Deterioration and strain energy development of sandstones under quasi-static and dynamic loading after freeze-thaw cycles

Abstract Rocks in cold regions are often exposed to extreme temperature change, and different loading conditions, therefore, will be subjected to deterioration. In this study, the deterioration of sandstone after freeze-thaw (F-T) cycles under quasi-static and dynamic loading conditions is investigated. In doing so, physical and mechanical properties of sandstone samples were studied after 20, 60, 100 and 140 F-T cycles. An increase in porosity and decrease in P wave velocity demonstrated a degradation in physical properties after F-T cycles. In addition, peak strengths of specimens were observed to be higher in the dynamic loading conditions as compared with the quasi-static conditions; while Young's modulus almost remained constant. Furthermore, a decay model was used to predict the deterioration of sandstone under different loading conditions and F-T cycles. Finally, the effects of F-T cycles on a brittleness and strain energy development were investigated. It was observed that rock became more brittle in the pre-peak regime after F-T cycles. It also demonstrated strain energies including the pre-peak, the peak, the post-peak and the total strain energies decrease after F-T cycles while variations of elastic strain energy with F-T cycles doesn't show any conclusive trend. Correlations between porosity and strain energies implied that porosity is a key factor in strain energy development for this kind of sandstone except that of elastic strain energy.

[1]  R. Martin,et al.  Static and Dynamic Elastic Moduli in Granite: The Effect of Strain Amplitude , 1994 .

[2]  Gong Feng-qiang,et al.  Experimental research of sandstone dynamic strength criterion under different strain rates , 2013 .

[3]  Huatao Zhao,et al.  Effects of freeze-thaw treatment on the dynamic tensile strength of granite using the Brazilian test , 2018, Cold Regions Science and Technology.

[4]  A. Özbek,et al.  Investigation of the effects of wetting–drying and freezing–thawing cycles on some physical and mechanical properties of selected ignimbrites , 2014, Bulletin of Engineering Geology and the Environment.

[5]  Xibing Li,et al.  Dynamic Characteristics of Granite Subjected to Intermediate Loading Rate , 2005 .

[6]  W. R. Wawersik,et al.  A study of brittle rock fracture in laboratory compression experiments , 1970 .

[7]  A. Taheri,et al.  Fracture Energy-Based Brittleness Index Development and Brittleness Quantification by Pre-peak Strength Parameters in Rock Uniaxial Compression , 2016, Rock Mechanics and Rock Engineering.

[8]  A. Kidybiński,et al.  Bursting liability indices of coal , 1981 .

[9]  Aydın Özsan,et al.  Evaluation of the long-term durability of yellow travertine using accelerated weathering tests , 2011 .

[10]  Dawn T. Nicholson,et al.  Physical deterioration of sedimentary rocks subjected to experimental freeze–thaw weathering , 2000 .

[11]  Feng Gao,et al.  Coupled effects of chemical environments and freeze–thaw cycles on damage characteristics of red sandstone , 2017, Bulletin of Engineering Geology and the Environment.

[12]  R. J. Christensen,et al.  Split-hopkinson-bar tests on rock under confining pressure , 1972 .

[13]  Bo Ke,et al.  Degradation of physical and mechanical properties of sandstone subjected to freeze-thaw cycles and chemical erosion , 2018, Cold Regions Science and Technology.

[14]  E. Chanda,et al.  Rock Drilling Performance Evaluation by an Energy Dissipation Based Rock Brittleness Index , 2016, Rock Mechanics and Rock Engineering.

[15]  Morrell H. Cohen,et al.  Nuclear magnetic relaxation and the internal geometry of sedimentary rocks , 1982 .

[16]  Surendra P. Shah,et al.  Effect of Length on Compressive Strain Softening of Concrete , 1997 .

[17]  G. R. Khanlari,et al.  The effect of freeze–thaw cycles on physical and mechanical properties of granitoid hard rocks , 2016, Bulletin of Engineering Geology and the Environment.

[18]  Abbas Taheri,et al.  Pre-Peak and Post-Peak Rock Strain Characteristics During Uniaxial Compression by 3D Digital Image Correlation , 2016, Rock Mechanics and Rock Engineering.

[19]  E. T. Brown Rock characterization, testing & monitoring: ISRM suggested methods , 1981 .

[20]  Peng Wang,et al.  Energy dissipation and damage evolution analyses for the dynamic compression failure process of red-sandstone after freeze-thaw cycles , 2017 .

[21]  M. J. Forrestal,et al.  A split Hopkinson pressure bar technique to determine compressive stress-strain data for rock materials , 2001 .

[22]  Michel Aubertin,et al.  On the Use of the Brittleness Index Modified (BIM) to Estimate the Post-Peak Behavior of Rocks , 1994 .

[23]  M. M. Aliyu,et al.  Porosity increment and strength degradation of low-porosity sedimentary rocks under different loading conditions , 2015 .

[24]  T. Onargan,et al.  Mechanical property degradation of ignimbrite subjected to recurrent freeze–thaw cycles , 2004 .

[25]  Zilong Zhou,et al.  Influence of cyclic wetting and drying on physical and dynamic compressive properties of sandstone , 2017 .

[26]  V. Hucka,et al.  Brittleness determination of rocks by different methods , 1974 .

[27]  C. Thomachot,et al.  Evolution of the petrophysical properties of two types of Alsatian sandstone subjected to simulated freeze-thaw conditions , 2002, Geological Society, London, Special Publications.

[28]  Xibing Li,et al.  Fracture Evolution Around a Cavity in Brittle Rock Under Uniaxial Compression and Coupled Static–Dynamic Loads , 2018, Rock Mechanics and Rock Engineering.

[29]  A. Taheri,et al.  Local Damage and Progressive Localisation in Porous Sandstone During Cyclic Loading , 2017, Rock Mechanics and Rock Engineering.

[30]  A. Taheri,et al.  Degradation and improvement of mechanical properties of rock under triaxial compressive cyclic loading , 2017 .

[31]  Abbas Taheri,et al.  Rock cutting performance assessment using strain energy characteristics of rocks , 2017 .

[32]  M. N. Bagde,et al.  Fatigue properties of intact sandstone samples subjected to dynamic uniaxial cyclical loading , 2005 .

[33]  Xibing Li,et al.  Suggested Methods for Determining the Dynamic Strength Parameters and Mode-I Fracture Toughness of Rock Materials , 2012 .

[34]  Zilong Zhou,et al.  Stress uniformity of split Hopkinson pressure bar under half-sine wave loads , 2011 .

[35]  C. Scholz,et al.  Dilatancy in the fracture of crystalline rocks , 1966 .

[36]  Abbas Taheri,et al.  Experimental Study on Degradation of Mechanical Properties of Sandstone Under Different Cyclic Loadings , 2016 .

[37]  A. Skauge,et al.  Absolute pore size distributions from NMR , 2006 .

[38]  R Altindag,et al.  A decay function model for the integrity loss of rock when subjected to recurrent cycles of freezing-thawing and heating-cooling , 2004 .

[39]  E. Fjær Static and dynamic moduli of a weak sandstone , 2009 .

[40]  Xibing Li,et al.  Oscillation elimination in the Hopkinson bar apparatus and resultant complete dynamic stress-strain curves for rocks , 2000 .

[41]  Da Huang,et al.  Strain Rate Dependency of Coarse Crystal Marble Under Uniaxial Compression: Strength, Deformation and Strain Energy , 2014, Rock Mechanics and Rock Engineering.