基于矿物纳米压痕测试的岩石力学参数跨尺度估计方法

doi:10.3724/1000-6915.jrme.2025.0756

摘要
图/表
参考文献
相关文章 (15)

全文: PDF (958 KB) HTML (1 KB)
输出: BibTeX | EndNote (RIS)

摘要岩石的力学特性是岩体工程设计与分析的关键依据。然而，在高地应力引起的岩芯饼化、强节理化岩体以及地外岩体等特殊工况下，往往难以获取符合试验要求的标准化圆柱岩石试样。为解决这一问题，构建一套基于岩石矿物纳米压痕测试的岩石宏观力学参数综合预测体系。首先，采用纳米压痕测试获取岩石组成矿物的细观力学参数，包括硬度、弹性模量及I型断裂韧度；进而采用广义均值法将矿物弹性模量升尺度为岩石宏观弹性模量，其预测精度显著优于传统均匀化方法。其次，基于压痕硬度与抗压强度在物理机制上的一致性，建立考虑不同强度等级矿物影响的多元线性回归模型，用于预测岩石单轴抗压强度，并揭示低强度矿物对宏观强度的控制作用。进一步地，结合断裂力学理论与等效加权模型，构建基于矿物I型断裂韧度的岩石抗拉强度预测方法。该预测体系为难以取样条件下的岩石力学参数快速评估提供了有效途径，并通过引入Hoek-Brown准则，为实现“岩屑纳米压痕–岩芯–岩体”力学参数的跨尺度预测奠定方法基础。

	服务

	把本文推荐给朋友
	加入我的书架
	加入引用管理器
	E-mail Alert
	RSS
	作者相关文章
	柳秀洋1
	2
	徐鼎平1*
	江权1
	李邵军1

关键词 ：岩石力学, 纳米压痕, 硬度, 弹性模量, 断裂韧度, 单轴抗压强度, 抗拉强度

Abstract：The mechanical properties of rocks are critically important for the design and analysis of rock mass engineering. However, under specific conditions—such as core disking due to high in-situ stress, highly jointed rock masses, and extraterrestrial rock bodies—obtaining standard cylindrical rock specimens that meet conventional testing requirements can be challenging. To address this issue, this study develops an integrated prediction framework for estimating the macroscopic mechanical parameters of rocks based on nanoindentation tests of the constituent minerals. First, nanoindentation is employed to obtain meso-scale mechanical parameters of rock-forming minerals, including hardness, elastic modulus, and mode-I fracture toughness. The generalized means method is then applied to upscale the mineral elastic moduli to the macroscopic elastic modulus of the rock, demonstrating significantly higher prediction accuracy than traditional homogenization approaches. Second, leveraging the physical consistency between indentation hardness and uniaxial compressive strength, a multiple linear regression model incorporating the influence of minerals with varying strength grades is established to predict the uniaxial compressive strength of rocks, revealing the dominant role of low-strength minerals in controlling macroscopic strength. Furthermore, by integrating fracture mechanics theory with an equivalent weighting model, a predictive model for the tensile strength of rocks is formulated based on the mode-I fracture toughness of minerals. This framework provides an effective approach for the rapid estimation of rock mechanical parameters under sampling-constrained conditions and, through the introduction of the Hoek-Brown criterion, establishes a methodological foundation for achieving cross-scale predictions of mechanical parameters from “rock cuttings nanoindentation-rock core-rock mass”.

Key words： rock mechanics nanoindentation hardness elastic modulus fracture toughness uniaxial compressive strength tensile strength

引用本文:

柳秀洋1，2，徐鼎平1*，江权1，李邵军1. 基于矿物纳米压痕测试的岩石力学参数跨尺度估计方法[J]. 岩石力学与工程学报, 2026, 45(5): 1489-1502.
LIU Xiuyang1, 2, XU Dingping1*, JIANG Quan1, LI Shaojun1. Cross-scale estimation method for rock mechanical parameters based on mineral nanoindentation testing. , 2026, 45(5): 1489-1502.

链接本文:

https://rockmech.whrsm.ac.cn/CN/10.3724/1000-6915.jrme.2025.0756 或 https://rockmech.whrsm.ac.cn/CN/Y2026/V45/I5/1489

[1] ALADEJARE A E. Evaluation of empirical estimation of uniaxial compressive strength of rock using measurements from index and physical tests[J]. Journal of Rock Mechanics and Geotechnical Engineering，2020，12(2)：256–268.
[2] KOMADJA G C，STANISLAS T T，MUNGANYINKA P，et al. New approach for assessing uniaxial compressive strength of rocks using measurement from nanoindentation experiments[J]. Bulletin of Engineering Geology and the Environment，2022，81(8)：299.
[3] KARAKUL H，ULUSAY R. Empirical Correlations for predicting strength properties of rocks from P-Wave velocity under different degrees of saturation[J]. Rock Mechanics and Rock Engineering，2013，46(5)：981–999.
[4] MISHRA D A，BASU A. Use of the block punch test to predict the compressive and tensile strengths of rocks[J]. International Journal of Rock Mechanics and Mining Sciences，2012，51：119–127.
[5] AYDIN A，BASU A. The Schmidt hammer in rock material characterization[J]. Engineering Geology，2005，81(1)：1–14.
[6] 周博，卢自立，汪华斌，等. 基于均匀化理论的土石混合体应力应变关系[J]. 地质通报，2013，32(12)：2 001–2 007.(ZHOU Bo，LU Zili，WANG Huabin，et al. Stress–strain relationship of soil-rock mixture based on homogenization theory[J]. Geological Bulletin of China，2013，32(12)：2 001–2 007.(in Chinese))
[7] 朱其志，胡大伟，周辉，等. 基于均匀化理论的岩石细观力学损伤模型及其应用研究[J]. 岩石力学与工程学报，2008，27(2)：266– 272.(ZHU Qizhi，HU Dawei，ZHOU Hui，et al. Research on homogenization-based mesomechanical damage model and its application[J]. Chinese Journal of Rock Mechanics and Engineering，2008，27(2)：266–272.(in Chinese))
[8] ZHANG F，GUO H Q，HU D W，et al. Characterization of the mechanical properties of a claystone by nano-indentation and homogenization[J]. Acta Geotechnica，2018，13(6)：1 395–1 404.
[9] CAO J，GAO J C，RAD H N，et al. A novel systematic and evolved approach based on XGBoost—firefly algorithm to predict Young?s modulus and unconfined compressive strength of rock[J]. Engineering with Computers，2022，38(5)：3 829–3 845.
[10] MOMENI E，ARMAGHANI D J，HAJIHASSANI M，et al. Prediction of uniaxial compressive strength of rock samples using hybrid particle swarm optimization-based artificial neural networks[J]. Measurement，2015，60：50–63.
[11] LIU X Y，XU D P，LI S J，et al. Estimating the mechanical properties of rocks and rock masses based on mineral micromechanics testing[J]. Rock Mechanics and Rock Engineering，2024，57(7)：5 267–5 278.
[12] 张帆，郭翰群，赵建建，等. 花岗岩微观力学性质试验研究[J]. 岩石力学与工程学报，2017，36(增2)：3 864–3 872.(ZHANG Fan，GUO Hanqun，ZHAO Jianjian，et al. Nanoindentation tests on granite after heat treatment[J]. Chinese Journal of Rock Mechanics and Engineering，2017，36(Supp.2)：3 864–3 872.(in Chinese))
[13] 徐鼎平，柳秀洋，徐怀胜，等. 深埋花岗岩细观力学特性纳米压痕试验及参数均质化研究[J]. 中南大学学报：自然科学版，2021，52(8)：2 761–2 771.(XU Dingping，LIU Xiuyang，XU Huaisheng，et al. Research on homogenization-based mesomechanical damage model and its application[J]. Journal of Central South University：Science and Technology，2021，52(8)：2 761–2 771.(in Chinese))
[14] OLIVER W，PHARR G. Measurement of hardness and elastic modulus by instrumented indentation：Advances in understanding and refinements to methodology[J]. Journal of Materials Research，2004，19(1)：3–20.
[15] 江俊达，沈吉云，侯东伟. 基于纳米压痕的水化硅酸钙断裂韧度测试与计算方法[J]. 硅酸盐学报，2018，46(8)：1 067–1 073.(JIANG Junda，SHEN Jiyun，HOU Dongwei. Determination of fracture toughness of hydrated calcium silicate by nanoindentation[J]. Journal of the Chinese Ceramic Society，2018，46(8)：1 067–1 073.(in Chinese))
[16] LAWN B R，EVANS A G，MARSHALL D B. Elastic-plastic indentation damage in ceramics—The median-radial crack system[J]. Journal of the American Ceramic Society，1980，63(9/10)：574–581.
[17] LI C X，WANG D M，KONG L Y. Mechanical response of the Middle Bakken rocks under triaxial compressive test and nanoindentation[J]. International Journal of Rock Mechanics and Mining Sciences，2021，139：104660.
[18] LU J K，XU T，TANG X H，et al. Nanoindentation–based characterization of micromechanical properties of greenish mudstone from deep Fushun West open?pit mine(Fushun City，China)[J]. Geomechanics and Geophysics for Geo-Energy and Geo-Resources，2022，8(2)：59.
[19] LIU X Y，XU D P，LI S J，et al. An insight into the mechanical and fracture characterization of minerals and mineral interfaces in granite using nanoindentation and micro X-ray computed tomography[J]. Rock Mechanics and Rock Engineering，2023，56(5)：3 359–3 375.
[20] JI S C，WANG Q，XIA B，et al. Mechanical properties of multiphase materials and rocks：a phenomenological approach using generalized means[J]. Journal of Structural Geology，2004，26(8)：1 377–1 390.
[21] AYATOLLAHI M R，NAJAFABADI M Z，KOLOOR S S R，et al. Mechanical characterization of heterogeneous polycrystalline rocks using nanoindentation method in combination with generalized means method[J]. Journal of Mechanics，2020，36(6)：813–823.
[22] 孙伟. 脆性岩石巴西劈裂和断裂韧度试验细观分析方法及破裂机理研究[博士学位论文][D]. 北京：北京科技大学，2020.(SUN Wei. Research on the meso-analysis method and fracture mechanism in Brazilian test and fracture toughness test of brittle rock[Ph. D. Thesis][D]. Beijing：University of Science and Technology Beijing，2020.(in Chinese))
[23] ZHANG Z X. An empirical relation between mode I fracture toughness and the tensile strength of rock[J]. International Journal of Rock Mechanics and Mining Sciences，2002，39(3)：401–406.
[24] LOU Y H. Isotropized Voigt-Reuss model for prediction of elastic properties of particulate composites[J]. Mechanics of Advanced Materials and Structures，2022，29(25)：3 934–3 941.
[25] MA Z Y，ZHANG C P，GAMAGE R P，et al. Uncovering the creep deformation mechanism of rock-forming minerals using nanoindentation[J]. International Journal of Mining Science and Technology，2022，32(2)：283–294.
[26] MAHABADI O K，TATONE B S A，GRASSELLI G. Influence of microscale heterogeneity and microstructure on the tensile behavior of crystalline rocks[J]. Journal of Geophysical Research-Solid Earth，2014，119(7)：5 324–5 341.
[27] JAMSHIDI A. Predicting the strength of granitic stones after freeze-thaw cycles：considering the petrographic characteristics and a new approach using petro–mechanical parameter[J]. Rock Mechanics and Rock Engineering，2021，54(6)：2 829–2 841.
[28] WONG L N Y，MARUVANCHERY V. Different lithological varieties of Bukit Timah granite in Singapore：a preliminary comparison study on engineering properties[J]. Rock Mechanics and Rock Engineering，2016，49(7)：2 923–2 935.
[29] XU J J，ZHANG Y H，RUTQVIST J，et al. Thermally induced microcracks in granite and their effect on the macroscale mechanical behavior[J]. Journal of Geophysical Research-Solid Earth，2023，128(1)：B024920.
[30] LI X，WANG S，XU Y，et al. Effect of microwave irradiation on dynamic mode—I fracture parameters of Barre granite[J]. Engineering Fracture Mechanics，2020，224：106748.
[31] MARTIN C D，CHANDLER N A. The progressive fracture of Lac du Bonnet granite[J]. International Journal of Rock Mechanics and Mining Sciences and Geomechanics Abstracts，1994，31(6)：643–659.
[32] MO C，ZHAO J，ZHANG D. Real-time measurement of mechanical behavior of granite during heating-cooling cycle：a mineralogical perspective[J]. Rock Mechanics and Rock Engineering，2022，55(7)：4 403–4 422.
[33] HUANG X，QI S，ZHENG B，et al. An advanced grain-based model to characterize mechanical behaviors of crystalline rocks with different weathering degrees[J]. Engineering Geology，2021，280：105951.
[34] LAN H X，MARTIN C D，HU B. Effect of heterogeneity of brittle rock on micromechanical extensile behavior during compression loading[J]. Journal of Geophysical Research-Solid Earth，2010，115：B01202.
[35] 左建平，周宏伟，范雄，等. 三点弯曲下热处理北山花岗岩的断裂特性研究[J]. 岩石力学与工程学报，2013，32(12)：2 422–2 430. (ZUO Jianping，ZHOU Hongwei，FAN Xiong，et al. Research on fracture behavior of Beishan granite after heat treatment under three-point bending[J]. Chinese Journal of Rock Mechanics and Engineering，2013，32(12)：2 422–2 430.(in Chinese))
[36] 王超圣，蔡俊超，韩书娟，等. 北山花岗岩声发射特征及破坏模式识别研究[J]. 地下空间与工程学报，2023，19(1)：87–94.(WANG Chaosheng，CAI Junchao，HAN Shujuan，et al. Study on acoustic emission characteristics and failure mode identification of Beishan granite[J]. Chinese Journal of Underground Space and Engineering，2023，19(1)：87–94.(in Chinese))
[37] 毛伟泽. 花岗岩力学性质变异性的细观机制研究[硕士学位论文][D]. 浙江：浙江大学，2020.(MAO Weize. Study on meso- mechanism of variability of mechanical properties of granite[M. S. Thesis][D]. Zhejiang：Zhejiang University，2020.(in Chinese))
[38] 李春，胡耀青，张纯旺，等. 不同温度循环冷却作用后花岗岩巴西劈裂特征及其物理力学特性演化规律研究[J]. 岩石力学与工程学报，2020，39(9)：1 797–1 807.(LI Chun，HU Yaoqing，ZHANG Chunwang，et al. Brazilian split characteristics and mechanical property evolution of granite after cyclic cooling at different temperatures[J]. Chinese Journal of Rock Mechanics and Engineering，2020，39(9)：1 797–1 807.(in Chinese))
[39] HENG Z，XU T，KONIETZKY H，et al. New insights into the continuous—discontinuous failure characteristics of granite under Brazilian splitting test conditions using acousto-optic-mechanical (AOM) method[J]. International Journal of Rock Mechanics and Mining Sciences，2025，187：106041.
[40] LEI M，DANG F N，XUE H B，et al. Study on mechanical properties of granite minerals based on nanoindentation test technology[J]. Thermal Science，2021，25(6)：4 457–4 463.
[41] INGA C E C，SINHA S，WALTON G，et al. Modeling Brazilian tensile strength tests on a brittle rock using deterministic，semi- deterministic，and Voronoi bonded block models[J]. Rock Mechanics and Rock Engineering，2023，56(7)：5 293–5 313.
[42] SHA S，RONG G，PENG J，et al. Effect of open-fire-induced damage on Brazilian tensile strength and microstructure of granite[J]. Rock Mechanics and Rock Engineering，2019，52(11)：4 189–4 202.
[43] 唐欣薇，黄文敏，周元德，等. 华南风化花岗岩劈拉断裂行为的试验与细观模拟研究[J]. 工程力学，2017，34(6)：246–256.(TANG Xinwei，HUANG Wenmin，ZHOU Yuande，et al. Experimental and meso–scale numerical modeling of splitting tensile behavior of weathered granites from South China[J]. Engineering Mechanics，2017，34(6)：246–256.(in Chinese))
[44] SHU B，LIANG M，ZHANG S H，et al. Numerical modeling of the relationship between mechanical properties of granite and microparameters of the flat-joint model considering particle size distribution[J]. Mathematical Geosciences，2019，51(3)：319–336.
[45] 胡训健，卞康，刘建，等. 花岗岩晶体粒径分布对声发射特性影响的颗粒流模拟[J]. 煤炭学报，2021，46(增2)：721–730.(HU Xunjian，BIAN Kang，LIU Jian，et al. Particle flow simulation of the influence of granite crystal size distribution on acoustic emission characteristics[J]. Journal of China Coal Society，2021，46(Supp.2)：721–730.(in Chinese))
[46] 李博，朱强，张丰收，等. 基于矿物晶体模型的非均质性岩石双裂纹扩展规律研究[J]. 岩石力学与工程学报，2021，40(6)： 1 119–1 131.(LI Bo，ZHU Qiang，ZHANG Fengshou，et al. Study on crack propagation of heterogeneous rocks with double flaws based on grain based model[J]. Chinese Journal of Rock Mechanics and Engineering，2021，40(6)：1 119–1 131.(in Chinese))
[47] HOFMANN H，BABADAGLI T，YOON J S，et al. A grain based modeling study of mineralogical factors affecting strength，elastic behavior and micro fracture development during compression tests in granites[J]. Engineering Fracture Mechanics，2015，147：261–275.
[48] SAADAT M，TAHERI A. Modelling micro-cracking behaviour of granite during direct tensile test using cohesive GBM approach[J]. Engineering Fracture Mechanics，2020，239：107297.
[49] ZHOU J，LAN H，ZHANG L，et al. Novel grain-based model for simulation of brittle failure of Alxa porphyritic granite[J]. Engineering Geology，2019，251：100–114.
[50] HOEK E，BROWN E T. The Hoek-Brown failure criterion and GSI-2018 edition[J]. Journal of Rock Mechanics and Geotechnical Engineering，2019，11(3)：445–463.
[51] HOEK E，CARRANZA-TORRES C，CORKUM B. Hoek-Brown failure criterion—2002 edition[C]// Proceedings of the North American Rock Mechanics Society. Toronto：[s. n.]， 2002：267–273.