在Phys. Rev. Lett., Smart Mater. Struct., Adv. Funct. Mater., Sci. Bullet., 等国内外学术期刊上发表论文40余篇。

期刊论文目录：

[43] Hongxing Shang, Huiting Dong, Xu Liang (*), Feng Deng, Shuling Hu, Shengping Shen (*). 2024. Evolution of flexoelectric polar patterns in wrinkled thin films. 

[42] Wensi Xing, Hongyu Cao, Xin Zhang, Xu Liang, Jianwei Song, Shengping Shen. 2024.  Enhanced flexoelectricity in barium titanate-cellulose composite thin films (Submited).

[41] Lianmeng Si, Yihan Wu, Hong Xiao, Wensi Xing, Rui Song, Sha Wang, Xu Liang, Wenshan Yu (*), Jianwei Song (*), Shengping Shen. 2023.  A Superstable, Flexible, and Scalable Nanofluidic Ion Regulation Composite Membrane. Science Bulletin, 68(20): 2344-2353.

[40] Hongxing Shang, Xu Liang (*), Feng Deng, Shuling Hu, Shengping Shen (*). 2024. Mechanical control of polar patterns in wrinkled thin films via flexoelectricity, Physical Review Letters, 132: 116201.

[39] Feng Deng, Wenshan Yu, Xu Liang, Shengping Shen(*). 2023. The existence and uniqueness theorem for linear flexoelectricity and application to the Galerkin approximation. Mathematics and Mechanics of Solids, 28(10):2278-2299. 

[38] Feng Deng, Wenshan Yu, Xu Liang, Shengping Shen(*). 2023. A mixed finite element method for large deformation of flexoelectric materials. Applied Mathematical Modelling, 118: 303-321.

[37] Hongxing Shang, Xu Liang(*), Feng Deng(*), Shuling Hu, Shengping Shen. 2022. Flexoelectricity in wrinkled thin films. International Journal of Mechanical Science, 234(15): 107685.

[36] Mengdie Lan, Wenjun Yang, Xu Liang(*), Shuling Hu, Shengping Shen. 2022. Vibration modes of flexoelectric circular plate. Acta Mechanica Sinica, 38: 422063.

[35] Xu Liang, Yiwen Yu, Ruijia Liu, Wenyuan Liu, Shengping Shen (*). 2022. Flexoelectricity in periodically poled lithium niobate by PFM. Journal of Physics D: Applied Physics, 55: 335303.

[34] Xiao-xiao Liu (*), Xu Liang. 2022. Global sensitivity analysis of electromechanical coupling behaviors for flexoelectric nanostructures. International Journal of Mechanics and Materials Design, 18, 21-37.

[33] 梁旭（*），尚红星，邓谦，胡淑玲，申胜平；2021，固体电介质中的挠曲电效应。固体力学学报，41（1）：33-44。

[32] Chen W H., Liang X(*)., Shen S P., 2021. Forced vibration of piezoelectric and flexoelectric Euler-Bernoulli beams by dynamic Green functions. Acta Mechnica, 232:449-460.

[31] Deng Q., Lv S H., Li Z Q., Tan K., Liang X., Shen S P(*)., 2020. The impact of flexoelectricity on materials, devices, and physics. Journal of  Applied Physics, 128: 080902(Online).

[30] 陈春林，李肇奇，梁旭（*），胡淑玲，申胜平，2020，悬臂梁挠曲电俘能器的力电耦合模型及性能分析。固体力学学报，41(2)：159-169。

[29] 陈春林，梁旭（*），胡淑玲，申胜平，2019，聚偏氟乙烯薄膜挠曲电效应的实验研究。实验力学，35(5): 738-746。

[28] Yang W J., Liang X(*)., Deng Q., Shen S P(*) 2020. Rayleigh wave propagation in a homogeneous centrosymmetric flexoelectric half-space. Ultrasonics 103: 106105.

[27] Chen Min et al.,...Liang X.,...Xia W J(*)., Wang X F(*).,  2019. Superhydrophobic Surface with Controllable Adhesion for Anti-Roof-Collapse Application in Flexible Microfluidics. Advanced Materials Interfaces 1901178.(online)

[26] Guo Q L., Koo J., Xie Z Q.,...Liang X.,...Huang Y G., Rogers J(*).,  2019. A Bioresorbable Magnetically Coupled System for Low-Frequency Wireless Power Transfer. Advanced Functional Materials, 1905451.(online)

[25] Lu J F., Liang X(*)., Yu W S., Hu S L., Shen S P(*)., 2019. Temperature dependence of flexoelectric coefficient for bulk polymer polyvinylidene fluoride. Journal of Physics D-Applied Physics, 52: 075302.

[24] Yang W J., Deng Q., Liang X(*)., Shen S P(*)., 2018. Lamb wave propagation with flexoelectricity and strain gradient elasticity considered. Smart Materials and Structures, 27: 085003.

[23] Yang W J., Hu T T., Liang X(*)., Shen S P(*)., 2018. On band structures of layered phononic crystals with flexoelectricity. Archive of Applied Mechanics, 88: 629-644.

[22] Yu P F., Chen J Y., Wang H L.,  Liang X(*)., Shen S P(*)., 2018. Path-independent integrals in electromechanical systems with flexoelectricity. International Journal of Solids and Structures, 147: 20-28.

[21] Hu T T., Yang W J., Liang X(*)., Shen S P(*)., 2017. Wave propagation in Flexoelectric Microstructure Solids. Journal of Elasticity, 130: 197-210.

[20] Liang X., Zhang R Z., Hu S L., Shen S P(*)., 2017. Flexoelectric energy harvesters based on Timoshenko laminated beam theory. Journal of Intelligent Material Systems and Structures, 28: 2064-2073.

[19] Yang W J., Liang X(*)., Shen S P(*)., 2017. Love waves in layered flexoelectric structures. Philosophical Magazine, 97: 3186-3209.

[18] Hu T T., Deng Q., Liang X(*)., Shen S P(*)., 2017. Measuring the flexoelectric coefficient of bulk barium titanate from a shock wave experiment. Journal of Applied Physics, 122: 055106.

[17] Liang X., Hu S L., Shen S P(*)., 2017. Nanoscale mechanical energy harvesting using piezoelectricity and flexoelectricity. Smart Materials and Structures, 26: 035020. (China Top Cited Author Award)

[16] Zhang R Z., Liang X., Shen S P(*)., 2016. A Timoshenko dielectric beam model with flexoelectric effect. Meccanica, 51: 1181-1188.

[15] Liang X., Yang W J., Hu S L., Shen S P(*)., 2016. Buckling and vibration of flexoelectric nanofilms subjected to mechanical loads. Journal of Physics D-Applied Physics, 49: 115307. (China Top Cited Author Award)

[14] Zhang S W., Xu M L(*).,  Ma G L., Liang X., Shen S P(*)., 2016. Experimental method research on transverse flexoelectric response of poly(vinylidene fluoride). Japanese Journal of Applied Physics, 55: 071601.

[13] Lu J F., Lv J Y.,  Liang X(*)., Xu M L., Shen S P(*)., 2015. Improved approach to measure the direct flexoelectric coefficient of bulk polyvinylidene fluoride. Journal of Applied Physics, 119: 094104.

[12] Yang W J., Liang X(*)., Shen S P(*)., 2015. Electromechanical response of piezoelectric nanoplates with flexoelectricity. Acta Mechanica, 226: 3097-3110.

[11] Lu J F., Liang X(*)., Hu S L(*)., 2015. Flexoelectricity in Solid Dielectrics: From Theory to Applications. CMC-Computer, Mechanics and Continua, 45(3): 145-162. 

[10] Zhang S W., Xu M L(*)., Liang X., Shen S P., 2015. Shear flexoelectric response mu(1211) in polyvinylidene fluoride. Journal of Applied Physics, 117: 204102. 

[9] Zhang S W., Liang X., Xu M L(*)., Feng B., Shen S P., 2015. Shear flexoelectric response along 3121 direction in polyvinylidene fluoride. Applied Physics Letters, 107: 142902. 

[8] Liang X., Hu S L., Shen S P(*)., 2015. Size-dependent buckling and vibration of piezoelectric nanostructures due to flexoelectricity. Smart Materials and Structures, 24: 105012. 

[7] Liang X., Hu S L., Shen S P(*)., 2015. Surface effects on the post-buckling of piezoelectric nanowires. Physica E-Low-Dimensional Systems & Nanostructures, 69: 61-64. 

[6] Liang X., Hu S L., Shen S P(*)., 2014. Effects of surface and flexoelectricity on a piezoelectric nanobeam. Smart Materials and Structures, 23: 035020. 

[5] Liang X., Shen S P(*)., 2013. Size-dependent piezoelectricity and elasticity due to the electric field-strain gradient coupling and strain gradient elasticity. International Journalof Applied Mechanics, 5(2): 1350015.

[4] Liang X., Hu S L., Shen S P(*)., 2013. A new Bernoulli-Euler beam model based on a simplified strain gradient elasticity theory and its applications. Composite Structures, 111: 317-323. 

[3] Liang X., Hu S L., Shen S P(*)., 2013. Bernoulli-Euler Dielectric Beam Model Based on Strain-Gradient Effect. Journal of Applied Mechanics-Transactions of the ASME, 80(4): 044502. 

[2] Liang X., Shen S P(*)., 2013. Dynamic analysis of Bernoulli-Euler piezoelectric nanobeam with electrostatic force. Science China-Physics Mechanics & Astronomy, 56(10): 1930-1937.

[1] Liang X., Shen S P(*)., 2012. Effect of electrostatic force on a piezoelectric nanobeam. Smart Materials and Structures, 21: 015001.