郭旭

个人信息Personal Information

教授

博士生导师

硕士生导师

性别:男

毕业院校:大连理工大学

学位:博士

所在单位:力学与航空航天学院

学科:固体力学. 计算力学. 工程力学. 航空航天力学与工程

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论文成果

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代表性论著目录 (*代表为通讯作者或通讯作者之一)

1. Zhu Y. C., Luo J., Guo X.*, Xiang Y., J. C. Stephen. Role of grain boundaries under long-time radiation. Physical Review Letters 2018, 120(22): 222501.

2. Du Z. L., Cui T. C., Liu C, Zhang W. S., Guo Y. L., Guo X.*, An efficient and easy-to-extend Matlab code of the Moving Morphable Component (MMC) method for three-dimensional topology optimization. Structural and Multidisciplinary Optimization, 2022, 65(5): 158.

3. Xue D. C., Zhu Y. C.*, Li S. S., Liu C., Zhang W. S., Guo X.* On speeding up an asymptotic-analysis-based homogenisation scheme for designing gradient porous structured materials using a zoning strategy. Structural and Multidisciplinary Optimization 2020, 62(2): 457-473.

4. Liu C., Zhu Y. C., Sun Z., Li D. D., Du Z. L.*, Zhang W. S., Guo X.* An efficient moving morphable component (MMC)-based approach for multi-resolution topology optimization. Structural and Multidisciplinary Optimization 2018, 58(6): 2455-2479.

5. Zhang W. S., Zhou J. H., Zhu Y. C., Guo X.* Structural complexity control in topology optimization via moving morphable component (MMC) approach. Structural and Multidisciplinary Optimization 2017, 56(3): 535-552.

6. Zhang W. S., Yuan J., Zhang J., Guo X.* A new topology optimization approach based on Moving Morphable Components (MMC) and the ersatz material model. Structural and Multidisciplinary Optimization 2016, 53(6): 1243-1260.

7. Du Z. L., Guo X.* Symmetry analysis for structural optimization problems involving reliability measure and bi-modulus materials. Structural and Multidisciplinary Optimization 2016, 53(5): 973-984.

8. Ni C. H., Yan J.*, Cheng G. D., Guo X. Integrated size and topology optimization of skeletal structures with exact frequency constraints. Structural and Multidisciplinary Optimization 2014, 50(1): 113-128.

9. Guo X.*, Du Z. L., Cheng G. D. A confirmation of a conjecture on the existence of symmetric optimal solution under multiple loads. Structural and Multidisciplinary Optimization 2014, 50(4): 659-661.

10. Guo X.*, Du Z. L., Cheng G. D., Ni C. H. Symmetry properties in structural optimization: some extensions. Structural and Multidisciplinary Optimization 2013, 47(6): 783-794.

11. Guo X.*, Ni C. H., Cheng G. D., Du Z. L. Some symmetry results for optimal solutions in structural optimization. Structural and Multidisciplinary Optimization 2012, 46(5): 631-645.

12. Guo X., Cheng G. D.*, Olhoff N. Optimum design of truss topology under buckling constraints. Structural and Multidisciplinary Optimization 2005, 30 (3): 169-180.

13. Guo X.*, Cheng G. D., Yamazaki K. A note on stress-constrained truss topology optimization. Structural and Multidisciplinary Optimization 2004, 27 (1): 136-137.

14. Guo X.*, Cheng G. D.*, Yamazaki K.* A new approach for the solution of singular optima in truss topology optimization with stress and local buckling constraints. Structural and Multidisciplinary Optimization 2001, 22(5): 364-373.

15. Guo X.*, Yamazaki K.*, Cheng G. D.* A new two-point approximation approach for structural optimization. Structural and Multidisciplinary Optimization 2000, 20 (1): 22-28.

16. Guo X.*, Cheng G. D.* An extrapolation approach for the solution of singular  optima. Structural and Multidisciplinary  Optimization 2000, 19 (4): 255-262.

17. Cheng G. D.*, Guo X. ε-relaxed approach in structural topology optimization. Structural and Multidisciplinary Optimization 1997, 13(4): 258-266.

18. Jiang X. D., Huo W. D., Liu C.*, Du Z. L., Zhang X. Y., Li X., Guo X.* Explicit layout optimization of complex rib-reinforced thin-walled structures via computational conformal mapping (CCM). Computer Methods in Applied Mechanics and Engineering, 2023, 404: 115745.

19. Jiang X. D., Liu C.*, Du Z. L., Huo W. D., Zhang X. Y., Liu F., Guo X.* A unified framework for explicit layout/topology optimization of thin-walled structures based on Moving Morphable Components (MMC) method and adaptive ground structure approach. Computer Methods in Applied Mechanics and Engineering 2022, 396: 115047.

20. Ma C., Xue D. C., Li S. S., Zhou Z. C., Zhu Y. C.*, Guo X.* Compliance minimisation of smoothly varying multiscale structures using asymptotic analysis and machine learning. Computer Methods in Applied Mechanics and Engineering 2022, 395: 114861.

21. Zhang W. S., Yan X. Y., Meng Y., Zhang C. L., Youn S. K.*, Guo X.* Flexoelectric nanostructure design using explicit topology optimization. Computer Methods in Applied Mechanics and Engineering 2022, 394: 114943.

22. Liu D. P., Yang H., Elkhodary E. I., Tang S.*, Liu W. K.*, Guo X.* Mechanistically informed data-driven modeling of cyclic plasticity via artificial neural networks. Computer Methods in Applied Mechanics and Engineering 2022, 393: 114766.

23. Li S. S., Zhu Y. C.*, Guo X.* Optimisation of spatially varying orthotropic porous structures based on conformal mapping. Computer Methods in Applied Mechanics and Engineering 2022, 391: 114589.

24. Zhang G., Guo T. F., Elkhodary E. I., Tang S.*, Guo X.* Mixed Graph-FEM phase field modeling of fracture in plates and shells with nonlinearly elastic solids. Computer Methods in Applied Mechanics and Engineering 2022, 389: 114282.

25. Tang S., Yang H., Qiu H., Fleming M., Liu W. K.*, Guo X.* MAP123-EPF: A mechanistic-based data-driven approach for numerical elastoplastic modeling at finite strain. Computer Methods in Applied Mechanics and Engineering 2021, 373: 113484.

26. Tang S., Li Y., Qiu H., Yang H., Saha S., Mojumder S., Liu W. K.*, Guo X.* MAP123-EP: A mechanistic-based data-driven approach for numerical elastoplastic analysis. Computer Methods in Applied Mechanics and Engineering 2021, 364: 112955.

27. Liu C., Du Z. L.*, Zhu Y. C., Zhang W. S., Zhang X. Y., Guo X.* Optimal design of shell-graded-infill structures by a hybrid MMC-MMV approach. Computer Methods in Applied Mechanics and Engineering 2020, 369: 113187.

28. Xue D. C., Zhu Y. C.*, Guo X.* Generation of smoothly-varying infill configurations from a continuous menu of cell patterns and the asymptotic analysis of its mechanical behaviour. Computer Methods in Applied Mechanics and Engineering 2020, 366: 113037.

29. Zhang W. S., Jiang S., Liu C., Li D. D., Kang P., Youn S. K.*, Guo X.* Stress-related topology optimization of shell structures using IGA/TSA-based moving morphable void (MMV) approach. Computer Methods in Applied Mechanics and Engineering 2020, 366: 113036.

30. Zhang W. S., Li D. D., Kang P., Guo X.*, Youn S. K.* Explicit topology optimization using IGA-based moving morphable void (MMV) approach. Computer Methods in Applied Mechanics and Engineering 2020, 360: 112685.

31. Zhang G., Guo T. F., Guo X.*, Tang S.*, Fleming M., Liu W. K. Fracture in tension–compression-asymmetry solids via phase field modeling. Computer Methods in Applied Mechanics and Engineering 2019, 357: 112573.

32. Tang S., Zhang G., Yang H., Li Y.*, Liu W. K.*, Guo X.* MAP123: A data-driven approach to use 1D data for 3D nonlinear elastic materials modeling. Computer Methods in Applied Mechanics and Engineering 2019, 357: 112587.

33. Tang S., Zhang G., Guo T. F., Guo X.*, Liu W. K.* Phase field modeling of fracture in nonlinearly elastic solids via energy decomposition. Computer Methods in Applied Mechanics and Engineering 2019, 347: 477-494.

34. Xue R. Y., Liu C., Zhang W. S., Zhu Y. C., Tang S., Du Z. L.*, Guo X.* Explicit structural topology optimization under finite deformation via moving morphable void (MMV) approach. Computer Methods in Applied Mechanics and Engineering 2019, 344: 798-818.

35. Zhang W. S., Li D., Zhou J. H., Du Z. L., Li B. J., Guo X.* A moving morphable void (MMV)-based explicit approach for topology optimization considering stress constraints. Computer Methods in Applied Mechanics and Engineering 2018, 334: 381-413.

36. Zhang W. S., Liu Y., Wei P., Zhu Y. C., Guo X.* Explicit control of structural complexity in topology optimization. Computer Methods in Applied Mechanics and Engineering 2017, 324: 149-169.

37. Guo X.*, Zhou J. H., Zhang W. S., Du Z. L., Liu C., Liu Y. Self-supporting structure design in additive manufacturing through explicit topology optimization. Computer Methods in Applied Mechanics and Engineering 2017, 323: 27-63.

38. Zhang W. S., Chen J. S., Zhu X. F., Zhou J. H., Xue D. C., Lei X., Guo X.* Explicit three dimensional topology optimization via Moving Morphable Void (MMV) approach. Computer Methods in Applied Mechanics and Engineering 2017, 322: 590-614.

39. Zhang W. S., Li D., Zhang J., Guo X.* Minimum length scale control in structural topology optimization based on the Moving Morphable Components (MMC) approach. Computer Methods in Applied Mechanics and Engineering 2016, 311: 327-355.

40. Guo X.*, Zhang W. S., Zhang J., Yuan J. Explicit structural topology optimization based on moving morphable components (MMC) with curved skeletons. Computer Methods in Applied Mechanics and Engineering 2016, 310: 711-748.

41. Zhang W. S., Zhong W. L., Guo X.* Explicit layout control in optimal design of structural systems with multiple embedding components. Computer Methods in Applied Mechanics and Engineering 2015, 290: 290-313.

42. Guo X.*, Zhao X. F., Zhang W. S., Yan J., Sun G. M. Multi-scale robust design and optimization considering load uncertainties. Computer Methods in Applied Mechanics and Engineering 2015, 283: 994-1009.

43. Guo X.*, Zhang W. S., Zhong W. L. Explicit feature control in structural topology optimization via level set method. Computer Methods in Applied Mechanics and Engineering 2014, 272: 354-378.

44. Guo X.*, Zhang W. S., Zhong W. L. Stress-related topology optimization of continuum structures involving multi-phase materials. Computer Methods in Applied Mechanics and Engineering 2014, 268: 632-655.

45. Wang X. Y., Guo X.*, Su Z. A quasi-continuum model for human erythrocyte membrane based on the higher order Cauchy-Born rule. Computer Methods in Applied Mechanics and Engineering 2014, 268: 284-298.

46. Zhang W. S., Zhong W. L., Guo X.* An explicit length scale control approach in SIMP-based topology optimization. Computer Methods in Applied Mechanics and Engineering 2014, 282: 71-86.

47. Guo X.*, Zhang W. S., Zhang L. Robust structural topology optimization considering boundary uncertainties. Computer Methods in Applied Mechanics and Engineering 2013, 253: 356-368.

48. Guo X.*, Zhang W. S., Wang M. Y., Wei P. Stress-related topology optimization via level set approach. Computer Methods in Applied Mechanics and Engineering 2011, 200(47-48): 3439-3452.

49. Guo X.*, Bai W., Zhang W. S., Gao X. X. Confidence structural robust design and optimization under stiffness and load uncertainties. Computer Methods in Applied Mechanics and Engineering 2009, 198(41-44): 3378-3399.

50. Zhou Z. C., Zhu Y. C.*, Guo X.*, Machine learning based asymptotic homogenization and localization: Predictions of key local behaviors of multiscale configurations bearing microstructural varieties. International Journal for Numerical Methods in Engineering, 2023, 124(3): 639-669.

51. Li J. L., Zhang Y. W.*, Du Z. L., Liu C., Zhang W. S., Guo X. L., Guo X.* A moving morphable componentbased topology optimization approach considering transient structural dynamic responses. International Journal for Numerical Methods in Engineering 2022, 123(3): 705-728.

52. Zhang W. S., Jiang Q. Q., Feng W. Z., Youn S. K.*, Guo X.* Explicit structural topology optimization using boundary element methodbased moving morphable void approach. International Journal for Numerical Methods in Engineering 2021, 122(21): 6155-6179.

53. Zhang W. S., Xiao Z., Liu C., Mei Y., Youn S. K., Guo X.* A scaled boundary finite element based explicit topology optimization approach for threedimensional structures. International Journal for Numerical Methods in Engineering 2020, 121(21): 4878-4900.

54. Du J. M., Du Z. L.*, Wei Y. H., Zhang W. S., Guo X.* Exact response bound analysis of truss structures via linear mixed 01 programming and sensitivity bounding technique. International Journal for Numerical Methods in Engineering 2018, 116(1): 21-42.

55. Zhang W. S., Song J. F., Zhou J. H., Du Z. L., Zhu Y. C., Sun Z., Guo X.* Topology optimization with multiple materials via moving morphable component (MMC) method. International Journal for Numerical Methods in Engineering 2018, 113(11): 1653-1675.

56. Zhang W. S., Guo X.*, Wang M. Y., Wei P. Optimal topology design of continuum structures with stress concentration alleviation via level set method. International Journal for Numerical Methods in Engineering 2013, 93(9): 942-959.

57. Guo X.*, Du J. M., Gao X. X. Confidence structural robust optimization by non-linear semidefinite programming-based single-level formulation. International Journal for Numerical Methods in Engineering 2011, 86(8): 953-974.

58. Kanno Y.*, Guo X. A mixed integer programming for robust truss topology optimization with stress constraints. International Journal for Numerical Methods in Engineering 2010, 83(13): 1675-1699.

59. Guo X.*, Bai W., Zhang W. S. Extreme structural response analysis of truss structures under material uncertainty via linear mixed 0-1 prograrnming. International Journal for Numerical Methods in Engineering 2008, 76(3): 253-277.

60. Guo X.*, Yamazaki K., Cheng G. D. A new three-point approximation approach for design optimization problems. International Journal for Numerical Methods in Engineering 2001, 50(4): 869-884.

61. Jin F.*, Tang Q. Q., Guo X., Gao H. J. A generalized Maugis-Dugdale solution for adhesion of power-law graded elastic materials. Journal of the Mechanics and Physics of Solids 2021, 154: 104509.

62. Du Z. L., Zhang G., Guo T. F., Tang S.*, Guo X.* Tension-compression asymmetry at finite strains: A theoretical model and exact solutions. Journal of the Mechanics and Physics of Solids 2020, 143: 104084.

63. Guo X.*, Ma B. B., Zhu Y. C.* A magnification-based multi-asperity (MBMA) model of rough contact without adhesion. Journal of the Mechanics and Physics of Solids 2019, 133: 103724.

64. Zhu Y. C., Li S. S., Du Z. L., Liu C., Guo X.*, Zhang W.S.* A novel asymptotic-analysis-based homogenisation approach towards fast design of infill graded microstructures. Journal of the Mechanics and Physics of Solids 2019, 124: 612-633.

65. Zhu Y. C., Wei Y. H., Guo X.* Gurtin-Murdoch surface elasticity theory revisit: An orbital-free density functional theory perspective. Journal of the Mechanics and Physics of Solids 2017, 109: 178-197.

66. Zhu Y. C., Wang J.*, Xiang Y.*, Guo X.* A three-scale homogenisation approach to the prediction of long-time absorption of radiation induced interstitials by nanovoids at interfaces. Journal of the Mechanics and Physics of Solids 2017, 105: 1-20.

67. Du Z. L., Guo X.* Variational principles and the related bounding theorems for bi-modulus materials. Journal of the Mechanics and Physics of Solids 2014, 73: 183-211.

68. Yang H., Fan F. F., Liang W. T., Guo X., Zhu T., Zhang S. L.* A chemo-mechanical model of lithiation in silicon. Journal of the Mechanics and Physics of Solids 2014, 70: 349-361.

69. Jin F., Guo X.*, Gao H. J. Adhesive contact on power-law graded elastic solids: The JKR-DMT transition using a double-Hertz model. Journal of the Mechanics and Physics of Solids 2013, 61(12): 2473-2492.

70. Guo X.*, Zhang T. A study on the bending stiffness of single-walled carbon nanotubes and related issues. Journal of the Mechanics and Physics of Solids 2010, 58(3): 428-443.

71. Zhang H. W.*, Wang J. B., Guo X.* Predicting the elastic properties of single-walled carbon nanotubes. Journal of the Mechanics and Physics of Solids 2005, 53(9): 1929-1950.

72. Xiang Q., Yang H., K. I. Elkhodary, Qiu H., Tang S.*, Guo X.* A multiscale, data-driven approach to identifying thermo-mechanically coupled laws—bottom-up with artificial neural networks. Computational Mechanics 2022, 70(1): 163-179.

73. Qiu H., Yang H., K. I. Elkhodary, Tang S., Guo X.*, Huang J. H. A data-driven approach for modeling tension–compression asymmetric material behavior: numerical simulation and experiment. Computational Mechanics 2022, 69: 299-313.

74. Mei Y., Deng J. W., Guo X., S. Goenezen, S. Avril.* Introducing regularization into the virtual fields method (VFM) to identify nonhomogeneous elastic property distributions. Computational Mechanics 2021, 67: 1581-1599.

75. Liu C., Du Z. L.*, Zhang W. S., Zhang X. Y., Mei Y., Guo X.* Design of optimized architected structures with exact size and connectivity via an enhanced multidomain topology optimization strategy. Computational Mechanics 2021, 67: 743-762.

76. Yang H., Guo X.*, Tang S.*, Liu W. K. Derivation of heterogeneous material laws via data-driven principal component expansions. Computational Mechanics 2019, 64: 365-379.

77. Li H. Y., Orion L. K., Gao J. Y., Yu C., Nie Y. H., Zhang L., Mahsa T., Tang S., Guo X., Li G., Tang S. Q., Cheng G. D., Liu W.K.* Clustering discretization methods for generation of material performance databases in machine learning and design optimization. Computational Mechanics 2019, 64: 281-305.

78. Du Z. L., Zhang W. S., Zhang Y. P., Xue R. Y., Guo X.* Structural topology optimization involving bi-modulus materials with asymmetric properties in tension and compression. Computational Mechanics 2019, 63: 335-363.

79. Zhang W. S., Li D., Yuan J., Song J. F., Guo X.* A new three-dimensional topology optimization method based on moving morphable components (MMCs). Computational Mechanics 2017, 59: 647–665.

80. Yan J., Guo X.*, Cheng G. D. Multi-scale concurrent material and structural design under mechanical and thermal loads. Computational Mechanics 2016, 57: 437–446.

81. Du Z. L., Jia Y. B., Chung H.*, Zhang Y. P., Li Y., Zhou H., Guo X.* Analysis and optimization of thermoelastic structures with tension–compression asymmetry. International Journal of Solids and Structures, 2022, 254: 111897.

82. Zhou Z. C., Zhu Y. C.*, Luo J., Yang X., Guo X.* Characterisation of dislocation patterning behaviour with a continuum dislocation dynamics model on two parallel slip planes equipped with a deep neural network resolving local microstructures. International Journal of Solids and Structures 2020, 198: 57-71.

83. Jin F., Wan Q., Guo X.* A double-Westergaard model for adhesive contact of a wavy surface. International Journal of Solids and Structures 2016, 102: 66-76.

84. Du Z. L., Zhang Y. P., Zhang W. S., Guo X.* A new computational framework for mechanical with different mechanical responses in tension and compression and its applications. International Journal of Solids and Structures 2016, 100: 54-73.

85. Jin F., Zhang W., Wan Q., Guo X.* Adhesive contact of a power-law graded elastic half-space with a randomly rough rigid surface. International Journal of Solids and Structures 2016, 81: 244-249.

86. Jin F., Zhang W., Zhang S. L., Guo X.* Adhesion between elastic cylinders based on the double-Hertz model. International Journal of Solids and Structures 2014, 51(14): 2706-2712.

87. Jin F., Guo X.* Mechanics of axisymmetric adhesive contact of rough surfaces involving power-law graded materials. International Journal of Solids and Structures 2013, 50(20-21): 3375-3386.

88. Jin F., Guo X.* Mode-mixity-dependent adhesion of power-law graded elastic solids under normal load and substrate stretch-induced mismatch strain. International Journal of Solids and Structures 2012, 49(17): 2349-2357.

89. Guo X.*, Jin F., Gao H. J. Mechanics of non-slipping adhesive contact on a power-law graded elastic half-space. International Journal of Solids and Structures 2011, 48(18): 2565-2575.

90. Jin F., Guo X.* Non-slipping adhesive contact of a rigid cylinder on an elastic power-law graded half-space. International Journal of Solids and Structures 2010, 47(11-12): 1508-1521.

91. Guo X.*, Jin F. A generalized JKR-model for two-dimensional adhesive contact of transversely isotropic piezoelectric half-space. International Journal of Solids and Structures 2009, 46(20): 3607-3619.

92. Guo X.*, Wang J. B., Zhang H. W. Mechanical properties of single-walled carbon nanotubes based on higher order Cauchy–Born rule. International Journal of Solids and Structures 2006, 43(5): 1276-1290.

93. Zhang H. W.*, Zhang S., Guo X., Bi J. Y. Multiple spatial and temporal scales method for numerical simulation of non-classical heat conduction problems: one dimensional case. International Journal of Solids and Structures 2005, 42(3-4): 877-899.

94. Huo W. D., Liu C.*, Du Z. L., Liu Z. Y., Guo X.* Topology optimization on complex surfaces based on the moving morphable components (MMCs) method and computational conformal mapping (CCM). Journal of Applied Mechanics-Transactions of the ASME 2022, 89(5): 051008.

95. Jin F.*, Tang C. Y., Guo X., Bai L. T. Roof deformation and collapse of stamps with isolated grooves: a contact mechanics approach. Journal of Applied Mechanics-Transactions of the ASME 2022, 89(3): 031007.

96. Guo X.*, Du Z. L., Liu C., Tang S. A new uncertainty analysis-based framework for data-driven computational mechanics. Journal of Applied Mechanics-Transactions of the ASME 2021, 88(11): 111003.

97. Mei Y., Du Z. L., Zhao D. M., Zhang W. S., Liu C.*, Guo X.* Moving morphable inclusion approach: an explicit framework to solve inverse problem in elasticity. Journal of Applied Mechanics-Transactions of the ASME 2021, 88(4): 041001.

98. Yang H., Qiu H., Xiang Q., Tang S.*, Guo X.* Exploring elastoplastic constitutive law of microstructured materials through artificial neural network—A mechanistic-based data-driven approach. Journal of Applied Mechanics-Transactions of the ASME 2020, 87(9): 091005.

99. Lei X., Liu C.*, Du Z. L., Zhang W. S., Guo X.* Machine learning-driven real-time topology optimization under moving morphable component-based framework. Journal of Applied Mechanics-Transactions of the ASME 2019, 86(1): 011004.

100. Jin F.*, Guo X., Wan Q. Plane contact and adhesion of two elastic solids with an interface groove. Journal of Applied Mechanics-Transactions of the ASME 2018, 85(4): 041002.

101. Liu C., Du Z. L., Zhang W. S., Zhu Y. C., Guo X.* Additive manufacturing-oriented design of graded lattice structures through explicit topology optimization. Journal of Applied Mechanics-Transactions of the ASME 2017, 84(8): 081008.

102. Zhang W. S., Yang W. Y., Zhou J. H., Li D., Guo X.* Structural topology optimization through explicit boundary evolution. Journal of Applied Mechanics-Transactions of the ASME 2017, 84(1): 011011.

103. Jin F.*, Guo X., Wan Q. Revisiting the maugis-dugdale adhesion model of elastic periodic wavy surfaces. Journal of Applied Mechanics-Transactions of the ASME 2016, 83(10): 101007.

104. Zhang W. S., Zhang J., Guo X.* Lagrangian description based topology optimization-a revival of shape optimization. Journal of Applied Mechanics-Transactions of the ASME 2016, 83(4): 041010.

105. Jin F., Wan Q., Guo X.* Plane contact and partial slip behaviors of elastic layers with randomly rough surfaces. Journal of Applied Mechanics-Transactions of the ASME 2015, 82(9): 091006.

106. Guo X.*, Zhang W. S., Zhong W. L. Doing Topology optimization explicitly and geometrically-a new moving morphable components based framework. Journal of Applied Mechanics-Transactions of the ASME 2014, 81(8): 081009.

107. Zhang W., Jin F., Zhang S. L., Guo X.* Adhesive contact on randomly rough surfaces based on the double-Hertz model. Journal of Applied Mechanics-Transactions of the ASME 2014, 81(5): 051008.

108. Jin F., Guo X.*, Zhang W. A unified treatment of axisymmetric adhesive contact on a power-law graded elastic half-space. Journal of Applied Mechanics-Transactions of the ASME 2013, 80(6): 061024.

109. Liu D. P., Yang H., Elkhodary K. I., Tang S., Guo X.* Cyclic softening in nonlocal shells—A data-driven graph-gradient plasticity approach. Extreme Mechanics Letters, 2023, 60: 101995.

110. Dong Z. C., Guo X.*, Zhu Y. C.* Origami discovery by means of digital resources. Extreme Mechanics Letters, 2022, 57: 101916.

111. Huang M. C., Du Z. L.*, Liu C.*, Zheng Y. G., Cui T. C., Mei Y., Li X., Zhang X. Y., Guo X.* Problem-independent machine learning (PIML)-based topology optimization—A universal approach. Extreme Mechanics Letters, 2022, 56: 101887.

112. Chen J., Yang H., Elkhodary K. I., Tang S., Guo X.* G-MAP123: A mechanistic-based data-driven approach for 3D nonlinear elastic modeling—Via both uniaxial and equibiaxial tension experimental data. Extreme Mechanics Letters, 2022, 50: 101545.

113. Luo J. C., Du Z. L.*, Liu C.*, Mei Y., Zhang W. S., Guo X. Moving Morphable Components-based inverse design formulation for quantum valley/spin hall insulators. Extreme Mechanics Letters, 2021, 45: 101276.

114. Gao B., Li Y., Guo T. F., Guo X.*, Tang S.* Void nucleation in alloys with lamella particles under biaxial loadings. Extreme Mechanics Letters, 2018, 22: 42-50.

115. Qiu H., Li Y., Guo T. F., Guo X.*, Tang S.* Deformation and pattern transformation of porous soft solids under biaxial loading: Experiments and simulations. Extreme Mechanics Letters, 2018, 20: 81-90.

116. Xue R. Y., Li R., Du Z. L.*, Zhang W. S., Zhu Y. C., Sun Z., Guo X.* Kirigami pattern design of mechanically driven formation of complex 3D structures through topology optimization. Extreme Mechanics Letters, 2017, 15: 139-144.

117. Yang H., Liang W. T., Guo X., Wang C., Zhang S. L.*, Strong kinetics-stress coupling in lithiation of Si and Ge anodes. Extreme Mechanics Letters, 2015, 2: 1-6.

118.  赵康郭旭*, 丁佳基于拓扑描述函数的特定性能复合材料设计力学学报 2005, 37 (5), 586-592.

119.  郭旭*, 赵康基于拓扑描述函数的连续体结构拓扑优化方法力学学报 2004, 36 (5), 520-526.

120.  郭旭顾元宪赵康广义变分原理的结构形状优化伴随法灵敏度分析力学学报 2004, 36 (3), 288-295.

121.  郭旭*, 赵康拓扑相关荷载作用下结构拓扑优化的水平集方法工程力学 2005, 22 (5), 69-77.

122.  郭旭王晋宝张洪武基于高阶Cauchy-Born准则的单壁碳纳米管本构模型计算力学学报 2005, 22 (2), 135-140.