Issue 40

A. Kyriazopoulos, Frattura ed Integrità Strutturale, 40 (2017) 52-60; DOI: 10.3221/IGF-ESIS.40.05 59 [14] Triantis, D., Anastasiadis, C., Vallianatos, F., Kyriazis, P., Nover, G., Electric signal emissions during repeated abrupt uniaxial compressional stress steps in amphibolite from KTB drilling, Natural Hazards & Earth System Sciences, 7 (2007) 149-154. [15] Kyriazopoulos, A., Anastasiadis, C., Triantis, D., Brown, J. C, Non-destructive evaluation of cement-based materials from pressure-stimulated electrical emission - Preliminary results, Construction and Building Materials, 25 (2011) 1980-1990. [16] Triantis, D., Stavrakas, I., Kyriazopoulos, A., Hloupis, G., Agioutantis, Z., Pressure Stimulated Electrical Emissions from cement mortar used as failure predictors, International Journal of Fracture, 175 (2012) 53-61. [17] Stavrakas, I., Pasiou, E.D., Hloupis, G., Malliaros, G.-T., Triantis, D., Kourkoulis, S.K., Exploring the size effect of marble by combined use of Pressure Stimulated Currents and Acoustic Emission, in: Beskos D.E., Stavroulakis G.E. (Eds.), 10th HSTAM International Congress on Mechanics, Chania, Hellas, (2013) 185-186. [18] Li, Z., Enyuan, W., Miao, H., Laboratory Studies of Electric Current Generated during Fracture of Coal and Rock in Rock Burst Coal Mine, Journal of Mining, 2015 (2015) ID 235636. [19] Sun, M., Liu, Q., Li, Z., Wang, E. Electrical emission in mortar under low compressive loading. Cement and Concrete Research, 32 (2002) 47–50. [20] Archer, J. W., Dobbs, M. R., Aydin, A., Reeves, H. J., & Prance, R. J., Measurement and correlation of acoustic emissions and pressure stimulated voltages in rock using an electric potential sensor. International Journal of Rock Mechanics and Mining Sciences, 89 (2016) 26-33. [21] Dann, D., Demikhova, A., Fursa, T., Kuimova, M., Research of Electrical Response Communication Parameters on the Pulse Mechanical Impact with the Stress–Strain State of Concrete Under Uniaxial Compression, IOP Conf. Series: Materials Science and Engineering, 66 (2014) 012036. doi:10.1088/1757-899X/66/1/012036 [22] Colombo, S., Main, I., G., Forde, M. C., Assessing damage of Reinforced Concrete Beam using ‘‘ b -value’’ Analysis of Acoustic Emission signals. J. Mat. Civil Eng. (ASCE), 15 (2003) 280-286. [23] Vidya Sagar, R., Prasad, RV., Raghu Prasad, B.K., Rao, M.V.M.S., Microcracking and fracture process in cement mortar and concrete: a comparative study using acoustic emission technique. Experimental Mechanics, 53 (2013) 1161–1175. [24] Vidya Sagar, R., Raghu Prasad, B.K., Shantha Kumar, S., An experimental study on cracking evolution in concrete and cement mortar by the b-value analysis of acoustic emission technique, Cement and Concrete Research, 42 (2012) 1094- 1104. [25] Stergiopoulos, C., Stavrakas, I., Hloupis, G., Triantis, D., Vallianatos, F., Electrical and acoustic emissions in cement mortar beams subjected to mechanical loading up to fracture, Engineering Failure Analysis, 35 (2013) 454–461. [26] Anastasiadis, C., Stavrakas, I., Triantis, D., Vallianatos, F., Correlation of pressure stimulated currents in rocks with the damage variable, Annals of Geophysics, 50 (2007) 1-6. [27] Vallianatos, F., Triantis, D., Scaling in Pressure Stimulated Currents related with Rock Fracture, Physica A, 387 (2008) 4940-4946. [28] Triantis, D., Anastasiadis, C., Stavrakas, I., The correlation of electric charge with strain on stressed rock samples, Natural Hazards and Earth System Sciences, 8 (2006) 1243-1248. [29] Scholz, C. H., The frequency–magnitude relation of microcracking in rock and its relation to earthquakes. Bull. Seis. Soc. Am., 58 ( 1968) 399–415. [30] Aki, K., Maximum likelihood estimates of b in the formula log N = a – bm and its confidence limits. Bull. Earthquake Res. Inst., Tokyo Univ., 43 ( 1965) 237–239. [31] Main, I. G., Meredith, P. G. and Jones, C., A reinterpretation of the precursory seismic b- value anomaly from fracture mechanics. Geophys. J., 96 (1989) 131–138. [32] Shiotani, T., Yuyama S., Li, Z. W., Ohtsu, M. Application of the AE improved b-value to qualitative evaluation of fracture process in concrete materials, J. Acoust. Emission, 19 (2001) 118–132. [33] Rouchier, S., Foray, G., Godin, N., Woloszyn, M., Roux, J.-J. Damage monitoring in fibre reinforced mortar by combined digital image correlation and acoustic emission, Construction and Building Materials, 38 (2012) 371-380. [34] Kourkoulis, S.K., Ganniari-Papageorgiou, E., Mentzini, M., Dionysos marble under bending: Α contribution towards understanding the fracture of the Parthenon architraves, Engineering Geology, 115 (3-4) (2010) 246-256. [35] Kourkoulis, S.K., Prassianakis, I., Agioutantis, Z., Exadaktylos, G.E., Reliability assessment of the NDT results for the internal damage of marble specimens, International Journal of Material and Product Technology, 26(1/2) (2006) 35- 56. [36] Kourkoulis, S.K., Exadaktylos, G.E., Vardoulakis I., U-notched Dionysos-Pentelicon marble in three point bending: The effect of nonlinearity, anisotropy and microstructure, International Journal of Fracture, 98(3-4) (1999) 369-392.