinkage of the injection moulded parts results from the change of physical state of plastic during its solidification in the mould.
Go to article

Authors and Affiliations

P. Palutkiewicz
1
ORCID: ORCID
A. Kalwik
1
ORCID: ORCID
T. Jaruga
1
ORCID: ORCID
  1. Czestochowa University of Technology, Faculty of Mechanical Engineering and Computer Science, Department of Technology and Automation, 19C Armii Krajowej Av., 42- 201 Czestochowa, Poland

Hybrid, Multiscale Numerical Simulations of the Equal Channel Angular Pressing (ECAP) using the Crystal Plasticity Theory

Marta Wójcik
Archives of Metallurgy and Materials | 2023 | vol. 68 | No 4 | 1649-1655 | DOI: 10.24425/amm.2023.146235
Keywords Crystal plasticity ECAP process CPFEM polycrystals crystalline structure
Download PDF Download RIS Download Bibtex

Abstract

The FEM simulations of the ECAP including real conditions of the process – the friction between the metal extruded and the die walls, as well as, the channels rounding, were done here in two scales – macro- and micro-. The macroscopic analyses were done for isotopic material with a non-linear hardening using the UMAT user material procedure. The pure Lagrangian approach was applied here. The stress, strains and their increments, as well as, the deformation gradient tensor were recorded for selected finite elements in each calculation step. The displacements obtained in the macroscopic FEM analysis are then used as the kinematic input for the polycrystalline structure. The dislocation slip was included as the source of the plastic deformation here for the face-centered cubic structure. The results obtained with the use of the crystal plasticity show the heterogeneous distribution of stress and strain within the material associated with the grains anisotropy. The results in both micro- and macro- scales are coincident. The FEM analyses show the potential of the application of the crystal plasticity approach for solving elastic-plastic problems including the material forming processes.
Go to article

Authors and Affiliations

Marta Wójcik
1
ORCID: ORCID
  1. Rzeszow University of Technology, Faculty of Mechanical Engineering and Aeronautics, Department of Materials Forming and Processing, 8 Powstańców Warszawy Av., 35-959 Rzeszów, Poland

Stability of αB-crystallin gene expression in canine mammary gland neoplasms. Should it be considered as circulating tumor cell genetic marker?

M. Chmielewska-Krzesińska A. Jakimiuk K. Wąsowicz
Polish Journal of Veterinary Sciences | 2019 | vol.22 | No 3 | 523-529 | DOI: 10.24425/pjvs.2019.129960
Keywords αB-crystallin (CRYAB) canine mammary gland tumor circulating tumor cells (CTC) cytokeratin 17 (CK17)
Download PDF Download RIS Download Bibtex

Abstract

αB-crystallin is a member of a small family of thermal shock proteins that protects cells from stress. Because of lack of its expression in peripheral blood leukocytes, it was proposed as a molecular marker of circulating tumor cells in canine mammary gland tumors. The aim of the present study was to determine if αB-crystallin shows stability of expression, what is the requirement for this type of marker. It was also assessed whether there is co-expression of αB-crystallin with the basal marker, cytokeratin 17. For this purpose, samples of various types of canine mammary gland tumors of epithelial origin, were selected. Using RT-qPCR, we have found αB-crystallin and cytokeratin 17 co-expression in benign and malignant canine mammary gland tumors. It has been demonstrated that the expression of αB-crystallin in tested neoplastic samples is not stable in comparison to the control group. Furthermore αB-crystallin overor down- expression was associated witch the same cytokeratin 17 pattern. αB-crystallin can be a marker of circulating tumor cells in the bloodstream, but for cancers in which basal marker expression occurs and thus not universal for all cancers originating from the mammary gland tissue.

Go to article

Authors and Affiliations

M. Chmielewska-Krzesińska
A. Jakimiuk
K. Wąsowicz

This page uses 'cookies'. Learn more