Document Type : Original Article
Akin, M., & Özsan, A. (2011). Evaluation of the long-term durability of yellow
travertine using accelerated weathering tests. Bulletin of Engineering Geology and
the Environment, 70(1), 101-114.
Akram, M., & Bakar, M. A. (2016). Correlation between uniaxial compressive
strength and point load index for salt-range rocks. Pakistan Journal of Engineering
and Applied Sciences.
ASTM, D. (2002). 5731, Standard test method for determination of the point load
strength index of rock. ASTM International, West Conshohocken, PA.
ASTM, D. (2008). 3967, Standard Test Method for Splitting Tensile Strength of
Intact Rock Core Specimens. ASTM International, West Conshohocken, PA.
travertine using accelerated weathering tests. Bulletin of Engineering Geology and
the Environment, 70(1), 101-114.
Akram, M., & Bakar, M. A. (2016). Correlation between uniaxial compressive
strength and point load index for salt-range rocks. Pakistan Journal of Engineering
and Applied Sciences.
ASTM, D. (2002). 5731, Standard test method for determination of the point load
strength index of rock. ASTM International, West Conshohocken, PA.
ASTM, D. (2008). 3967, Standard Test Method for Splitting Tensile Strength of
Intact Rock Core Specimens. ASTM International, West Conshohocken, PA.
BELL, R. G. (1992). The durability of sandstone as building stone, especially in
urban environments. Bulletin of the Association of Engineering Geologists, 29(1),
49-60.
Bieniawski, Z. T., & Bernede, M. J. (1979, April). Suggested methods for
determining the uniaxial compressive strength and deformability of rock materials:
Part 1. Suggested method for determination of the uniaxial compressive strength of
rock materials. In International Journal of Rock Mechanics and Mining Sciences &
Geomechanics Abstracts (Vol. 16, No. 2, p. 137). Pergamon.
Cargill, J. S., & Shakoor, A. (1990, December). Evaluation of empirical methods
for measuring the uniaxial compressive strength of rock. In International Journal
of Rock Mechanics and Mining Sciences & Geomechanics Abstracts (Vol. 27, No.
6, pp. 495-503). Pergamon.
Chen, T. C., Yeung, M. R., & Mori, N. (2004). Effect of water saturation on
deterioration of welded tuff due to freeze-thaw action. Cold Regions Science and
Technology, 38(2-3), 127-136.
Erguler, Z. A., & Shakoor, A. (2009). Relative contribution of various climatic
processes in disintegration of clay-bearing rocks. Engineering Geology, 108(1-2),
36-42.
Grossi, C. M., Brimblecombe, P., & Harris, I. (2007). Predicting long term
freeze–thaw risks on Europe built heritage and archaeological sites in a changing
climate. Science of the Total Environment, 377(2-3), 273-281.
Hale, P. A., & Shakoor, A. (2003). A laboratory investigation of the effects of
cyclic heating and cooling, wetting and drying, and freezing and thawing on the
compressive strength of selected sandstones. Environmental & Engineering
Geoscience, 9(2), 117-130.
urban environments. Bulletin of the Association of Engineering Geologists, 29(1),
49-60.
Bieniawski, Z. T., & Bernede, M. J. (1979, April). Suggested methods for
determining the uniaxial compressive strength and deformability of rock materials:
Part 1. Suggested method for determination of the uniaxial compressive strength of
rock materials. In International Journal of Rock Mechanics and Mining Sciences &
Geomechanics Abstracts (Vol. 16, No. 2, p. 137). Pergamon.
Cargill, J. S., & Shakoor, A. (1990, December). Evaluation of empirical methods
for measuring the uniaxial compressive strength of rock. In International Journal
of Rock Mechanics and Mining Sciences & Geomechanics Abstracts (Vol. 27, No.
6, pp. 495-503). Pergamon.
Chen, T. C., Yeung, M. R., & Mori, N. (2004). Effect of water saturation on
deterioration of welded tuff due to freeze-thaw action. Cold Regions Science and
Technology, 38(2-3), 127-136.
Erguler, Z. A., & Shakoor, A. (2009). Relative contribution of various climatic
processes in disintegration of clay-bearing rocks. Engineering Geology, 108(1-2),
36-42.
Grossi, C. M., Brimblecombe, P., & Harris, I. (2007). Predicting long term
freeze–thaw risks on Europe built heritage and archaeological sites in a changing
climate. Science of the Total Environment, 377(2-3), 273-281.
Hale, P. A., & Shakoor, A. (2003). A laboratory investigation of the effects of
cyclic heating and cooling, wetting and drying, and freezing and thawing on the
compressive strength of selected sandstones. Environmental & Engineering
Geoscience, 9(2), 117-130.
Hyam, S. D., Younis, M. A., & Kamal, A. R. (2017). Prediction of Uniaxial
Compressive Strength and Modulus of Elasticity for Some Sedimentary Rocks in
Kurdistan Region-Iraq using Schmidt Hammer. Journal of Zankoy Sulaimani, 19 –
3-4, pp. 57-72.
Ingham, J. P. (2005). Predicting the frost resistance of building stone. Quarterly
Journal of Engineering Geology and Hydrogeology, 38(4), 387-399.
Jamshidi, A., Nikudel, M. R., & Khamehchiyan, M. (2013). Predicting the long-
term durability of building stones against freeze–thaw using a decay function
model. Cold Regions Science and Technology, 92, 29-36.
Khanlari, G., Sahamieh, R. Z., & Abdilor, Y. (2015). The effect of freeze–thaw
cycles on physical and mechanical properties of Upper Red Formation sandstones,
central part of Iran. Arabian Journal of Geosciences, 8(8), 5991-6001.
Kolay, E. (2016). Modeling the effect of freezing and thawing for sedimentary
rocks. Environmental Earth Sciences, 75(3), 210.
Lienhart, D. A. (1988). The geographic distribution of intensity and frequency of
freeze-thaw cycles. Bulletin of the Association of Engineering Geologists, 25(4),
465-469.
Lienhart, D. A., & Stransky, T. E. (1981). Evaluation of potential sources of riprap
and armor stone—methods and considerations. Bulletin of the Association of
Engineering Geologists, 18(3), 323-332.
Mutlutürk, M., Altindag, R., & Türk, G. (2004). A decay function model for the
integrity loss of rock when subjected to recurrent cycles of freezing–thawing and
heating–cooling. International journal of rock mechanics and mining
sciences, 41(2), 237-244.
Compressive Strength and Modulus of Elasticity for Some Sedimentary Rocks in
Kurdistan Region-Iraq using Schmidt Hammer. Journal of Zankoy Sulaimani, 19 –
3-4, pp. 57-72.
Ingham, J. P. (2005). Predicting the frost resistance of building stone. Quarterly
Journal of Engineering Geology and Hydrogeology, 38(4), 387-399.
Jamshidi, A., Nikudel, M. R., & Khamehchiyan, M. (2013). Predicting the long-
term durability of building stones against freeze–thaw using a decay function
model. Cold Regions Science and Technology, 92, 29-36.
Khanlari, G., Sahamieh, R. Z., & Abdilor, Y. (2015). The effect of freeze–thaw
cycles on physical and mechanical properties of Upper Red Formation sandstones,
central part of Iran. Arabian Journal of Geosciences, 8(8), 5991-6001.
Kolay, E. (2016). Modeling the effect of freezing and thawing for sedimentary
rocks. Environmental Earth Sciences, 75(3), 210.
Lienhart, D. A. (1988). The geographic distribution of intensity and frequency of
freeze-thaw cycles. Bulletin of the Association of Engineering Geologists, 25(4),
465-469.
Lienhart, D. A., & Stransky, T. E. (1981). Evaluation of potential sources of riprap
and armor stone—methods and considerations. Bulletin of the Association of
Engineering Geologists, 18(3), 323-332.
Mutlutürk, M., Altindag, R., & Türk, G. (2004). A decay function model for the
integrity loss of rock when subjected to recurrent cycles of freezing–thawing and
heating–cooling. International journal of rock mechanics and mining
sciences, 41(2), 237-244.
Nazir, R., Momeni, E., Armaghani, D. J., & Amin, M. M. (2013). Correlation
between unconfined compressive strength and indirect tensile strength of limestone
rock samples. Electr J Geotech Eng, 18, 1737-1746.
Nicholson, D. T. (2001). Pore properties as indicators of breakdown mechanisms
in experimentally weathered limestones. Earth surface processes and
landforms, 26(8), 819-838.
Nuri, T. M., Awad, M. A., & Msbah, A. M. A. (2011). Effect of Freezing-Thawing
Cycles on the Physical and Mechanical Properties of Some Sedimentary Rocks
Located Near Mosul City. Engineering and Technology Journal, 29(16), 3388-
3404.
Pettijohn, F. J., Potter, P. E., & Siever, R. (2012). Sand and sandstone. Springer
Science & Business Media.
Ruedrich, J., & Siegesmund, S. (2007). Salt and ice crystallisation in porous
sandstones. Environmental Geology, 52(2), 225-249.
SHAKOOR, A., & BONELLI, R. E. (1991). Relationship between petrographic
characteristics, engineering index properties, and mechanical properties of selected
sandstones. Bulletin of the Association of Engineering Geologists, 28(1), 55-71.
Sharma, P. K., & Singh, T. N. (2008). A correlation between P-wave velocity,
impact strength index, slake durability index and uniaxial compressive
strength. Bulletin of Engineering Geology and the Environment, 67(1), 17-22.
Tan, X., Chen, W., Yang, J., & Cao, J. (2011). Laboratory investigations on the
mechanical properties degradation of granite under freeze–thaw cycles. Cold
Regions Science and Technology, 68(3), 130-138.
Vasconcelos, G., Lourenço, P. B., Alves, C. A., & Pamplona, J. (2007). Prediction
of the mechanical properties of granites by ultrasonic pulse velocity and Schmidt
hammer hardness.
between unconfined compressive strength and indirect tensile strength of limestone
rock samples. Electr J Geotech Eng, 18, 1737-1746.
Nicholson, D. T. (2001). Pore properties as indicators of breakdown mechanisms
in experimentally weathered limestones. Earth surface processes and
landforms, 26(8), 819-838.
Nuri, T. M., Awad, M. A., & Msbah, A. M. A. (2011). Effect of Freezing-Thawing
Cycles on the Physical and Mechanical Properties of Some Sedimentary Rocks
Located Near Mosul City. Engineering and Technology Journal, 29(16), 3388-
3404.
Pettijohn, F. J., Potter, P. E., & Siever, R. (2012). Sand and sandstone. Springer
Science & Business Media.
Ruedrich, J., & Siegesmund, S. (2007). Salt and ice crystallisation in porous
sandstones. Environmental Geology, 52(2), 225-249.
SHAKOOR, A., & BONELLI, R. E. (1991). Relationship between petrographic
characteristics, engineering index properties, and mechanical properties of selected
sandstones. Bulletin of the Association of Engineering Geologists, 28(1), 55-71.
Sharma, P. K., & Singh, T. N. (2008). A correlation between P-wave velocity,
impact strength index, slake durability index and uniaxial compressive
strength. Bulletin of Engineering Geology and the Environment, 67(1), 17-22.
Tan, X., Chen, W., Yang, J., & Cao, J. (2011). Laboratory investigations on the
mechanical properties degradation of granite under freeze–thaw cycles. Cold
Regions Science and Technology, 68(3), 130-138.
Vasconcelos, G., Lourenço, P. B., Alves, C. A., & Pamplona, J. (2007). Prediction
of the mechanical properties of granites by ultrasonic pulse velocity and Schmidt
hammer hardness.
Yavuz, H., Altindag, R., Sarac, S., Ugur, I., & Sengun, N. (2006). Estimating the
index properties of deteriorated carbonate rocks due to freeze–thaw and thermal
shock weathering. International Journal of Rock Mechanics and Mining
Sciences, 43(5), 767-775.
Zappia, G., Sabbioni, C., Riontino, C., Gobbi, G., & Favoni, O. (1998). Exposure
tests of building materials in urban atmosphere. Science of the total
environment, 224(1-3), 235-244.
Zhang, S., Lai, Y., Zhang, X., Pu, Y., & Yu, W. (2004). Study on the damage
propagation of surrounding rock from a cold-region tunnel under freeze–thaw
cycle condition. Tunnelling and Underground Space Technology, 19(3), 295-302.
index properties of deteriorated carbonate rocks due to freeze–thaw and thermal
shock weathering. International Journal of Rock Mechanics and Mining
Sciences, 43(5), 767-775.
Zappia, G., Sabbioni, C., Riontino, C., Gobbi, G., & Favoni, O. (1998). Exposure
tests of building materials in urban atmosphere. Science of the total
environment, 224(1-3), 235-244.
Zhang, S., Lai, Y., Zhang, X., Pu, Y., & Yu, W. (2004). Study on the damage
propagation of surrounding rock from a cold-region tunnel under freeze–thaw
cycle condition. Tunnelling and Underground Space Technology, 19(3), 295-302.
)