Establishing constitutive relationships that describe the deformation behaviour of rocks remains a central focus in rock mechanics. With the introduction of growth laws, adoption of distinct assumptions for the damage evolution rate under loading, and incorporation of a new parameter termed the maximum damage degree to represent the practical characteristic that the load-bearing capacity of rocks does not vanish completely with progressive deformation, three damage constitutive relations are derived, namely, linear, logarithmic and quadratic forms. The proposed models include two damage evolution parameters. These parameters can be determined analytically through closed-form expressions based on conventional mechanical properties, thereby ensuring the practicality and applicability of the models. Validation is performed using existing compression test data for granite and marble. Additionally, the effect of damage evolution parameters on the stress–strain response is examined. The results show that for identical strain conditions, the damage degree predicted by the quadratic damage constitutive relationship is greater than that obtained from the linear and logarithmic relationships in sequence. Error statistics show that the quadratic damage constitutive relationship exhibits the best performance, followed by the linear and logarithmic models. Furthermore, both the quadratic and linear relationships outperform the existing damage relationship employing the Weibull function. In the proposed models, the two damage evolution parameters respectively govern the size and shape of deformation curve. By incorporating the variation of conventional mechanical parameters with confining pressure, the proposed model can predict the deformation response of rocks under various confining pressures.
AghababaeiMBehniaMMoradianO (2019) Experimental investigation on strength and failure behavior of carbonate rocks under multistage triaxial compression. International Journal of Rock Mechanics and Mining Sciences123: 104099.
2.
AsemPGardoniP (2021) A generalized Bayesian approach for prediction of strength and elastic properties of rock. Engineering Geology289: 106187.
3.
BrantutNHeapMJMeredithPG, et al. (2013) Time-dependent cracking and brittle creep in crustal rocks: A review. Journal of Structural Geology52: 17–43.
4.
CaiMKPKKaiserPKTasakaY, et al. (2004) Generalized crack initiation and crack damage stress thresholds of brittle rock masses near underground excavations. International Journal of Rock Mechanics and Mining Sciences41(5): 833–847.
5.
CaoHZhuDBaoT, et al. (2024) Applicability of rock damage model based on power law distribution. Acta Geophysica72(5): 3021–3036.
6.
CaoWMoRLiX (2007) Study on statistical constitutive model and determination of parameters of rock based on normal distribution. Chinese Journal of Geotechnical Engineering29(5): 671–675.
7.
ChenGZhaoCWeiT, et al. (2018) Evaluation method of brittle characteristics of rock based on full stress–strain curve and crack initiation stress. Chinese Journal of Rock Mechanics and Engineering37(1): 51–59.
8.
ChenKCudmaniR (2025a) A damage-based mechanical model for rock joints and its application to evaluate roughness and safety factor of the rock slope. Rock Mechanics and Rock Engineering59: 2313–2344.
9.
ChenKCudmaniROlarteAAP (2024) Validation of a damage constitutive model based on logistic model dedicated to the mechanical behavior of the rock. Geomechanics and Geophysics for Geo-Energy and Geo-Resources10(1): 15.
10.
ChenKCudmaniRPeñaA (2025b) A rock damage model considering shear failure by modified logistic growth theory. Journal of Rock Mechanics and Geotechnical Engineering17(3): 1321–1355.
11.
ChengHMYangXBLuJ, et al. (2025) Statistical damage constitutive model based on energy conversion for rocks. International Journal of Damage Mechanics34(1): 186–210.
12.
ColmenaresLBZobackMD (2002) A statistical evaluation of intact rock failure criteria constrained by polyaxial test data for five different rocks. International Journal of Rock Mechanics and Mining Sciences39(6): 695–729.
13.
DengJGuD (2011) On a statistical damage constitutive model for rock materials. Computers & Geosciences37(2): 122–128.
14.
DetournayE (1986) Elastoplastic model of a deep tunnel for a rock with variable dilatancy. Rock Mechanics and Rock Engineering19(2): 99–108.
15.
FuHYYuXWZengL, et al. (2024) Mechanical properties and damage constitutive model of silty mudstone under heating and water-cooling cycles. Acta Geotechnica19: 5031–5050.
16.
GuoYPLiuDQXiongX, et al. (2025a) A Gompertz-based statistical damage model for water–rock interaction under uniaxial compression and its verification. International Journal of Geomechanics25(9): 04025183.
17.
GuoY. P.LiuD. Q.YangS. K., et al. (2025b). A new rock damage constitutive model based on Usher function and its application to brittleness evaluation. Rock Mechanics and Rock Engineering, 58(2), 1451–1472.
18.
HajiabdolmajidVKaiserPKMartinCD (2002) Modelling brittle failure of rock. International Journal of Rock Mechanics and Mining Sciences39(6): 731–741.
19.
HudsonJAHarrisonJP (2000) Engineering rock mechanics: an introduction to the principles. Amsterdam: Elsevier.
20.
IdlangoMAShepherdJJNguyenL, et al. (2012) Harvesting a logistic population in a slowly varying environment. Applied Mathematics Letters25(1): 81–87.
21.
JiangWLaiYMaQ, et al. (2023) Mechanical damage model and brittleness index of frozen rocks based on statistical damage theory. Acta Geotechnica18(9): 4687–4713.
22.
KapitzaSP (1996) The phenomenological theory of world population growth. Physics-uspekhi39(1): 57.
23.
KrajcinovicDSilvaMAG (1982) Statistical aspects of the continuous damage theory. International Journal of Solids and Structures18(7): 551–562.
24.
KuangZQiuSLiS, et al. (2021) A new rock brittleness index based on the characteristics of complete stress–strain behaviors. Rock Mechanics and Rock Engineering54: 1109–1128.
25.
LemaitreJ (1984) How to use damage mechanics. Nuclear Engineering and Design80(2): 233–245.
26.
LemaitreJ (1985) Coupled elasto-plasticity and damage constitutive equations. Computer Methods in Applied Mechanics and Engineering51(1-3): 31–49.
27.
LiXCaoWGSuYH (2012) A statistical damage constitutive model for softening behavior of rocks. Engineering Geology143: 1–17.
28.
LiYJiaDRuiZ, et al. (2017) Evaluation method of rock brittleness based on statistical constitutive relations for rock damage. Journal of Petroleum Science and Engineering153: 123–132.
29.
LiYLongMZuoL, et al. (2019) Brittleness evaluation of coal based on statistical damage and energy evolution theory. Journal of Petroleum Science and Engineering172: 753–763.
30.
LiuDHeMCaiM (2018) A damage model for modeling the complete stress–strain relations of brittle rocks under uniaxial compression. International Journal of Damage Mechanics27(7): 1000–1019.
31.
LiuDQGuoYPLingK, et al. (2024a) A whole process damage constitutive model for layered sandstone under uniaxial compression based on logistic function. Journal of Central South University31(7): 2411–2430.
32.
LiuXLiPGuoX, et al. (2024b) A statistical damage-based constitutive model for shearing of rock joints in brittle drop mode. International Journal of Mining Science and Technology34(8): 1041–1058.
33.
LiuHYLvSRZhangLM, et al. (2015) A dynamic damage constitutive model for a rock mass with persistent joints. International Journal of Rock Mechanics and Mining Sciences75: 132–139.
34.
LiuYDaiF (2018) A damage constitutive model for intermittent jointed rocks under cyclic uniaxial compression. International Journal of Rock Mechanics and Mining Sciences103: 289–301.
35.
PathiranageiSVGratchevI (2022) Coupled thermo-mechanical constitutive damage model for sandstone. Journal of Rock Mechanics and Geotechnical Engineering14(6): 1710–1721.
36.
PourhosseiniOShabanimashcoolM (2014) Development of an elasto-plastic constitutive model for intact rocks. International Journal of Rock Mechanics and Mining Sciences66: 1–12.
37.
SeidlITisdellCA (1999) Carrying capacity reconsidered: From Malthus’ population theory to cultural carrying capacity. Ecological Economics31(3): 395–408.
38.
SunXShiFLuanZ, et al. (2023) Constitutive model and microscopic mechanism for sandstone strength softening damage. Rock Mechanics and Rock Engineering56(1): 797–813.
39.
TaheriAShirani FaradonbehRMunozH (2022) Experimental study on progressive damage evolution in rocks subjected to post-peak cyclic loading history. Geotechnical Testing Journal45(3): 606–626.
40.
UlusayR (2016) Rock mechanics and rock engineering: From the past to the future. London: CRC Press.
41.
WangCPLiuJFCaiYG, et al. (2024) Effects of damage and fractional derivative operator on creep model of fractured rock. Rock Mechanics and Rock Engineering57: 9323–9341.
42.
WangZFengCWangJ, et al. (2022) An improved statistical damage constitutive model for rock considering the temperature effect. International Journal of Geomechanics22(11): 04022203.
43.
WangZFQiCZMaXY, et al. (2025) A statistical damage constitutive model of anisotropic intact rock considering brittle‒ductile behavior based on the improved Hoek‒Brown criterion. Rock Mechanics and Rock Engineering: 1–20.
44.
WangZLLiYCWangJG (2007) A damage-softening statistical constitutive model considering rock residual strength. Computers & Geosciences33(1): –9.
45.
WangZLLiuYSShenRF (2008) Stress–strain relationship of steel fiber-reinforced concrete under dynamic compression. Construction and Building Materials22(5): 811–819.
46.
WuFChenJZouQ (2019) A nonlinear creep damage model for salt rock. International Journal of Damage Mechanics28(5): 758–771.
47.
WuLYWangZMaD, et al. (2022) A continuous damage statistical constitutive model for sandstone and mudstone based on triaxial compression tests. Rock Mechanics and Rock Engineering55(8): 4963–4978.
48.
XieSHanZHuH, et al. (2022) Application of a novel constitutive model to evaluate the shear deformation of discontinuity. Engineering Geology304: 106693.
49.
XieSLinHChenY, et al. (2020) A damage constitutive model for shear behavior of joints based on determination of the yield point. International Journal of Rock Mechanics and Mining Sciences128: 104269.
50.
XuXLKarakusM (2018) A coupled thermo-mechanical damage model for granite. International Journal of Rock Mechanics and Mining Sciences103: 195–204.
51.
YahalomYSteinmetzBShnerbNM (2019) Comprehensive phase diagram for logistic populations in fluctuating environment. Physical Review E99(6): 062417.
52.
YanZWuWDaiF, et al. (2023) Dynamic mechanical response and damage constitutive model of multi-flawed rocks under high strain rates. Rock Mechanics and Rock Engineering56(6): 4405–4425.
53.
ZhaoHShiCZhaoM, et al. (2017) Statistical damage constitutive model for rocks considering residual strength. International Journal of Geomechanics17(1): 04016033.
54.
ZhengZXuHHeB, et al. (2023) A new statistical damage model for true triaxial pre- and post-peak behaviors of rock considering intermediate principal stress and initial compaction effects. International Journal of Damage Mechanics32(2): 204–234.
55.
ZhouHJinZ (2023) Fractional derivative triaxial creep model of Beishan granite considering probabilistic damage evolution. Acta Geotechnica18(8): 4017–4033.
56.
ZouZYanJTangH, et al. (2020) A shear constitutive model for describing the full process of the deformation and failure of slip zone soil. Engineering Geology276: 105766.
