(en) P. Kumar Mehta et Paulo J. M. Monteiro, Concrete: Microstructure, Properties, and Materials, Fourth Edition, McGraw-Hill Education, (ISBN978-0-07-179787-0, lire en ligne)
ascelibrary.org
(en) Mohammad Pour-Ghaz, O. Burkan Isgor et Pouria Ghods, « Quantitative Interpretation of Half-Cell Potential Measurements in Concrete Structures », Journal of Materials in Civil Engineering, vol. 21, no 9, , p. 467–475 (ISSN0899-1561, DOI10.1061/(ASCE)0899-1561(2009)21:9(467), lire en ligne, consulté le )
concrete.org
(en) Mehdi Khanzadeh Moradllo, Chunyu Qiao, Burkan Isgor et Steven Reese, « Relating Formation Factor of Concrete to Water Absorption », Materials Journal, vol. 115, no 6, , p. 887–898 (DOI10.14359/51706844, lire en ligne, consulté le )
(en) Jieying Zhang, Paulo J. M. Monteiro et H. Frank Morrison, « Noninvasive Surface Measurement of Corrosion Impedance of Reinforcing Bar in Concrete—Part 1: Experimental Results », Materials Journal, vol. 98, no 2, , p. 116–125 (ISSN0889-325X, DOI10.14359/10195, lire en ligne, consulté le )
(en) Romain Rodrigues, Stéphane Gaboreau, Julien Gance, Ioannis Ignatiadis et Stéphanie Betelu, « Reinforced concrete structures: A review of corrosion mechanisms and advances in electrical methods for corrosion monitoring », Construction and Building Materials, vol. 269, , p. 121240 (ISSN0950-0618, DOI10.1016/j.conbuildmat.2020.121240, lire en ligne, consulté le )
(en) Ueli M. Angst, Mette R. Geiker, Alexander Michel et Christoph Gehlen, « The steel–concrete interface », Materials and Structures, vol. 50, no 2, , p. 143 (ISSN1871-6873, DOI10.1617/s11527-017-1010-1, lire en ligne, consulté le )
(en) « Statistical relationship between mix properties and the interfacial transition zone around embedded rebar », Cement and Concrete Composites, vol. 60, , p. 82–91 (ISSN0958-9465, DOI10.1016/j.cemconcomp.2015.04.002, lire en ligne, consulté le )
(en) « Characteristics of the steel-concrete interface and their effect on the corrosion of steel bars in concrete », Construction and Building Materials, vol. 253, , p. 119162 (ISSN0950-0618, DOI10.1016/j.conbuildmat.2020.119162, lire en ligne, consulté le )
(en) « The mechanism controlling corrosion of steel in carbonated cementitious materials in wetting and drying exposure », Cement and Concrete Composites, vol. 113, , p. 103717 (ISSN0958-9465, DOI10.1016/j.cemconcomp.2020.103717, lire en ligne, consulté le )
(en) « Influence of Rapid Changes of Moisture Content in Concrete and Temperature on Corrosion Rate of Reinforcing Steel », Procedia Engineering, vol. 108, , p. 316–323 (ISSN1877-7058, DOI10.1016/j.proeng.2015.06.153, lire en ligne, consulté le )
Véronique Bouteiller, Jean-François Cherrier, Valérie L’Hostis et Nuria Rebolledo, « Influence of humidity and temperature on the corrosion of reinforced concrete prisms », European Journal of Environmental and Civil Engineering, vol. 16, nos 3-4, , p. 471–480 (ISSN1964-8189, DOI10.1080/19648189.2012.668004, lire en ligne, consulté le )
(en) « Influence of temperature and relative humidity variations on non-uniform corrosion of reinforced concrete », Structures, vol. 19, , p. 296–308 (ISSN2352-0124, DOI10.1016/j.istruc.2019.01.016, lire en ligne, consulté le )
(en) Stefanie von Greve-Dierfeld, Barbara Lothenbach, Anya Vollpracht et Bei Wu, « Understanding the carbonation of concrete with supplementary cementitious materials: a critical review by RILEM TC 281-CCC », Materials and Structures, vol. 53, no 6, , p. 136 (ISSN1871-6873, DOI10.1617/s11527-020-01558-w, lire en ligne, consulté le )
(en) « Influence of steel–concrete interface condition on galvanic corrosion currents in carbonated concrete », Corrosion Science, vol. 52, no 9, , p. 2878–2890 (ISSN0010-938X, DOI10.1016/j.corsci.2010.04.037, lire en ligne, consulté le )
(en) M. G. Sohail, S. Laurens, F. Deby et J. P. Balayssac, « Significance of macrocell corrosion of reinforcing steel in partially carbonated concrete: numerical and experimental investigation », Materials and Structures, vol. 48, no 1, , p. 217–233 (ISSN1871-6873, DOI10.1617/s11527-013-0178-2, lire en ligne, consulté le )
(en) « Macrocell and microcell corrosion of steel in ordinary Portland cement and high performance concretes », Cement and Concrete Research, vol. 36, no 11, , p. 2098–2102 (ISSN0008-8846, DOI10.1016/j.cemconres.2006.07.005, lire en ligne, consulté le )
(en) « Macrocell corrosion in carbonated Portland and Portland-fly ash concrete - Contribution and mechanism », Cement and Concrete Research, vol. 116, , p. 273–283 (ISSN0008-8846, DOI10.1016/j.cemconres.2018.12.005, lire en ligne, consulté le )
(en) Matteo Stefanoni, Ueli M. Angst et Bernhard Elsener, « Electrochemistry and capillary condensation theory reveal the mechanism of corrosion in dense porous media », Scientific Reports, vol. 8, no 1, , p. 7407 (ISSN2045-2322, DOI10.1038/s41598-018-25794-x, lire en ligne, consulté le )
(en) Matteo Stefanoni, Ueli M. Angst et Bernhard Elsener, « Kinetics of electrochemical dissolution of metals in porous media », Nature Materials, vol. 18, no 9, , p. 942–947 (ISSN1476-4660, DOI10.1038/s41563-019-0439-8, lire en ligne, consulté le )
(en) « Thermodynamic modeling of the essential physicochemical interactions between the pore solution and the cement hydrates in chloride-contaminated cement-based materials », Journal of Colloid and Interface Science, vol. 531, , p. 56–63 (ISSN0021-9797, DOI10.1016/j.jcis.2018.07.005, lire en ligne, consulté le )
(en) J. Warkus et M. Raupach, « Modelling of reinforcement corrosion – geometrical effects on macrocell corrosion », Materials and Corrosion, vol. 61, no 6, , p. 494–504 (ISSN1521-4176, DOI10.1002/maco.200905437, lire en ligne, consulté le )
(en) « Identification of corrosion products and 3D distribution in reinforced concrete using X-ray micro computed tomography », Construction and Building Materials, vol. 207, , p. 304–315 (ISSN0950-0618, DOI10.1016/j.conbuildmat.2019.02.133, lire en ligne, consulté le )
(en) « Composition and expansion coefficient of rust based on X-ray diffraction and thermal analysis », Corrosion Science, vol. 53, no 5, , p. 1646–1658 (ISSN0010-938X, DOI10.1016/j.corsci.2011.01.007, lire en ligne, consulté le )
(en) « “Green rust”, iron solubility and the role of chloride in the corrosion of steel at high pH », Cement and Concrete Research, vol. 23, no 4, , p. 785–791 (ISSN0008-8846, DOI10.1016/0008-8846(93)90032-5, lire en ligne, consulté le )
(en) V. L'Hostis, E. Amblard, W. Guillot et C. Paris, « Characterisation of the steel concrete interface submitted to chloride-induced-corrosion », Materials and Corrosion, vol. 64, no 3, , p. 185–194 (ISSN1521-4176, DOI10.1002/maco.201106488, lire en ligne, consulté le )
(en) « Distribution of millscale on corroded steel bars and penetration of steel corrosion products in concrete », Corrosion Science, vol. 66, , p. 160–168 (ISSN0010-938X, DOI10.1016/j.corsci.2012.09.014, lire en ligne, consulté le )
(en) « Reinforcement corrosion-induced cover cracking and its time prediction for reinforced concrete structures », Corrosion Science, vol. 53, no 4, , p. 1337–1347 (ISSN0010-938X, DOI10.1016/j.corsci.2010.12.026, lire en ligne, consulté le )
Carolina Boschmann Käthler, Ueli M. Angst, Gino Ebell et Bernhard Elsener, « Chloride-induced reinforcement corrosion in cracked concrete: the influence of time of wetness on corrosion propagation », Corrosion Engineering, Science and Technology, vol. 56, no 1, , p. 1–10 (ISSN1478-422X, DOI10.1080/1478422X.2020.1789371, lire en ligne, consulté le )
(en) B. Elsener, C. Andrade, J. Gulikers et R. Polder, « Half-cell potential measurements—Potential mapping on reinforced concrete structures », Materials and Structures, vol. 36, no 7, , p. 461–471 (ISSN1871-6873, DOI10.1007/BF02481526, lire en ligne, consulté le )
(en) Mohammad Pour-Ghaz, O. Burkan Isgor et Pouria Ghods, « Quantitative Interpretation of Half-Cell Potential Measurements in Concrete Structures », Journal of Materials in Civil Engineering, vol. 21, no 9, , p. 467–475 (ISSN0899-1561, DOI10.1061/(ASCE)0899-1561(2009)21:9(467), lire en ligne, consulté le )
(en) K. Reichling, M. Raupach, J. Broomfield et J. Gulikers, « Full surface inspection methods regarding reinforcement corrosion of concrete structures », Materials and Corrosion, vol. 64, no 2, , p. 116–127 (ISSN1521-4176, DOI10.1002/maco.201206625, lire en ligne, consulté le )
(en) « Probabilistic evaluation method for corrosion risk of steel reinforcement based on concrete resistivity », Construction and Building Materials, vol. 138, , p. 101–113 (ISSN0950-0618, DOI10.1016/j.conbuildmat.2017.01.100, lire en ligne, consulté le )
(en) Ueli Angst, Fabrizio Moro, Mette Geiker et Sylvia Kessler, « Corrosion of steel in carbonated concrete: mechanisms, practical experience, and research priorities – a critical review by RILEM TC 281-CCC », RILEM Technical Letters, vol. 5, , p. 85–100 (ISSN2518-0231, DOI10.21809/rilemtechlett.2020.127, lire en ligne, consulté le )
(en) Karla Hornbostel, Bernhard Elsener, Ueli M. Angst et Claus K. Larsen, « Limitations of the use of concrete bulk resistivity as an indicator for the rate of chloride-induced macro-cell corrosion », Structural Concrete, vol. 18, no 2, , p. 326–333 (ISSN1751-7648, DOI10.1002/suco.201500141, lire en ligne, consulté le )
(en) « Accounting for steel rebar effect on resistivity profiles in view of reinforced concrete structure survey », Construction and Building Materials, vol. 223, , p. 898–909 (ISSN0950-0618, DOI10.1016/j.conbuildmat.2019.07.208, lire en ligne, consulté le )
(en) « On the limitations of predicting the ohmic resistance in a macro-cell in mortar from bulk resistivity measurements », Cement and Concrete Research, vol. 76, , p. 147–158 (ISSN0008-8846, DOI10.1016/j.cemconres.2015.05.023, lire en ligne, consulté le )
(en) Mehdi Khanzadeh Moradllo, Chunyu Qiao, Burkan Isgor et Steven Reese, « Relating Formation Factor of Concrete to Water Absorption », Materials Journal, vol. 115, no 6, , p. 887–898 (DOI10.14359/51706844, lire en ligne, consulté le )
(en) « Electrical tomography for characterizing transport properties in cement-based materials: A review », Construction and Building Materials, vol. 244, , p. 118299 (ISSN0950-0618, DOI10.1016/j.conbuildmat.2020.118299, lire en ligne, consulté le )
(en) C. Andrade et C. Alonso, « Test methods for on-site corrosion rate measurement of steel reinforcement in concrete by means of the polarization resistance method », Materials and Structures, vol. 37, no 9, , p. 623–643 (ISSN1871-6873, DOI10.1007/BF02483292, lire en ligne, consulté le )
(en) E. V. Pereira, M. M. Salta et I. T. E. Fonseca, « On the measurement of the polarisation resistance of reinforcing steel with embedded sensors: A comparative study », Materials and Corrosion, vol. 66, no 10, , p. 1029–1038 (ISSN1521-4176, DOI10.1002/maco.201407910, lire en ligne, consulté le )
(en) Andrew Fahim, Pouria Ghods, O. Burkan Isgor et Michael D. A. Thomas, « A critical examination of corrosion rate measurement techniques applied to reinforcing steel in concrete », Materials and Corrosion, vol. 69, no 12, , p. 1784–1799 (ISSN1521-4176, DOI10.1002/maco.201810263, lire en ligne, consulté le )
(en) U. Angst et M. Büchler, « On the applicability of the Stern–Geary relationship to determine instantaneous corrosion rates in macro-cell corrosion », Materials and Corrosion, vol. 66, no 10, , p. 1017–1028 (ISSN1521-4176, DOI10.1002/maco.201407997, lire en ligne, consulté le )
(en) Ueli Angst et Markus Büchler, « A new perspective on measuring the corrosion rate of localized corrosion », Materials and Corrosion, vol. 71, no 5, , p. 808–823 (ISSN1521-4176, DOI10.1002/maco.201911467, lire en ligne, consulté le )
(en) Jieying Zhang, Paulo J. M. Monteiro et H. Frank Morrison, « Noninvasive Surface Measurement of Corrosion Impedance of Reinforcing Bar in Concrete—Part 1: Experimental Results », Materials Journal, vol. 98, no 2, , p. 116–125 (ISSN0889-325X, DOI10.14359/10195, lire en ligne, consulté le )
(en) « Indirect Impedance for Corrosion Detection of External Post-tensioned Tendons: 2. Multiple Steel Strands », Corrosion Science, vol. 164, , p. 108330 (ISSN0010-938X, DOI10.1016/j.corsci.2019.108330, lire en ligne, consulté le )
(en) Romain Rodrigues, Stéphane Gaboreau, Julien Gance, Ioannis Ignatiadis et Stéphanie Betelu, « Indirect Galvanostatic Pulse in Wenner Configuration: Numerical Insights into Its Physical Aspect and Its Ability to Locate Highly Corroding Areas in Macrocell Corrosion of Steel in Concrete », Corrosion and Materials Degradation, vol. 1, no 3, , p. 373–407 (DOI10.3390/cmd1030018, lire en ligne, consulté le )
Ueli M. Angst, « A Critical Review of the Science and Engineering of Cathodic Protection of Steel in Soil and Concrete », Corrosion, vol. 75, no 12, , p. 1420–1433 (ISSN0010-9312, DOI10.5006/3355, lire en ligne, consulté le )
(en) Chava Venkatesh, Syed Khaja Mohiddin et N. Ruben, « Corrosion Inhibitors Behaviour on Reinforced Concrete—A Review », Sustainable Construction and Building Materials, Springer, lecture Notes in Civil Engineering, , p. 127–134 (ISBN978-981-13-3317-0, DOI10.1007/978-981-13-3317-0_11, lire en ligne, consulté le )
(en) Ueli M. Angst, Mette R. Geiker, Alexander Michel et Christoph Gehlen, « The steel–concrete interface », Materials and Structures, vol. 50, no 2, , p. 143 (ISSN1871-6873, DOI10.1617/s11527-017-1010-1, lire en ligne, consulté le )
Véronique Bouteiller, Jean-François Cherrier, Valérie L’Hostis et Nuria Rebolledo, « Influence of humidity and temperature on the corrosion of reinforced concrete prisms », European Journal of Environmental and Civil Engineering, vol. 16, nos 3-4, , p. 471–480 (ISSN1964-8189, DOI10.1080/19648189.2012.668004, lire en ligne, consulté le )
(en) Stefanie von Greve-Dierfeld, Barbara Lothenbach, Anya Vollpracht et Bei Wu, « Understanding the carbonation of concrete with supplementary cementitious materials: a critical review by RILEM TC 281-CCC », Materials and Structures, vol. 53, no 6, , p. 136 (ISSN1871-6873, DOI10.1617/s11527-020-01558-w, lire en ligne, consulté le )
(en) M. G. Sohail, S. Laurens, F. Deby et J. P. Balayssac, « Significance of macrocell corrosion of reinforcing steel in partially carbonated concrete: numerical and experimental investigation », Materials and Structures, vol. 48, no 1, , p. 217–233 (ISSN1871-6873, DOI10.1617/s11527-013-0178-2, lire en ligne, consulté le )
Carolina Boschmann Käthler, Ueli M. Angst, Gino Ebell et Bernhard Elsener, « Chloride-induced reinforcement corrosion in cracked concrete: the influence of time of wetness on corrosion propagation », Corrosion Engineering, Science and Technology, vol. 56, no 1, , p. 1–10 (ISSN1478-422X, DOI10.1080/1478422X.2020.1789371, lire en ligne, consulté le )
(en) B. Elsener, C. Andrade, J. Gulikers et R. Polder, « Half-cell potential measurements—Potential mapping on reinforced concrete structures », Materials and Structures, vol. 36, no 7, , p. 461–471 (ISSN1871-6873, DOI10.1007/BF02481526, lire en ligne, consulté le )
(en) C. Andrade et C. Alonso, « Test methods for on-site corrosion rate measurement of steel reinforcement in concrete by means of the polarization resistance method », Materials and Structures, vol. 37, no 9, , p. 623–643 (ISSN1871-6873, DOI10.1007/BF02483292, lire en ligne, consulté le )
Ueli M. Angst, « A Critical Review of the Science and Engineering of Cathodic Protection of Steel in Soil and Concrete », Corrosion, vol. 75, no 12, , p. 1420–1433 (ISSN0010-9312, DOI10.5006/3355, lire en ligne, consulté le )
(en) Romain Rodrigues, Stéphane Gaboreau, Julien Gance, Ioannis Ignatiadis et Stéphanie Betelu, « Reinforced concrete structures: A review of corrosion mechanisms and advances in electrical methods for corrosion monitoring », Construction and Building Materials, vol. 269, , p. 121240 (ISSN0950-0618, DOI10.1016/j.conbuildmat.2020.121240, lire en ligne, consulté le )
(en) Ueli M. Angst, Mette R. Geiker, Alexander Michel et Christoph Gehlen, « The steel–concrete interface », Materials and Structures, vol. 50, no 2, , p. 143 (ISSN1871-6873, DOI10.1617/s11527-017-1010-1, lire en ligne, consulté le )
(en) « Statistical relationship between mix properties and the interfacial transition zone around embedded rebar », Cement and Concrete Composites, vol. 60, , p. 82–91 (ISSN0958-9465, DOI10.1016/j.cemconcomp.2015.04.002, lire en ligne, consulté le )
(en) « Characteristics of the steel-concrete interface and their effect on the corrosion of steel bars in concrete », Construction and Building Materials, vol. 253, , p. 119162 (ISSN0950-0618, DOI10.1016/j.conbuildmat.2020.119162, lire en ligne, consulté le )
(en) « The mechanism controlling corrosion of steel in carbonated cementitious materials in wetting and drying exposure », Cement and Concrete Composites, vol. 113, , p. 103717 (ISSN0958-9465, DOI10.1016/j.cemconcomp.2020.103717, lire en ligne, consulté le )
(en) « Influence of Rapid Changes of Moisture Content in Concrete and Temperature on Corrosion Rate of Reinforcing Steel », Procedia Engineering, vol. 108, , p. 316–323 (ISSN1877-7058, DOI10.1016/j.proeng.2015.06.153, lire en ligne, consulté le )
Véronique Bouteiller, Jean-François Cherrier, Valérie L’Hostis et Nuria Rebolledo, « Influence of humidity and temperature on the corrosion of reinforced concrete prisms », European Journal of Environmental and Civil Engineering, vol. 16, nos 3-4, , p. 471–480 (ISSN1964-8189, DOI10.1080/19648189.2012.668004, lire en ligne, consulté le )
(en) « Influence of temperature and relative humidity variations on non-uniform corrosion of reinforced concrete », Structures, vol. 19, , p. 296–308 (ISSN2352-0124, DOI10.1016/j.istruc.2019.01.016, lire en ligne, consulté le )
(en) Stefanie von Greve-Dierfeld, Barbara Lothenbach, Anya Vollpracht et Bei Wu, « Understanding the carbonation of concrete with supplementary cementitious materials: a critical review by RILEM TC 281-CCC », Materials and Structures, vol. 53, no 6, , p. 136 (ISSN1871-6873, DOI10.1617/s11527-020-01558-w, lire en ligne, consulté le )
(en) « Influence of steel–concrete interface condition on galvanic corrosion currents in carbonated concrete », Corrosion Science, vol. 52, no 9, , p. 2878–2890 (ISSN0010-938X, DOI10.1016/j.corsci.2010.04.037, lire en ligne, consulté le )
(en) M. G. Sohail, S. Laurens, F. Deby et J. P. Balayssac, « Significance of macrocell corrosion of reinforcing steel in partially carbonated concrete: numerical and experimental investigation », Materials and Structures, vol. 48, no 1, , p. 217–233 (ISSN1871-6873, DOI10.1617/s11527-013-0178-2, lire en ligne, consulté le )
(en) « Macrocell and microcell corrosion of steel in ordinary Portland cement and high performance concretes », Cement and Concrete Research, vol. 36, no 11, , p. 2098–2102 (ISSN0008-8846, DOI10.1016/j.cemconres.2006.07.005, lire en ligne, consulté le )
(en) « Macrocell corrosion in carbonated Portland and Portland-fly ash concrete - Contribution and mechanism », Cement and Concrete Research, vol. 116, , p. 273–283 (ISSN0008-8846, DOI10.1016/j.cemconres.2018.12.005, lire en ligne, consulté le )
(en) Matteo Stefanoni, Ueli M. Angst et Bernhard Elsener, « Electrochemistry and capillary condensation theory reveal the mechanism of corrosion in dense porous media », Scientific Reports, vol. 8, no 1, , p. 7407 (ISSN2045-2322, DOI10.1038/s41598-018-25794-x, lire en ligne, consulté le )
(en) Matteo Stefanoni, Ueli M. Angst et Bernhard Elsener, « Kinetics of electrochemical dissolution of metals in porous media », Nature Materials, vol. 18, no 9, , p. 942–947 (ISSN1476-4660, DOI10.1038/s41563-019-0439-8, lire en ligne, consulté le )
(en) « Thermodynamic modeling of the essential physicochemical interactions between the pore solution and the cement hydrates in chloride-contaminated cement-based materials », Journal of Colloid and Interface Science, vol. 531, , p. 56–63 (ISSN0021-9797, DOI10.1016/j.jcis.2018.07.005, lire en ligne, consulté le )
(en) J. Warkus et M. Raupach, « Modelling of reinforcement corrosion – geometrical effects on macrocell corrosion », Materials and Corrosion, vol. 61, no 6, , p. 494–504 (ISSN1521-4176, DOI10.1002/maco.200905437, lire en ligne, consulté le )
(en) « Identification of corrosion products and 3D distribution in reinforced concrete using X-ray micro computed tomography », Construction and Building Materials, vol. 207, , p. 304–315 (ISSN0950-0618, DOI10.1016/j.conbuildmat.2019.02.133, lire en ligne, consulté le )
(en) « Composition and expansion coefficient of rust based on X-ray diffraction and thermal analysis », Corrosion Science, vol. 53, no 5, , p. 1646–1658 (ISSN0010-938X, DOI10.1016/j.corsci.2011.01.007, lire en ligne, consulté le )
(en) « “Green rust”, iron solubility and the role of chloride in the corrosion of steel at high pH », Cement and Concrete Research, vol. 23, no 4, , p. 785–791 (ISSN0008-8846, DOI10.1016/0008-8846(93)90032-5, lire en ligne, consulté le )
(en) V. L'Hostis, E. Amblard, W. Guillot et C. Paris, « Characterisation of the steel concrete interface submitted to chloride-induced-corrosion », Materials and Corrosion, vol. 64, no 3, , p. 185–194 (ISSN1521-4176, DOI10.1002/maco.201106488, lire en ligne, consulté le )
(en) « Distribution of millscale on corroded steel bars and penetration of steel corrosion products in concrete », Corrosion Science, vol. 66, , p. 160–168 (ISSN0010-938X, DOI10.1016/j.corsci.2012.09.014, lire en ligne, consulté le )
(en) « Reinforcement corrosion-induced cover cracking and its time prediction for reinforced concrete structures », Corrosion Science, vol. 53, no 4, , p. 1337–1347 (ISSN0010-938X, DOI10.1016/j.corsci.2010.12.026, lire en ligne, consulté le )
Carolina Boschmann Käthler, Ueli M. Angst, Gino Ebell et Bernhard Elsener, « Chloride-induced reinforcement corrosion in cracked concrete: the influence of time of wetness on corrosion propagation », Corrosion Engineering, Science and Technology, vol. 56, no 1, , p. 1–10 (ISSN1478-422X, DOI10.1080/1478422X.2020.1789371, lire en ligne, consulté le )
(en) B. Elsener, C. Andrade, J. Gulikers et R. Polder, « Half-cell potential measurements—Potential mapping on reinforced concrete structures », Materials and Structures, vol. 36, no 7, , p. 461–471 (ISSN1871-6873, DOI10.1007/BF02481526, lire en ligne, consulté le )
(en) Mohammad Pour-Ghaz, O. Burkan Isgor et Pouria Ghods, « Quantitative Interpretation of Half-Cell Potential Measurements in Concrete Structures », Journal of Materials in Civil Engineering, vol. 21, no 9, , p. 467–475 (ISSN0899-1561, DOI10.1061/(ASCE)0899-1561(2009)21:9(467), lire en ligne, consulté le )
(en) K. Reichling, M. Raupach, J. Broomfield et J. Gulikers, « Full surface inspection methods regarding reinforcement corrosion of concrete structures », Materials and Corrosion, vol. 64, no 2, , p. 116–127 (ISSN1521-4176, DOI10.1002/maco.201206625, lire en ligne, consulté le )
(en) « Probabilistic evaluation method for corrosion risk of steel reinforcement based on concrete resistivity », Construction and Building Materials, vol. 138, , p. 101–113 (ISSN0950-0618, DOI10.1016/j.conbuildmat.2017.01.100, lire en ligne, consulté le )
(en) Ueli Angst, Fabrizio Moro, Mette Geiker et Sylvia Kessler, « Corrosion of steel in carbonated concrete: mechanisms, practical experience, and research priorities – a critical review by RILEM TC 281-CCC », RILEM Technical Letters, vol. 5, , p. 85–100 (ISSN2518-0231, DOI10.21809/rilemtechlett.2020.127, lire en ligne, consulté le )
(en) Karla Hornbostel, Bernhard Elsener, Ueli M. Angst et Claus K. Larsen, « Limitations of the use of concrete bulk resistivity as an indicator for the rate of chloride-induced macro-cell corrosion », Structural Concrete, vol. 18, no 2, , p. 326–333 (ISSN1751-7648, DOI10.1002/suco.201500141, lire en ligne, consulté le )
(en) « Accounting for steel rebar effect on resistivity profiles in view of reinforced concrete structure survey », Construction and Building Materials, vol. 223, , p. 898–909 (ISSN0950-0618, DOI10.1016/j.conbuildmat.2019.07.208, lire en ligne, consulté le )
(en) « On the limitations of predicting the ohmic resistance in a macro-cell in mortar from bulk resistivity measurements », Cement and Concrete Research, vol. 76, , p. 147–158 (ISSN0008-8846, DOI10.1016/j.cemconres.2015.05.023, lire en ligne, consulté le )
(en) « Electrical tomography for characterizing transport properties in cement-based materials: A review », Construction and Building Materials, vol. 244, , p. 118299 (ISSN0950-0618, DOI10.1016/j.conbuildmat.2020.118299, lire en ligne, consulté le )
(en) C. Andrade et C. Alonso, « Test methods for on-site corrosion rate measurement of steel reinforcement in concrete by means of the polarization resistance method », Materials and Structures, vol. 37, no 9, , p. 623–643 (ISSN1871-6873, DOI10.1007/BF02483292, lire en ligne, consulté le )
(en) E. V. Pereira, M. M. Salta et I. T. E. Fonseca, « On the measurement of the polarisation resistance of reinforcing steel with embedded sensors: A comparative study », Materials and Corrosion, vol. 66, no 10, , p. 1029–1038 (ISSN1521-4176, DOI10.1002/maco.201407910, lire en ligne, consulté le )
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(en) « Indirect Impedance for Corrosion Detection of External Post-tensioned Tendons: 2. Multiple Steel Strands », Corrosion Science, vol. 164, , p. 108330 (ISSN0010-938X, DOI10.1016/j.corsci.2019.108330, lire en ligne, consulté le )
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mdpi.com
(en) Romain Rodrigues, Stéphane Gaboreau, Julien Gance, Ioannis Ignatiadis et Stéphanie Betelu, « Indirect Galvanostatic Pulse in Wenner Configuration: Numerical Insights into Its Physical Aspect and Its Ability to Locate Highly Corroding Areas in Macrocell Corrosion of Steel in Concrete », Corrosion and Materials Degradation, vol. 1, no 3, , p. 373–407 (DOI10.3390/cmd1030018, lire en ligne, consulté le )
nature.com
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rilem.net
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(en) Ueli Angst, Fabrizio Moro, Mette Geiker et Sylvia Kessler, « Corrosion of steel in carbonated concrete: mechanisms, practical experience, and research priorities – a critical review by RILEM TC 281-CCC », RILEM Technical Letters, vol. 5, , p. 85–100 (ISSN2518-0231, DOI10.21809/rilemtechlett.2020.127, lire en ligne, consulté le )
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(en) « The mechanism controlling corrosion of steel in carbonated cementitious materials in wetting and drying exposure », Cement and Concrete Composites, vol. 113, , p. 103717 (ISSN0958-9465, DOI10.1016/j.cemconcomp.2020.103717, lire en ligne, consulté le )
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(en) Andrew Fahim, Pouria Ghods, O. Burkan Isgor et Michael D. A. Thomas, « A critical examination of corrosion rate measurement techniques applied to reinforcing steel in concrete », Materials and Corrosion, vol. 69, no 12, , p. 1784–1799 (ISSN1521-4176, DOI10.1002/maco.201810263, lire en ligne, consulté le )
(en) U. Angst et M. Büchler, « On the applicability of the Stern–Geary relationship to determine instantaneous corrosion rates in macro-cell corrosion », Materials and Corrosion, vol. 66, no 10, , p. 1017–1028 (ISSN1521-4176, DOI10.1002/maco.201407997, lire en ligne, consulté le )
(en) Ueli Angst et Markus Büchler, « A new perspective on measuring the corrosion rate of localized corrosion », Materials and Corrosion, vol. 71, no 5, , p. 808–823 (ISSN1521-4176, DOI10.1002/maco.201911467, lire en ligne, consulté le )