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PETROGRAPHY AND CATHODOLUMINESCENCE MICROSCOPY IN THE STUDY OF ALKALI REACTIVE GRANITIC ROCKS IN CONCRETE

Fernandes, Isabel, Couto, Helena, Santos, Ana

First published: 2014-06-20https://doi.org/10.5593/sgem2014/b12/s2.092View metrics

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Title
PETROGRAPHY AND CATHODOLUMINESCENCE MICROSCOPY IN THE STUDY OF ALKALI REACTIVE GRANITIC ROCKS IN CONCRETE
Authors
Fernandes, Isabel, Couto, Helena, Santos, Ana
Proceedings
SGEM International Multidisciplinary Scientific GeoConference EXPO Proceedings; 14th SGEM GeoConference on SCIENCE AND TECHNOLOGIES IN GEOLOGY, EXPLORATION AND MINING
Publisher
Stef92 Technology
Year
2014
Pages
Not available yet
ISSN
1314-2704
ISBN
978-619-7105-08-7
Language
en
Publication type
Conference Paper
Keywords
References28
  1. Götze J. Application of Nomarski DIC and cathodoluminescence (CL) microscopy to building materials, Materials Characterization, vol. 60, pp 594-602, 2009.

  2. Št’astná A., Šachlová Š., Pertold Z., Přikryl R. & Leichmann J. Cathodoluminescence microscopy and petrographic image analysis of aggregates in concrete pavements affected by alkali-silica reaction, Materials Characterization, Springer, vol. 65, pp 115-125, 2012.

  3. RILEM AAR-3. Detection of potential alkali-reactivity – 38ºC method for aggregate combinations using concrete prisms. In: Special Issue RILEM TC219 -ACS, Materials & Structures, vol. 47 (in press), 2014.

  4. RILEM AAR-4. Detection of potential alkali-reactivity – 60ºC method for aggregate combinations using concrete prisms. In: Special Issue RILEM TC219-ACS, Materials & Structures, vol. 47 (in press), 2014.

  5. LNEC E 461. Betões. Metodologias para prevenir reacções expansivas internas. Laboratório Nacional de Engenharia Civil, Lisboa, 6 pp, 2007 (in Portuguese).

  6. RILEM AAR-1: Detection of potential alkali reactivity of aggregates – petrographic method. Alkali reactivity and prevention – assessment, specification and diagnosis of alkali-reactivity. In TC 191-ARP, Materials & Structures (p repared by Sims I. & Nixon P.), vol. 36, pp 472–479, 2003.

  7. St John D.A., Poole A. W. & Sims I. Concrete petrography. A handbook of investigative techniques. Arnold, London, UK: 474 pp, 1998.

  8. Shayan A. Alkali reactivity of deformed granitic rocks: a case study. Cement and Concrete Research, vol. 23, pp 1229-1236, 1993.

  9. Wenk H-R, Monteiro PJM & Shomglin K. Relationship between aggregate microstructure and mortar expansion. A case study of deformed granitic rocks from Santa Rosa mylonite zone. Journal of Materials and Science, vol. 43, pp 1278 -1285, 2008.

  10. Locati F., Marfil S.A., Baldo E. Effect of ductile deformation of quartz -bearing rocks on the alkali-silica reaction. Engineering Geology, vol. 116, pp 117-128, 2010.

  11. Alaejos P. & Lanza V. Influence of equivalent reactive quartz content on expansion due to alkali-silica reaction. Cement and Concrete Research, vol. 42, pp 99-104, 2012.

  12. Marinoni N. & Broekmans M.A.T.M. Microstructure of selected aggregate quartz by XRD, and a critical review of the crystallinity index. Cement and Concrete Research, vol. 54, pp 215-225, 2012.

  13. Götze J., Schertl H.P., Neuser R.D., Kempe U. & Hanchar J.M. Optical microcope- cathodoluminescence (OM-CL) imaging as a powerful tool to reveal internal textures of minerals, Mineralogy & Petrology, vol. 107, pp 373-392, 2013.

  14. Couto H., Lourenço A. & Borges, F. Estudo de quartzos em catodoluminescência. Revista Electrónica de Ciências da Terra, Geosciences On-line Journal, e-Terra ,http://e- terra.geopor.pt. ISSN 1645-0388, vol. 16, nº 2, 2010.

  15. Götze J. Application of Nomarski DIC and cathodoluminescence (CL) microscopy to building materials, Materials Characterization, vol. 60, pp 594-602, 2009.

  16. Št’astná A., Šachlová Š., Pertold Z., Přikryl R. & Leichmann J. Cathodoluminescence microscopy and petrographic image analysis of aggregates in concrete pavements affected by alkali-silica reaction, Materials Characterization, Springer, vol. 65, pp 115-125, 2012.

  17. RILEM AAR-3. Detection of potential alkali-reactivity – 38ºC method for aggregate combinations using concrete prisms. In: Special Issue RILEM TC219 -ACS, Materials & Structures, vol. 47 (in press), 2014.

  18. RILEM AAR-4. Detection of potential alkali-reactivity – 60ºC method for aggregate combinations using concrete prisms. In: Special Issue RILEM TC219-ACS, Materials & Structures, vol. 47 (in press), 2014.

  19. LNEC E 461. Betões. Metodologias para prevenir reacções expansivas internas. Laboratório Nacional de Engenharia Civil, Lisboa, 6 pp, 2007 (in Portuguese).

  20. RILEM AAR-1: Detection of potential alkali reactivity of aggregates – petrographic method. Alkali reactivity and prevention – assessment, specification and diagnosis of alkali-reactivity. In TC 191-ARP, Materials & Structures (p repared by Sims I. & Nixon P.), vol. 36, pp 472–479, 2003.

  21. St John D.A., Poole A. W. & Sims I. Concrete petrography. A handbook of investigative techniques. Arnold, London, UK: 474 pp, 1998.

  22. Shayan A. Alkali reactivity of deformed granitic rocks: a case study. Cement and Concrete Research, vol. 23, pp 1229-1236, 1993.

  23. Wenk H-R, Monteiro PJM & Shomglin K. Relationship between aggregate microstructure and mortar expansion. A case study of deformed granitic rocks from Santa Rosa mylonite zone. Journal of Materials and Science, vol. 43, pp 1278 -1285, 2008.

  24. Locati F., Marfil S.A., Baldo E. Effect of ductile deformation of quartz -bearing rocks on the alkali-silica reaction. Engineering Geology, vol. 116, pp 117-128, 2010.

  25. Alaejos P. & Lanza V. Influence of equivalent reactive quartz content on expansion due to alkali-silica reaction. Cement and Concrete Research, vol. 42, pp 99-104, 2012.

  26. Marinoni N. & Broekmans M.A.T.M. Microstructure of selected aggregate quartz by XRD, and a critical review of the crystallinity index. Cement and Concrete Research, vol. 54, pp 215-225, 2012.

  27. Götze J., Schertl H.P., Neuser R.D., Kempe U. & Hanchar J.M. Optical microcope- cathodoluminescence (OM-CL) imaging as a powerful tool to reveal internal textures of minerals, Mineralogy & Petrology, vol. 107, pp 373-392, 2013.

  28. Couto H., Lourenço A. & Borges, F. Estudo de quartzos em catodoluminescência. Revista Electrónica de Ciências da Terra, Geosciences On-line Journal, e-Terra ,http://e- terra.geopor.pt. ISSN 1645-0388, vol. 16, nº 2, 2010.

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