Publications

出版书籍

  1. Liu Z.S., Frontiers in Applied Mechanics, Imperial College Press, (2014) UK, Singapore. ISBN 978-1-78326-683-8.
  2. Liu Z.S., Ng T.Y. and Feng X.Q., Proceedings of Frontiers in Applied Mechanics, Research Publishing, (2015), Singapore. ISBN 9-789810-962784.
  3. Ng T.Y., Joshi S.C., Yeo J.J. and Liu Z.S. (2016) Effects of Nano Porosity on the Mechanical Properties and Applications of Aerogels in Composite Structures, Advances in Nanocomposites, Springer. ISBN: 978-3-319-31660-4.
  4. Yeo J.J., Liu Z.S. and Ng T.Y. (2018) Molecular Dynamics Modeling of Silica Aerogels, Handbook of Materials Modeling. Volume 2 Applications: Current and Emerging Materials, Springer. ISBN: 978-3-319-44679-0.
  5. Liu Z.S., He J.Y. Frontiers in Applied Mechanics, Research Publishing, (2018), Singapore. ISBN 978-981-11-2729-8.
  6. Guirong Liu, Zishun Liu, Proceedings of APCOM2013 & ISCM2013 Conference, December 11-14 2013, Singapore, ST eBooks, ScienTech Publisher, 2020,09,15.
  7. Liu Z.S., Fang D.N. Frontiers in Applied Mechanics, Research Publishing, (2020), Singapore. ISBN 978-981-14-7514-6.
  8. Liu Z.S., Zheng S.J., Li Z.Q., Xu S., Lei J.C. Toh W., Multiscale modeling of hydrogels, The Mechanics of Hydrogels, Elsevier, (2022) ISBN 978-0-08-102862-9.
  9. 刘子顺,雷金成,徐帅,郑守靖,李子谦,《软物质力学:水凝胶大变形》,西安交通大学出版社,(2022, 03), 西安. ISBN 978-7-5693-2485-3.
  10. Liu Z.S., Fundamentals of Continuum Mechanics, “Quality Graduate Teaching Materials for the 14th Five-year Plan of Xi'an Jiaotong University”, World Scientific, (2024). ISBN: 9789811283789.
    Liu Z.S., Li R.F., He X.D., Zhu Z.H., Advances and Challenges in Advanced Unmanned Aerial Systems, Springer, Singapore, (2024) ISBN:978-981-99-8044-4.

 

发表论文

 

2024:

  1. J.A. Zhu, Xue Y.H., Liu Z.S., A transfer learning enhanced physics-informed neural network for parameter identification in soft materials, Applied Mathematics and Mechanics, Volume 45, DOI: https://doi.org/10.1007/s10483-024-3178-9.
  2. R Huang, Z Liu. (2014), The effect of swelling/deswelling cycles on the mechanical behaviors of the polyacrylamide hydrogels, Polymer, Volume 312. DOI: https://doi.org/10.1016/j.polymer.2024.127634.
  3. H Li, J Lei, D Wang, Z Liu. (2024), The fracture and toughening mechanism of double-network hydrogel using the network mechanics method, Engineering Fracture Mechanics, volume 309. DOI: 10.1016/j.engfracmech.2024.110413.
  4. Xue Y.H., Liu Z.S. and Reddy J.N. (2024), A three-fields coupled numerical framework for transient deformation of thermo-sensitive hydrogel, Int. Journal for Numerical Methods in Engineering, nme7550. DOI: 10.1002/nme.7550 .
  5. You J.P. and Liu Z.S. (2024), Revealing Novel Insights into the Toughening Mechanism of Double Network Hydrogels via Uniaxial Tensile Tests, Journal of the Mechanics and Physics of Solids, Vol. 190. DOI: 10.1016/j.jmps.2024.105710.
  6. Wang C.Y., Wang D.Y. and Liu Z.S. (2024), Vibration Suppression Control Methods for Two-Link Flexible Manipulators, Int. Journal of Computational Materials Science and Engineering. DOI 10.1142/S2047684124500209 .
  7. Lin R.J., Xu S. and Liu Z.S. (2024), A visco-hyperelastic model for hydrogels with different water content and its finite element implementation, International Journal of Solids and Structures, Vol. 293, 112761. DOI: 10.1016/j.ijsolstr.2024.112761.
  8. Zhou Z.D., Jia Y.T., Lu W.J., Lei J.C. and Liu Z.S. (2024), Enhancing the crack initiation resistance of hydrogels through crosswise cutting, Journal of the Mechanics and Physics of Solids, Vol. 183, 105516. DOI: 10.1016/j.jmps.2023.105516. 215.
  9. Sebaq M. H. and Liu Z.S. (2024), Energy absorption and vibration mitigation performances of novel 2D auxetic metamterials, Int. Journal of Computational Materials Science and Engineering, Vol. 12(4), 2350022. DOI: 10.1142/S2047684123500227.
  10. Jiang H.L., Lei J.C. and Liu Z.S. (2024), Deformation Mechanism of the Dual Thermo-sensitive Hydrogel Bilayer Structure, Smart Materials and Structures, Vol. 33, DOI: 10.1088/1361-665X/ad5944.
  11. Lei J.C. and Liu Z.S. (2024), A chain scission-induced anisotropic damage constitutive model for double network hydrogels, Int. Journal of Applied Mechanics, Vol. 16 (6).

2023:

  1. Xue Y.H., Zhou Z.D., Lei J.C. and Liu Z.S. (2023), A constitutive model of water-triggered shape memory hydrogels and its finite element implementation, Journal of Applied Mechanics, Vol. 90(7) 071005.  DOI: 10.1115/1.4056912.
  2. Sebaq M. H. and  Liu Z.S.  (2023), Energy absorption and vibration mitigation performances of novel 2D auxetic metamterials, Int. Journal of Computational Materials Science and Engineering, Vol. 12(4),  DOI: 10.1142/S2047684123500227.
  3. Zhang Y.Y., Guo M.Y., Li G.P., Chen X.L., Liu Z.S., Shao J.Y., Huang Y.A., He G. (2023), Ultrastable Viologen Ionic Liquids-based Ionogels for Visible Strain Sensor Integrated with Electrochromism, Electrofluorochromism and Strain Sensing, CCS Chemistry, Vol. 5(8), 1917–1930.  DOI: 10.31635/ccschem.022.202202310.
  4. Wang D.Y., Luo X.Y. Liu Z.S. and  Stewart P., (2023), Flow-induced surface instabilities in a flexible-walled channel with a heavy wall, Journal of Fluid Mechanics, Vol. 956. PII S0022112022010862. DOI: 10.1017/jfm.2022.1086.
  5. Xu S., Zhou Z.D., Liu Z.S. and Sharma P.   (2023), Concurrent stiffening and softening in hydrogels under dehydration, Science Advances, Vol. 9(1) eade3240.  DOI: 10.1126/sciadv.ade3240.
  6. Hu J.Y., Li H., Du J.K., Liu Z.S., Carrera E. (2023), Inhomogeneous large deformation of magneto-thermal sensitive hydrogel-based composite structures, Mechanics of Advanced Materials and Structures, DOI:10.1080/15376494.2023.2231442.
  7. He LC, Ye H.L., Sun Q.M., Tieu AJK; Lu L., Liu Z.S.,  Adams S. (2023) In situ curing enables high performance all-solid-state lithium metal batteries based on ultrathin-layer solid electrolytes, Energy Storage Materials, Vol. 60, 102838, DOI 10.1016/j.ensm.2023.102838.
  8. Xu S. and Liu Z.S., (2023) A Deformation-Diffusion-Coupled Constitutive Theory for Hydrogels by Considering the Preparation Conditions, International Journal of Applied Mechanics, V15 (8), 2350062. DOI: 10.1142/S175882512350062X.

2022:

  1. Zheng S.J., Huang R., lin R.J. and Liu Z.S. (2022), A phase field solution for modelling hyperelastic material and hydrogel fracture in ABAQUS, Engineering Fracture Mechanics,  108894.  DOI: 10.1016/j.engfracmech.2022.108894.
  2. Jia Y.T., Zhou Z.D., Jiang H.L. and Liu Z.S. (2022), Characterization of fracture toughness and damage zone of double network hydrogels, Journal of the Mechanics and Physics of Solids,  Vol. 169, 105090.  DOI: 10.1016/j.jmps.2022.105090.
  3. Toh W., Ang E. Y.M., Ng T.Y., Lin R.M., and Liu Z.S. (2022), Antifouling Bilayer Graphene Slit Membrane for Desalination of Nanoplastic-Infested Seawater: A Molecular Dynamics Simulation Study, ACS Applied Materials & Interfaces, 14 (38), 43965–43974, DOI: 10.1021/acsami.2c12638.
  4. Lei J.C. and Liu Z.S. (2022), A Network Mechanics Method to Study the Mechanism of the Large-deformation Fracture of Elastomers, Journal of Applied Physics,     132 (13), DOI: 10.1063/5.0106445.
  5. Toh W., Ang E. Y.M., Lin R.M., Liu Z.S. and Ng T.Y. (2022), On the Performance of Vertically Aligned Graphene Array Membranes for Desalination, ACS Applied Materials & Interfaces,     14(23), 27405−27412, DOI: 10.1021/acsami.2c05425.
  6. Chen C., Wang D.Y., Lei J.C. and Liu Z.S. (2022), A Locally Resonant Phononic Crystal Structure with Low-frequency Broad Bandgap, Int. Journal of Computational Materials Science and Engineering, Vol. 11(4),  2250012, DOI: 10.1142/S2047684122500129.
  7. Zhou Z.D., Lei J.C. and Liu Z.S. (2022), Effect of water content on physical adhesion of polyacrylamide hydrogels, Polymer,  Vol.246, 124730. DOI: 10.1016/j.polymer.2022.124730.
  8. Xue Y.H., Lei J.C. and Liu Z.S. (2022), A Thermodynamic Constitutive Model for Shape Memory Polymers Based On Phase Transition, Polymer,  Vol.243, 124623. DOI:  10.1016/j.polymer.2022.124623.
  9. Chen C., Lei J.C. and Liu Z.S. (2022), A Ternary Seismic Metamaterial for Low Frequency Vibration Attenuation, Materials,  15, 1246. DOI:    10.3390/ma15031246
  10. Zheng S.J., Cohen N. and Liu Z.S. (2022), Large Deformation Adhesion Study of Polymetric Hydrogel under Different Stimuli, Mechanics of Materials,  Vol.165, 104174. DOI:  10.1016/j.mechmat.2021.104174.
  11. Yu Y.F., Zhang X., Yin S.W., Bai L.C. and Liu Z.S. (2022), The sp2-sp3 transition and shear slipping dominating the compressive deformation of diamond-like carbon, Journal of Non-Crystalline Solids,  Vol.577, 121318. DOI: 10.1016/j.jnoncrysol.2021.121318.

2021:

  1. Zheng S.J. and Liu Z.S.  (2021), The Machine Learning Embedded Method of Parameters Determination in the Constitutional Models and Potential Applications for Hydrogels, International Journal of Applied Mechanics, Vol. 13(1), 2150001.  DOI: S1758825121500010.  pdf
  2. Vengatachalam B., Huang R., Poh L.H., Liu Z.S., Qin Q.H. and Swaddiwudhipong S.  (2021), Initial yield behaviour of closed-cell aluminium foams in biaxial loading, International Journal of Mechanical Sciences, Vol. 191, 106063.  DOI: 10.1016/j.ijmecsci.2020.106063.
  3. Lei J.C., Li Z.Q., Xu S. and Liu Z.S.  (2021), Recent Advances of Hydrogel Network Models for Studies on Mechanical Behaviors, Acta Mechanica Sinica, Vol. 37.  DOI: 10.1007/s10409-021-01058-2. pdf
  4. Jia Y.R., Han L.Z., Lei J.C. and Liu Z.S.  (2021), Study on the Equivalent Properties of Nonlinear Periodic Heterogeneous Composite Plates Using the Structural Genome Approach, 利用结构基因法研究非线性周期性板结构的等效力学性能《计算力学学报》Chinese Journal of Computational Mechanics, Vol. 38(5),  631-637. DOI: 10.7511/jslx20200729003.  
  5. Han L.Z., Lei J.C., Liu Z.S. and Lee H.P. (2021), Prediction of Mechanical and Thermal Properties of Particle Reinforced Hydrogel Composites Using THE Structural Genome Approach, Int. Journal of Computational Materials Science and Engineering, Vol. 10(1), 2150004, DOI: 10.1142/S2047684121500044.
  6. Lei J.C., Li Z,Q., Xu S. and Liu Z.S. (2021), A Mesoscopic Network Mechanics Method to Reproduce the Large Deformation and Fracture Process of Cross-linked Elastomers, Journal of the Mechanics and Physics of Solids,  Vol. 156, 104599.  DOI: 10.1016/j.jmps.2021.104599.
  7. Hu J.Y., Toh W., Ng T.Y., Jiang N., Zeng L.S., Du J.K. Liu Z.S. (2021), Inhomogeneous large deformation study on magneto-thermal sensitive hydrogels, International Journal of Applied Mechanics, Vol. 13(5), 2150053.  DOI: 10.1142/S1758825121500538.
  8. Zhang B.J., Yang X.D., He B., Wang Q.Q. Liu Z.S., Yu D.M., He G. (2021), Thionated benzo thiophen-1(3H)-one as an organic cathode with high capacity for sulfur-rich all organic lithium-ion batteries, Journal of Materials Chemistry A,  DOI: 10.1039/d1ta03045k.
  9. Selim B.A. and Liu Z.S. (2021), Impact analysis of functionally-graded graphene nanoplatelets-reinforced composite plates laying on Winkler-Pasternak elastic foundations applying a meshless approach, Engineering Structures, Vol. 241, 112453. DOI: 10.1016/j.engstruct.2021.112453.
  10. Xie C.H., Wu Y. and Liu Z.S. (2021) An electromechanical cohesive zone model merging with contact and friction effects for fiber debonding and pushing-out in piezoelectric fiber composites, Applied Mathematical Modelling, Vol.951-21.  DOI: 10.1016/j.apm.2021.01.048.
  11. Wang L.F., Feng P.H., Xing X.G., Wu Y. and Liu Z.S.  (2021) A one-dimensional constitutive model for NiTi shape memory alloys considering inelastic strains caused by the R-phase transformation, Journal of Alloys and Compounds, Vol.  858, 159192. DOI: 10.1016/j.jallcom.2021.159192.
  12. Zhu J.A., Jia Y.T., Lei J.C. and Liu Z.S. (2021), Deep Learning Approach to Mechanical Property Prediction of Single-Network Hydrogel, Mathematics,  Vol. 9, 2804.  DOI: 10.3390/math9212804.
  13. Tang J.D., Zeng L.S., and Liu Z.S. (2021), Fabrication of Patterned Magnetic Hydrogels by Ion Transfer Printing, Soft Matter,  Vol. 17, 8059-8067.  DOI: 10.1039/D1SM00869B.

2020:

  1. Lei J.C., Xu S., Li Z.Q. and Liu Z.S.,  (2020), Study on Large Deformation Behavior of Polyacrylamide Hydrogel Using Dissipative Particle Dynamics, Frontiers in Chemistry,Vol. 8: 115,  doi: 10.3389/fchem.2020.00115.
  2.  Toh W., Ang Elisa Y.M., Ng T.Y., Lin R.M., Liu Z.S.,  (2020), Nanopumping of Water via Rotation of Graphene Nanoribbons, Nanotechnology. Vol. 31(17),. 175704, DOI: 10.1088/1361-6528/ab6ab6.
  3. Selim B. A., Liu Z.S. and Liew K.M. (2020), Active control of functionally graded CNT-reinforced composite plates with piezoelectric layers subjected to impact loading, Journal of Vibration and Control, Vol. 26(7-8), 581-598, DOI: 10.1177/1077546319889849 .
  4. Li Z.Q., Liu Z.S., Ng T.Y., Sharma P.  (2020) The effect of water content on the elastic modulus and fracture energy of hydrogel Article reference, Extreme Mechanics Letters, Vol.35, 100617  DOI: 10.1016/j.eml.2019.100617.
  5. Huang R., Zheng S.J. L, Liu Z.S. and Ng T.Y.,  (2020), Recent Advances of the Constitutive Models of Smart Materials- Hydrogels and Shape Memory Polymers, International Journal of Applied Mechanics, Vol. 12(2), 2050014. DOI: 10.1142/S1758825120500143.(pdf).
  6. Ang Y.M., Ng T.Y., Yeo J.J., Lin R.M., Liu Z.S. and Geethalakshmi, K. R. (2020), Investigations on Different Two-Dimensional Materials as Slit Membranes for Enhanced Desalination, Journal of Membrane Science, Vol.598, 117653. DOI: 10.1016/j.memsci.2019.117653.
  7. Toh W., Ang Elisa Y.M., Yeo J.J., Lin R.M., Liu Z.S.,  Geethalakshmi, K. R., Ng T.Y.  (2020), A Review on Low dimensional Carbon Desalination and Gas Separation Membrane Designs, Journal of Membrane Science, Vol. 598, 117785. DOI: 10.1016/j.memsci.2019.117785
  8. Liu R.X., Xu S., Luo X.Y. and Liu Z.S., (2020), Theoretical and numerical analysis of mechanical behaviors of a metamaterial-based shape memory polymer stent, Polymers, Vol.12(8), 1784. DOI:10.3390/polym12081784.   
  9. Wang L.F., Feng P.H., Wu Y. and Liu Z.S., (2020), A temperature-dependent model of shape memory alloys considering tensile-compressive asymmetry and the ratchetting effect, Materials, Vol.13, 3116. DOI: 10.3390/ma13143116.   
  10. Xu S. and Liu Z.S., (2020), Coupled theory for transient responses of conductive  hydrogels with multi-stimuli, Journal of the Mechanics and Physics of Solids, Vol. 143, 104055. DOI: 10.1016/j.jmps.2020.104055. 
  11. Li Z.Q. and Liu Z.S.,  (2020), The elongation-criterion for fracture toughness of hydrogels based on percolation model, Journal of Applied Physics, Vol.127(21)  215101,  DOI: 10.1063/5.0009626.
  12. Li Y.X., Liu R.X., Liu Z.S. and Swaddiwudhipong S., (2020), 3D phase-evolution-based thermomechanical constitutive model of shape memory polymer with finite element implementation, Journal of Mechanics of Materials and Structures, Vol.  15(3), 291-306. DOI: 10.2140/jomms.2020.15.291. 
  13. Huang R., Xue Y.H., Li Z.J. and Liu Z.S., (2020), The programmable spiral and helical deformation behaviors of the hydrogel-based bi-material beam structures, International Journal of Structural Stability and Dynamics, Vol. 20(13) article No. 2041010.  DOI: 10.1142/S0219455420410102.  
  14. Sha Z.D., Lin W.H., Poh L.H., Xing G.C., Liu Z.S., Wang T.J., Gao H.J. (2020), Fatigue of metallic glasses, Applied Mechanics Reviews, Vol.72(5), 050801 DOI: 10.1115/1.4048056. 
  15. Toh W., Ang Elisa Y.M., Ng T.Y. Lin R.M. and Liu Z.S.  (2020), An investigation on the effects of nanoplastic particles on nanoporous graphene membrane desalination, Desalination, Vol. 496, 114765, DOI: 10.1016/j.desal.2020.114765.  
  16. Zhang B.J., Zhang Y.Y., Yang X.D., Li G.P., Zhang S.K., Zhang Y.F., Liu Z.S. He G.  (2020), Isometric Thionated Naphthalene Diimides As Organic Cathodes for High Capacity Lithium Batteries, Chemistry of Materials, Vol.32(24), 10575–10583.    

2019:

  1. Aphinyan S. Ang Elisa Y.M., Yeo, J.J., Ng, T.Y., Lin, R.M., Liu, Z.S., Rangaswamy G. K. (2019), Many-Body Dissipative Particle Dynamics Simulations of Nano-Droplet Formation in 3D Nano-Inkjet Printing, Modelling and Simulation in Materials Science and Engineering, Vol.27 (5), 055005. DOI: 10.1088/1361-651X/ab1d43.
  2. Xie Cihang, Ying Wu and Liu Z.S., (2019), Stress Fields and Effective Modulus of Piezoelectric Fiber Composite with Arbitrary Shaped Inclusion under In-plane Mechanical and Anti-plane Electric Loadings, Mathematics and Mechanics of Solids, DOI: 10.1177/1081286519840685.
  3. Zheng S.J., Li Z.Q. and Liu Z.S., (2019), The Inhomogeneous Diffusion of Chemically Crosslinked Polyacrylamide Hydrogel Based on Poroviscosity Theory, Science China Technological Sciences, DOI: 10.1007/s11431-018-9472-2. 
  4. Xu S and Liu Z.S., (2019), A nonequilibrium thermodynamics approach to the transient properties of hydrogels, Journal of the Mechanics and Physics of Solids, Vol. 127, 94-110. DOI 10.1016/j.jmps.2019.03.008.
  5. Rangaswamy G. K., Ang Elisa Y.M., Yeo, J.J., Lin R.M., NG T.Y., and Liu Z.S., (2019), Carbon Nanotube Arrays as Multilayer Transverse Flow Carbon Nanotube Membrane for Efficient Desalination, Journal of Membrane Science,    V581, 383-392.  
  6. Wang Y., Lei J.C. and Liu Z.S., (2019), Molecular Dynamics Study on the Anisotropic Poisson's Ratio of the Graphene, Diamond and Related Materials, Vol.93, 66-74. 10.1016/j.diamond.2019.01.026.
  7. Liu R.X., McGinty S., Cui F.S., Luo X.Y., Liu Z.S., (2019), Modelling and Simulation of the Expansion of a Shape Memory Polymer Stent, Engineering Computations, DOI 10.1108/EC-10-2018-0462.
  8. Liu R.X., Li Y.X. and Liu Z.S., (2019), Experimental study on thermo-mechanical behavior of a thermosetting shape memory polymer. Mechanics of Time-Dependent Materials, Vol.23. DOI: 10.1007/s11043-018-9377-0. [PDF]
  9. Pan Z.Z., Huang R. and Liu Z.S., (2019), Prediction of the thermomechanical behavior of particle reinforced shape memory polymers. Polymer Composites, 40(1), 353-363. DOI: 10.1002/pc.24658.[PDF]  
  10. Zhou Y., Hu J.Y. and Liu Z.S., (2019), Deformation Behavior of Fiber-Reinforced Hydrogel Structures, International Journal of Structural Stability and Dynamics,  Vol.19, No.3, 1950032. DOI: 10.1142/S0219455419500329.
  11. Ang Elisa Y. M., Ng T.Y., Liu Z.S. Lin R.M., Yeo J.J. and Rangaswamy K. (2019), Effects of Oscillating Pressure on Desalination Performance of Transverse Flow CNT Membrane. Desalination, Vol.451 35-44. DOI: 10.1016/j.desal.2018.03.029.[PDF]
  12. Yang X.D., Zhang B.J., Zhang S.K., Li G.P., Xu L.T., Wang Z.J., Li P.F., Zhang Y.F., Liu Z.S. and He G. (2019), The Marriage of Carborane with Chalcogen Atoms: Non-Conjugation, σ-π Conjugation and Intramolecular Charge Transfer, Organic Letters, (Accepted).
  13. Wang L.F., Feng P.H., Wu Y. and Liu Z.S. (2019), A tensile-compressive asymmetry model for shape memory alloys with a redefined martensite internal variable, Smart Materials and Structures, (Accepted). 
  14. Li Z.J., Huang R. and Liu Z.S. (2019), A Periodic Deformation Mechanism of a Soft Actuator for Crawling and Grasping, Advanced Materials Technologies, DOI: 10.1002/admt.201900653.
  15. Selim B. A., Liu Z.S. and Liew K.M. (2019), Active vibration control of functionally graded graphene nanoplatelets reinforced composite plates integrated with piezoelectric layers, Thin-Walled Structures, Vol. 145,106372. DOI:10.1016/j.tws.2019.106372.
  16. Wang Y., Lei J.C., Bai L.C., Zhou K. and Liu Z.S., (2019), Effects of Tensile Strain Rate and Grain Size on the Mechanical Properties of Nanocrystalline T-carbon, Computational Materials Science, Vol. 170, 109188. 
  17. Zheng S.J. and Liu Z.S., (2019), Constitutive Model of Salt Concentration Sensitive Hydrogel, Mechanics of Materials, Vol. 136, 103092. DOI: 10.1016/j.mechmat.2019.103092.
  18. Vengatachalam B., Poh L.H., Liu Z.S., Qin Q.H., Swaddiwudhipong S.,  (2019), Three dimensional modelling of closed-cell aluminium foams with predictive macroscopic behaviour, Mechanics of Materials, Vol. 136, UNSP 103067. DOI: 10.1016/j.mechmat.2019.103067.
  19. Wang L.F., Wu Y. and Liu Z.S.,  (2019), Theoretical analysis on the adaptive vibration attenuation of a fixed-fixed beam realized by a piezo-SMA ferrule, Journal of Intelligent Material Systems and Structures, Vol. 30(14), 2079-2090. DOI: 10.1177/1045389X19853640.
  20. Xie C.H. Wu Y. and Liu Z.S.,  (2019), A new approach for electro-elastic analysis of piezoelectric fiber composites with arbitrary shaped inclusions under anti-plane shear and in-plane electric loadings, Smart Materials and Structures,    Vol. 28(7), 075030. DOI: 10.1088/1361-665X/ab1cf7.
  21.  Lei J.C., Zhou Z.D. and Liu Z.S. (2019), Side Chains and the Insufficient Lubrication of Water in Polyacrylamide Hydrogel - A New Insight, Polymers, Vol. 11, 1845, doi:10.3390/polym11111845. 
  22. Li Z.Q. and Liu Z.S. (2019), Energy transfer speed of polymer network and its scaling-law of elastic modulus-New insights, Journal of Applied Physics, Vol.126(21)  215101,  DOI: 10.1063/1.5129621 .
  23. Jia Y.R., Lei J.C., Liu Z.S. and Lee H.P. (2019), Determination of the Equivalent Properties of Periodic Heterogeneous Composite Plates Using the Structural Genome Approach, Int. Journal of Computational Materials Science and Engineering, Vol. 8(4), 1950017, DOI: 10.1142/S2047684119500179. 

2018:

  1. Pan Z.Z., Zhou Y., Zhang N. and Liu Z.S., (2018), A Modified Phase-based Constitutive Model for Shape Memory Polymers, Polymer International, Vol.67 (12), 1677-1683. DOI: 10.1002/pi.5698.[PDF]
  2. Xu S., Cai S.Q. and Liu Z.S., (2018), Thermal Conductivity of Polyacrylamide Hydrogel at Nanoscale, ACS Applied Materials & Interfaces, Vol.10(42), 36352-36360. DOI: 10.1021/acsami.8b09891.[PDF]
  3. Li Y.X., Liu R.X. and Liu Z.S., (2018), The Dynamic Behaviors of a Shape Memory Polymer Membrane, Acta Mechanica Solida Sinica, Vol.31 (5), 635-651. DOI: 10.1007/s10338-018-0042-6.[PDF]
  4. Zhang N., Pan Z.Z., Lei J.C. and Liu Z.S., (2018), Effects of Temperature on Fracture and Fatigue Damage of Temperature Sensitive Hydrogels, RSC Advances, Vol.8,31048-31054. DOI: 10.1039/c8ra06518g.[PDF
  5. Bai, L.C., Sun P.P., Liu B., Liu Z.S. and Zhou K., (2018), Mechanical behaviors of T-carbon: A molecular dynamics study, Carbon, Vol.138, 357-362.[PDF]
  6. He Y.H., Zhou Y., Liu Z.S. and Liew K.M., (2018), Buckling and pattern transformation of modified periodic lattice structures, Extreme Mechanics Letters, Vol.22, 112–121, DOI: 10.1016/j.eml.2018.05.011.[PDF]
  7. Pan Z.Z. and Liu Z.S., (2018), A novel fractional viscoelastic constitutive model for shape memory polymers,  The Journal of Polymer Science Part B: Polymer Physics, Vol.56, 1125–1134. DOI: 10.1002/polb.20180157.[PDF]
  8. Xie C.H., Wu Y. and Liu Z.S., (2018), Modeling and active vibration control of lattice grid beam with piezoelectric fiber composite using fractional order PDμ algorithm, Composite Structures, Vol.198, 126–134.[PDF]
  9. Lei J.C. and Liu Z.S., (2018), A novel model for the mechanical properties of silica aerogels, Journal of Applied Physics, Vol.123, 025102, DOI: 10.1063/1.5028479.
  10. Wang YR, Huang R. and Liu Z.S. (2018), Using Structural Intensity Approach to Characterize Vibro-acoustic Behavior of the Cylindrical Shell Structure, Coupled  Systems Mechanics, Vol.7 (3), 297-319.
  11. Li Y.X. and Liu Z.S., (2018), A Novel Constitutive Model of Shape Memory Polymers Combining Phase Transition and Viscoelasticity, Polymer, Vol.143, 298-308. DOI: 10.1016/j.polymer.2018.04.026.[PDF]
  12. Ang Elisa Y. M., Ng T.Y., Lin R.M., Yeo J.J., Liu Z.S. and Rangaswamy K., (2018), Effects of CNT size on desalination performance of outer-wall CNT slit membrane, Physical Chemistry Chemical Physics, Vol.20 (20), 13896-13902, DOI: 10.1039/C8CP01191E.[PDF]
  13. Zhang N., Zheng S.J., Pan Z.Z. and Liu Z.S., (2018), Phase Transition Effects on Mechanical Properties of NIPA Hydrogel, Polymers, Vol.10 (4), 358.[PDF]
  14. Liu Z., Ng T.Y. and Liu Z.S.,(2018), Preface: Advances in computational aerospace materials science and engineerin. Int. J. Computational Materials Science and Engineering, Vol.7(1), 1802001.[PDF]
  15. Du X.Y., Huang R., Vengatachalam B. and Liu Z.S., (2018), Vibration Control for Slotted Plate Using Structural Intensity Method. Int. J. Computational Materials Science and Engineering, Vol.7 (1), 1850006.[PDF]
  16. Wang Y. and Liu Z.S., (2018), Spontaneous Rolling-up and Assembly of Graphene by Designing with Defects, Nanoscale, 2018, 10 (14), 6487–6495.[PDF]
  17. Hu J.Y., Zhou Y. and Liu Z.S., (2018), The Friction Effect on Buckling Behavior of Cellular Structures under Axial Load, International Journal of Applied Mechanics, Vol.10 (2), 1850013.[PDF]
  18. Zheng S.J., Li Z.Q. and Liu Z.S., (2018), The fast homogeneous diffusion of hydrogel under different stimuli, International Journal of Mechanical Sciences, Vol.137, 263–270.[PDF]
  19. Lei J.C. and Liu Z.S., (2018), The structural and mechanical properties of graphene aerogels based on Schwarz-surface-like graphene models, Carbon, Vol. 130, 741-748.[PDF]
  20. Zheng S.J. and Liu Z.S., (2018), Phase transition of temperature sensitive hydrogel under mechanical constraint, Journal of Applied Mechanics, Vol. 85(2), 021002.  [PDF]
  21. 沙振东; 滕云; 刘子顺; 王铁军, (2018),  金属玻璃的微结构、增韧与疲劳问题研究进展, 固体力学学报, Chinese Journal of Solid Mechanics Vol.39 (4), 333-374.

2017:

  1. Zhang N., Zheng S.J. and Liu Z.S., (2017), Numerical Simulation and Experimental Study of Crack Propagation of Polydimethylsiloxane. Procedia Engineering. DOI:10.1016/j.proeng.2017.08.191.
  2. Wang Y.R., Huang R. and Liu Z.S., (2017), The Relationship between Structural Intensity and Sound Field Characteristics of Cylindrical Shells. Procedia Engineering. DOI:10.1016/j.proeng.2017.08.192.
  3. Li Z.Q., and Liu Z.S. (2017), An algorithm for obtaining real stress field of hyperelastic materials based on digital image correlation system. Int. J. Computational Materials Science and Engineering, 6(4), 1850003, DOI: 10.1142/S2047684118500033.
  4. Sha Z.D., She C.M., Pei Q.X., Liu Z.S., Wang T.J., Gao H.J. (2107), Metallic glass-based chiral nanolattice: Light weight, auxeticity, and superior mechanical propertie. Materials Today, 20(10). 569-576. DOI:10.1016/j.mattod.2017.10.001.
  5. He Y.H., Li Y.X., Liu Z.S. and Liew K.M., (2017), Buckling analysis and buckling control of thin films on shape memory polymer substrate. European Journal of Mechanics - A/Solids, 66, 356-369. DOI: 10.1016/j.euromechsol.2017.08.006. [pdf]
  6. Hu J.Y., Zhou Y., Liu Z.S. and Ng T.Y., (2017), Pattern Switching in Soft Cellular Structures and Hydrogel-Elastomer Composite Materials under Compression. Polymers, 9(6), 229. DOI: 10.3390/polym9060229. [pdf]
  7. He Y.H., Zhou Y., Liu Z.S. and Liew K.M., (2017), Pattern transformation of single-material and composite periodic cellular structures. Materials & Design, 132, 375-384. DOI: 10.1016/j.matdes.2017.07.022. [pdf]
  8. Li, Y.X., Hu J.Y. and Liu Z.S., (2017), A constitutive model of shape memory polymers based on glass transition and the concept of frozen strain release rate. International Journal of Solids and Structures, 124 (1), 252-263. DOI: 10.1016/j.ijsolstr.2017.06.039. [pdf]
  9. Sha Z.D., Wong W.H., Pei Q.X., Branicioc P.S., Liu Z.S., Wang T.J. and Gao H.J., (2017), Atomistic origin of size effects in fatigue behavior of metallic glasses. Journal of the Mechanics and Physics of Solids, 104, 84-95. DOI: 10.1016/j.jmps.2017.04.005.
  10. Li, Y.X., He Y.H. and Liu Z.S. (2017), A Viscoelastic Constitutive Model for Shape Memory Polymers Based on multiplicative decompositions of the deformation gradient. International Journal of Plasticity, 91, 300-317. DOI: 10.1016/j.ijplas.2017.04.004. [pdf]
  11. Lei J.C., Hu Y.W., Liu Z.S., Cheng Gary J. and Zhao K.J. (2017). Defects Mediated Corrosion in Graphene Coating Layer. ACS Applied Materials & Interfaces, 9(13), 11902-11908. DOI: 10.1021/acsami.7b01539. [pdf]
  12. Sha Z.D., Pei Q.X., Wan Q. and Liu, Z.S. (2017), Failure Mechanism of Phosphorene by Nanoindentation. J. Phys. Chem. C, 121, 4708-4713. DOI: 10.1021/acs.jpcc.6b13071.

2016:

  1. Bai, L.C.; Srikanth, N.; Zhao, B.; Liu, B.; Liu, Z.S.; Zhou, K. (2016), Lubrication Mechanisms of Graphene for DLC Films Scratched by a Diamond Tip. J. Phys. D: Appl. Phys. 49(48), 485302. DOI: 10.1088/0022-3727/49/48/485302.
  2. Liu Z.S. (2016), Foreword Special issue on Mechanics of Soft Materials and Machines, International Journal of Applied Mechanics, 8 (7), 1601002. DOI: 10.1142/S175882511601002X.
  3. Xu S., Wang Y., Hu J.Y. and Liu Z.S. (2016), Atomic Understanding of the Swelling and Phase Transition of Polyacrylamide Hydrogel, International Journal of Applied Mechanics, 8(7), 1640002. DOI: 10.1142/S1758825116400020. [pdf]
  4. Ang Elisa Y.M., Ng T.Y., Yeo J.J., Liu Z.S., Geethalakshmi K.R. (2016), Free-standing graphene slit membrane for enhanced desalination, Carbon, 110, 350-355. DOI: 10.1016/j.carbon.2016.09.043.
  5. Wang Y. and Liu Z.S. (2016), The Fracture Toughness Of Graphene During Tearing Process. Modelling Simul. Mater. Sci. Eng., 24(8), 085002 (14pp). [pdf]
  6. Wang Y., Xu S. Liu Z.S. and Ng T.Y., (2016), Energy Wave Propogation In Pristine and Bi-Crystal Graphene. Int. J. Computational Materials Science and Engineering, 4(3), 1560021; DOI: 10.1142/ S2047684116500214. [pdf]
  7. Liu Z.S. (2016), Message from the Editor-in-Chief, International Journal of Applied Mechanics, 8(3), 1601001 DOI: 10.1142/S1758825116010018.
  8. Xu G.K., Liu Z.S., Feng X.Q., and Gao H.J., (2016) Tension-compression asymmetry in the binding affinity of membrane-anchored receptors and ligands. Physical Review E, 93, 032411.
  9. Toh, W.. Ding, Z.W., Ng, T.Y., Liu, Z.S., (2016) Light intensity controlled wrinkling patterns in photo-thermal sensitive hydrogels. Coupled systems mechanics, 5(4), 315-327. DOI: 10.12989/csm.2016.5.4.315. [pdf]
  10. Ding, Z.W., Toh, W., Hu, J.Y., Liu, Z.S., Ng, T.Y., (2016) A simplified coupled thermo-mechanical model for the transient analysis of temperature-sensitive hydrogels. Mechanics of Materials, 97, 212-227. DOI: 10.1016/j.mechmat.2016.02.018. [pdf]

2015:

  1. Sha Z.D., Branicio P.S., Pei Q.X., Liu Z.S., Lee H.P., Tay T.E., and Wang T.J. (2015), Strong and superplastic nanoglass. Nanoscale, 7(41), 17404-17409. DOI: 10.1039/C5NR04740D.
  2. Sha Z.D., Qu S.X., Liu Z.S., Wang T.J. Gao H.J., (2015) Cyclic deformation in metallic glasses. Nano Letters, 15(10), 7010-7015. DOI: 10.1021/acs.nanolett.5b03045.
  3. Xu S., Wan Q., Sha Z.D. and Liu Z.S., (2015), Molecular dynamics simulations of nano-indentation and wear of the γTi-Al alloy, Computational Materials Science, 110, 247-253. DOI: 10.1016/j.commatsci.2015.08.045.
  4. Liu Z.S., Toh W. and Ng T.Y. (2015), Advances In Mechanics Of Soft Materials - A Review of Large Deformation Behavior Of Hydrogel, International Journal of Applied Mechanics, 7(5), 1530001. [pdf]
  5. Zhou H.F., Li X.Y., Wang Y., Liu Z.S., Yang W. and Gao H.J. (2015), Torsional Detwinning Domino in Nanotwinned One-Dimensional Nanostructures, Nano Letters, 15(9), 6082-6087. DOI: 10.1021/acs.nanolett.5b02330.
  6. He Y.H., Guo S.S., Liu Z.S., and Liew K.M. (2015), Pattern Transformation of Thermo-responsive Shape Memory Polymer Periodic Cellular Structures, International Journal of Solids and Structures, 71, 194-205. DOI: 10.1016/j.ijsolstr.2015.06.022. [pdf]
  7. Toh W.. Ding Z.W., Ng T.Y. and Liu Z.S., (2015), Wrinkling of a Polymeric Gel during Transient Swelling, Journal of Applied Mechanics, 82(6), 061004 DOI: 10.1115/1.4030327.
  8. Sha Z.D., Pei Q.X., Liu Z.S., Zhang Y.W. and Wang T.J., (2015), Necking and notch strengthening in metallic glass with symmetric sharp-and-deep notches, Scientific Reports, 5, 10797.
  9. Guo S.S., Wang D.F. and Liu Z.S., (2015), Probabilistic Analysis of Random Structural Intensity for Structural Members under Stochastic Loadings, Int. J. Computational Methods, 12(3), 1550013; DOI: 10.1142/S0219876215500139.
  10. Li Y.X., Guo S.S., He Y.H. and Liu Z.S., (2015), A simplified constitutive model for predicting shape memory polymers deformation behaviour, Int. J. Computational Materials Science and Engineering, 3(4), 1550001 (16 pages); DOI: 10.1142/S204768411550001393.

2014:

  1. Sha Z.D., Wan Q., Pei Q.X. Quek S.S. Liu Z.S., Zhang Y.W. and Shenoy V., (2014), On the failure load and mechanism of polycrystalline graphene by nanoindentation, Scientific Reports, 4, 7437. DOI: 10.1038/srep07437.
  2. Shakouri A., Yeo J.J., Ng T.Y., Liu Z.S. and Taylor H., (2014) Superlubricity-activated thinning of graphite flakes compressed by passivated crystalline silicon substrates for graphene exfoliation,Carbon, 80, 68-74. DOI: 10.1016/j.carbon.2014.08.026.
  3. Sha Z.D., He L.C., Xu S., Pei Q.X., Liu Z.S., Zhang Y.W. and Wang T.J (2014) Effect of aspect ratio on the mechanical properties of metallic glasses, Scripta Materialia, 93, 36-39. DOI: 10.1016/j.scriptamat.2014.08.025.
  4. Toh W. Ng T.Y., Hu J.Y. and Liu Z.S. (2014), Mechanics of Inhomogeneous Large Deformation of Photo-Thermal Sensitive Hydrogels,InternationalJournal of Solids and Structures, 51(25-26), 4440-4451. DOI: 10.1016/j.ijsolstr.2014.09.014.
  5. Sha Z.D., Quek S.S., Pei Q.X., Liu Z.S., Wang T.J. Shenoy V.B. and Zhang Y.W., (2014) Inverse Pseudo Hall-Petch Relation in Polycrystalline Graphene, Scientific Reports, 4, 5991. DOI: 10.1038/srep05991, SREP-13-06507.3d.
  6. Swaddiwudhipong S., Lam N. and Liu Z.S., (2014) Special Issue on Computing in Engineering Applications Preface, Structural Engineering and Mechanics, 50(5), I-II.
  7. Sha Z. D., He L.C., Pei Q.X., Liu Z.S., Zhang Y.W. and Wang T.J., (2014) The mechanical properties of a nanoglass/metallic glass/nanoglass sandwich structure, Scripta Materialia, 83, 37-40.
  8. Yang Z.Z., Liu Z.S.. Ding Z.W., Hu J.Y., Tan Y.M., Swaddiwudhipong S., Lee K. (2014) Strength Analyses of the menisci and the ligaments of the Knee Joint under Different Loading Cases, Journal of Life Medicine, 2(3), 85-94.
  9. Sha Z.D., He L.C., Pei Q.X., Pan H., Liu Z.S., Zhang Y.W., Wang T.J. (2014) On the notch sensitivity of CuZr nanoglass,Journal of Applied Physics, 115(16), 163507.
  10. Chen L., Zhang Y., Swaddiwudhipong S., Liu Z.S. (2014) Mimicking the pattern formation of fruits and leaves using gel materials, Structural Engineering and Mechanics, 50(5), 575-588.
  11. Hu J.Y., He Y.H., Lei J.C., Liu Z.S., Swaddiwudhipong S., (2014) Mechanical behavior of composite gel periodic structures with the pattern transformation Structural Engineering and Mechanics, 50(5), 605-616.
  12. He LC, Guo S.S., Lei J.C., Sha Z.D. and Liu Z.S. (2014) The effect of Stone-Thrower-Wales defects on mechanical properties of graphene sheets- a molecular dynamics study,CARBON, 75, 124-132. DOI:10.1016/j.carbon.2014.03.044.
  13. Sha Z.D., Pei Q.X., Liu Z.S., Shenoy V.B. and Zhang Y.W., (2014) Is the failure of large-area polycrystalline graphene notch sensitive or insensitive?, CARBON, 72, 200-206. DOI: 10.1016/j.carbon.2014.02.003.
  14. Toh W, Ng T.Y, Liu Z.S., Hu, J.Y. (2014) The Deformation Kinetics of pH-Sensitive Hydrogels, Polymer International, 63(9), 1578-1583. DOI 10.1002/pi.4652.
  15. Yeo J.J., Ng T.Y., and Liu Z.S., (2014), Molecular dynamics analysis of the thermal conductivity of graphene and silicene monolayers of different lengths, Journal of Computational and Theoretical Nanoscience 11(8), 1-7.
  16. Zhang Y., Chen L., Swaddiwudhipong S., Liu Z.S., (2014), Buckling Deformation of Annular Plates Describing Natural Forms, International Journal of Structural Stability and Dynamics, 14 (1), 1350054. DOI: 10.1142/S0219455413500545.

2013:

  1. Adibi S., Sha Z.D. Branicio P.S., Joshi S.P., Liu Z.S., Zhang Y.W. (2013) A transition from localized shear banding to homogeneous superplastic flow in nanoglass, Applied Physics Letters, Vol.103 (21), 211905. (DOI: 10.1063/1.4833018.
  2. Hu J.Y., He Y.H., Lei J.C.,Liu Z.S.(2013), Novel mechanical behavior of periodic structure with the pattern transformation,Theoretical & Applied Mechanics Letters, Vol. 3, 054007.
  3. Lei J.C.,Liu Z.S., Yeo J.J., Ng T.Y. (2013). Determination of the Young’s Modulus of Silica Aerogel-An Analytical-Numerical Approach,Soft Matter,Vol. 9 (47), 11367-11373. DOI:10.1039/C3SM51926K.
  4. Yeo J.J., Liu Z.S. Ng T.Y., (2013), Enhanced thermal characterization of silica aerogels through molecular dynamics simulation,Modelling and Simulation in Materials Science and Engineering, Vol. 21(7), 075004.
  5. Ding Z.W.,Liu Z.S., Hu J.Y., Swaddiwudhipong S., Yang Z.Z. (2013), Inhomogeneous large deformation study of temperature-sensitive hydrogel,InternationalJournal of Solids and Structures, Vol. 50(16-17), 2610-2619.
  6. Ren M., Huang J.G., Cai H., Tsai J. M.L., Zhou J.X.,Liu Z.S., Suo Z.G., Liu A.Q. (2013) Nano-optomechanical Actuator and Pull-Back Instability,ACS NANO, 7(2), 1676-1681.
  7. Ng T.Y., Yeo J.J., andLiu Z.S.(2013), Molecular dynamics simulation of the thermal conductivity of shorts strips of graphene and silicene: a comparative study,Int. J. Mech Mater Des,Vol. 9(2), 105-114.DOI: 10.1007/s10999-013-9215-0.
  8. Toh W,Liu Z.S.Ng T.Y, Hong W. (2013), Inhomogeneous Large Deformation Kinetics of Polymeric Gels,International Journal of Applied Mechanics, 5(1). 1350001.
  9. Toh W, Ng T.Y.,Liu Z.S.(2013), Non-Linear Large Deformation Kinetics of Polymeric Gel,Key Engineering Materials, Vols. 535-536 pp 338-341.
  10. Liu Z.S., Swaddiwudhipong S., Hong W., (2013,) Pattern Formation in Plants via Instability Theory of Hydrogels,Soft Matter, Vol. 9 (2), 577 - 587. DOI:10.1039/c2sm26642c.

2012:

  1. Huang W.X., Pei Q.X.,Liu Z.S., Zhang Y.W. (2012), Thermal conductivity of fluorinated graphene: A non-equilibrium molecular dynamics study,Chemical Physics Letters, 552, 97-101.
  2. Islam M.J., Swaddiwudhipong S.,Liu Z.S., (2012), Penetration of Concrete Targets Using a Modified Holmquist-Johnson-Cook Material Model,International Journal of Computational Methods, Vol. 9 (4), 1250056.
  3. Yeo J.J.,Liu Z.S.,Ng T.Y. (2012), Comparing the effects of dispersed stone-thrower-wales defects and double vacancies on the thermal conductivity of graphene nanoribbons,Nanotechnology,Vol. 23,385702.
  4. Zhang Y.,Liu Z.S., Swaddiwudhipong S., Miao H.. Ding Z.W., Yang Z.Z., (2012),pH-Sensitive Hydrogel for Micro-Fluidic Valve,Journal of Functional Biomaterials, Vol. 3 (3), 464-479.
  5. Yang Z.Z.. Ding Z.W.,Liu Z.S., Swaddiwudhipong S., Tan Y.M. and Lee K.,(2012), Comparative Study on Strength of Knee Joint Using Various Material Models,Int. J. Computational Materials Science and Engineering, Vol. 1(2),DOI: 10.1142/S2047684112500133 , No.1250013.
  6. Ng T.Y., Yeo J.J.,Liu Z.S., (2012), A molecular dynamics study of the thermal conductivity of graphene nanoribbons containing dispersed Stone-Thrower-Wales defects,CARBON, Vol.50 (13),4887-4893.
  7. Liu Z.S., Swaddiwudhipong S., Islam M.J., (2012), Perforation of Steel and Aluminum Targets Using a Modified Johnson-Cook Material Model,Nuclear Engineering and Design. Vol. 250, 108-115.
  8. Ng T.Y., Yeo J.J.,Liu Z.S., (2012), A molecular dynamics study of the thermal conductivity of nanoporous silica aerogel, obtained through negative pressure rupturing,Journal of Non-Crystalline Solids, 358(11), 1350-1355.

2011:

  1. Swaddiwudhipong S., Islam M.J.,Liu Z.S., (2011), High Velocity Perforation Simulations of Lightweight Target Plates Using a Modified Johnson-Cook Model,International Journal of Aerospace and Lightweight Structures, Vol. 1 (1) 67-88.
  2. Liu Z.S., SwaddiwudhipongS., Cui F.F., Hong W., Suo Z.G., Zhang Y.W., (2011), Analytical Solutions of Polymeric Gel Structures under Buckling and Wrinkle,International Journal of Applied Mechanics, Vol. 3 (2) 235-257.
  3. Harsono E., Swaddiwudhipong S.,Liu Z.S.and Shen L., (2011), Numerical and experimental indentation tests considering size effects"InternationalJournal of Solids and Structures, Vol. 48 (6) 972-978.
  4. Islam M.J.,Liu Z.S. and Swaddiwudhipong S., (2011), Numerical study on concrete penetration /perforation under high velocity impact by ogive-nose steel projectile,Computers and Concrete, Vol. 8 (1), 111-123.

2010:

  1. Swaddiwudhipong S., Islam M.J. andLiu Z.S.,(2010), High Velocity Penetration/Perforation Using Coupled Smooth Particle Hydrodynamics-Finite Element Method",International Journal of Protective Structures, Vol. 1. No.4, 489-506.
  2. Pei Q.X.,Liu Z.S., Zhang Y.W. and Dong Z.L., (2010), Study of Nanoimprinting Processes by Molecular Dynamics Simulations,Journal of Computational and Theoretical Nanoscience, Vol. 7.2144-2150.
  3. Liu Z.S., Hong W., Suo Z.G.,Swaddiwudhipong S., and Zhang Y.W., (2010), Modeling and Simulation of Buckling of Polymeric Membrane Thin Film Gel,Computational Materials Science, Vol. 49 S60-64.

2009:

  1. Hong W.,Liu Z.S., and Suo Z.G., (2009) Inhomogeneous Swelling of a Gel in Equilibrium with A Solvent and Mechanical Load,InternationalJournal of Solids and Structures, Vol. 46 No. 17, 3282-3289.
  2. Liu Z.S., Harsono E.,SwaddiwudhipongS., (2009), Material Characterization Based on Instrumented and Simulated Indentation Tests,International Journal of Applied Mechanics, Vol. 1(1), 61-84.
  3. Harsono E.,SwaddiwudhipongS.,Liu Z.S.,(2009), Material Characterization Based on Simulated Spherical-Berkovich Indentation Tests,Scripta Materialia, Vol. 60 (11), 972-975.

2008:

  1. Wang D.F, He P.F.,Liu Z.S.,(2008), Structural Intensity Characterization of Composite Laminates Subjected To Impact Load,Journal of Shanghai Jiaotong University (Science), Vol. 13(3), 375-380.
  2. 王东方,贺鹏飞,朱晓玲,刘子顺(Liu Z.S.)(2008),箱形复合材料层板结构的内噪声优化控制,力学季刊,Chinese Quarterly of Mechanics,Vol. 29(2),210-217.
  3. SwaddiwudhipongS., Harsono E.,and Liu Z.S., (2008), Comparative Study of Reverse Algorithms via Artificial Neural Networks Based on Simulated Indentation Tests,Tsinghua Science & Technology. Vol. 13 (S1) 393-399.
  4. Harsono E.,SwaddiwudhipongS. andLiu Z.S., (2008), Effect Of Friction on Indentation Test Results,Modelling and Simulation in Materials Science and Engineering, 16 (6) 065001, 1-12.
  5. Liu Z.S., Swaddiwudhipong S. and Pei, Q.X., (2008), Simulations of Micro and Nanoindentations,Journal of Mechanics of Materials and Structures, Vol. 3 (10) 1847-1856.6.
  6. SwaddiwudhipongS., Harsono E., Hua J., andLiu Z.S., (2008), Reverse Analysis via Efficient Artificial Neural Networks Based on Simulated Berkovich Indentation Considering Effects of Friction,Engineering with Computers, Vol. 24, No. 2, 127-134.

2007:

  1. Pei Q.X., Lu C.,Liu Z.S. and Lam KY (2007), Molecular Dynamics Study on the Nano-imprint of Copper,Journal of Physics D. Applied Physics.Vol. 40, 4928-4935.
  2. 顾易瓅,郑百林,贺鹏飞,刘子顺(Liu Z.S.)(2007),具有分形结构界面的固体膜/粘滞层/基底层状结构的变形,固体力学学报,ACTA Mechanica Solida Sinica, Vol.28 No.2, 183-188.
  3. 王东方,贺鹏飞,刘子顺(Liu Z.S.),李岩(2007),复合材料层合板在动集中力作用下的结构声强特性,力学季刊,Chinese Quarterly of Mechanics, Vol.28(2), 217-222.
  4. Swaddiwudhipong S., Ton T.T.,Liu Z.S. and Hua J., (2007), Modelling of wind load on single and staggered dual buildings,Engineering with Computers, Vol. 23 No. 3, 215-227.
  5. Liu Z.S., Luo X.Y., Lee H.P. and Lu C., (2007), Snoring source identification using structure intensity method,Journal of Biomechanics, Vol. 40(4), 861-870.

2006:

  1. Liu A.Q., Li J.,Liu Z.S., Lu C., Zhang X.M. and Wang Y., (2006) Self-Latched Micromachined Mechanism with Large Displacement Ratio,Journalof Microelectromechanical Systems, Vol. 15 (6), 1576-1585.
  2. Swaddiwudhipong S., Hua J., Harsono E.,Liu Z.S. and Ooi. Brandon, N.S (2006), Improved Algorithm for Material Characterization by Simulated Indentation Tests,Modelling and Simulation in Materials Science and Engineering, 14 (2006) 1347-1362.
  3. SwaddiwudhipongS, Hua J., Tho K.K. andLiu Z.S.(2006), Finite Element Modeling For Materials With Size Effect,Modelling and Simulation in Materials Science and Engineering, Vol. 14 (7), 1127-1137.
  4. Gu Y.L., He P.F., Zheng B.L. andLiu Z.S., (2006). Deformation Of Thin Solid Film/Liquid Layer/Substrate Structures With Rough Liquid Layer/Substrate Interface,Thin Solid Films, Vol. 513, No.1-2, 243-247.
  5. Liu Z.S., Lee H.P. and Lu C. (2006), Reply To Comments On Passive And Active Interior Noise Control Of Box Structures Using The Structural Intensity Method,Applied Acoustics, Vol. 67 (10), 1046-1047.
  6. Tho K.K., Swaddiwudhipong S., Hua J. andLiu Z.S. (2006), Numerical Simulation of Indentation with Size Effect,Material Science and Engineering A., Vol. 421 (1-2): 268-275.
  7. SwaddiwudhipongS., Hua J., Tho K.K. andLiu Z.S. (2006), Equivalency Of Berkovich And Conical Load-Indentation Curves,Modelling and Simulation in Materials Science and Engineering,. Vol. 14 (1), 71-82.
  8. Swaddiwudhipong, S, Tho K.K, Hua J andLiu Z.S., (2006), Mechanism-Based Strain Gradient Plasticity in C0 Axisymmetric Element,International Journal of Solids and Structures, Vol. 43(5), 1117-1130.
  9. Liu Z.S., Lee H.P. and Lu C. (2006), Passive and Active Interior Noise Control of Box Structure Using Structural Intensity Method,Applied Acoustics, Vol. 67(2), 112-134.
  10. Liu Z.S., Lu C., Wang Y.Y., Lee H.P., Koh Y.K. and Lee K.S. (2006), Interior Noise Prediction of Tracked vehicles,Applied Acoustics, Vol. 67(1), 74-91.

2005:

  1. Swaddiwudhipong S, Hua J, Tho K.K andLiu Z.S., (2005), C0 solid elements for materials with strain gradient effects,International Journal for Numerical Methods in Engineering, Vol. 64(10), 1400-1414.
  2. Swaddiwudhipong S., Poh L.H., Hua J.,Liu Z.S. And Tho K.K., (2005), Modeling Nano-Indentation Tests Of Glassy Polymers Using Finite Elements With Strain Gradient Plasticity,Material Science and Engineering A, Vol. 404(1-2) 179-187.
  3. SwaddiwudhipongS., Tho K.K.,Liu Z.S., Hua J. and Ooi Brandon N.S., (2005), Material Characterization via Least Squares Support Vector Machines,Modelling and Simulation in Materials Science and Engineering,13 (6), 993-1004.
  4. Liu Z.S., SwaddiwudhipongS., Lu C. and Hua J., (2005), Transient Energy Flow of Vessel Plate/Shell Structures under Low Velocity Impact,Structural Engineering and Mechanics, Vol. 20 (4), 451-463.
  5. Liu Z.S., Lee H.P. and Lu C., (2005), Numerical Study of Dynamic Buckling for Plate and Shell Structures,Structural Engineering and Mechanics, Vol. 20 (2), 241-257.
  6. Tang M., Liu A.Q., Agarwal A.,Liu Z.S. and Lu C. (2005), A Single-Pole Double-Throw (SPDT) Circuit Using Lateral Metal-Contact Micromachined Switches,Sensors & Actuators: A. Physical, 121 (1), 187-196.
  7. Liu Z.S., Cheng Q.H., He P.F., Lee H.P. and Lu C. (2005), Active Interior Noise Control of Box Structure,GESTSInternational Transaction on Acoustic Science and Engineering, Vol. 3(1), 155-163.
  8. Tang M., Yu, A.B., Liu A.Q., Agarwal A., Aditya S. andLiu Z.S., (2005), High Isolation X-Band MEMS Capacitive Switches,Sensors & Actuators: A. Physical,Vol. 120 (1), 241-248.
  9. Hua J.,SwaddiwudhipongS.,Liu Z.S. and XuQ.Y. (2005), Numerical Analysis of Nonlinear Rotor-Seal System,Journal of Sound and Vibration, Vol. 283(3-5), 525-542.
  10. Liu Z.S., Lee H.P., and Lu C. (2005) Structural Intensity Study of Plates under Low Velocity Impact,International Journal of Impact Engineering, Vol. 31(8), 957-975.
  11. Tho K.K., Swaddiwudhipong S.,Liu Z.S. and Zeng K. (2005), Simulation of Instrumented Indentation and Material Characterization,Material Science and Engineering A, Vol. 390(1-2), 202-209.
  12. Swaddiwudhipong S., Tho K.K.,Liu Z.S., and Zeng K. (2005), Material Characterization Based on Dual Indenters,InternationalJournal of Solids and Structures, Vol. 42 (1), 69-83.
  13. Swaddiwudhipong S., Tho, K. K.,Liu Z.S. and Zeng K. (2005), Material Characterization Based on Nano-Indentation,Journal of Metastable & Nanocrystalline Materials, Vol. 23, 359-362.

2004:

  1. Liu Z.S., Swaddiwudhipong S. and Koh C.G., (2004), High Velocity Impact Dynamic Response of Structures Using SPH Method,International Journal of Computational Engineering and Science, Vol. 5(2), 315-326.
  2. Tho K.K.,SwaddiwudhipongS.,Liu Z.S., and Hua J. (2004), Artificial Neural Network Model For Material Characterization By Instrumented Indentation,Modelling and Simulation in Materials Science and Engineering, Vol. 12(5), 1055-1062.
  3. Tho K.K., Swaddiwudhipong S.,Liu Z.S., Zeng K. and Hua J. (2004), Uniqueness of Reverse Analysis from Conical Indentation Tests,Journal of Materials Research, Vol. 19(8), 2498-2502.

1987-2003:

  1. Zhang X.M., Liu A.Q., Lu C., Wang F. andLiu Z.S., (2003), Polysilicon Micromachined Fiber-Optical Attenuator for DWDM Applications,Sensors& Actuators: A. Physical, Vol. 108 (1-3): 28-35.
  2. Liu A.Q., Zhang X.M., Lu C., Wang F., Lu C. andLiu Z.S., (2003), Optical and Mechanical Models For A Variable Optical Attenuator Using A Micromirror Drawbridge,Journal of Micromechanical and Microengineering, Vol. 13(3), 400-411.
  3. Wang F., Lu C.,Liu Z.S., Li J., Liu A.Q. and Zhang X.M. (2002), Finite Element Simulation and theoretical Analysis of Fiber-optical Switch,Sensors& Actuators: A. Physical, Vol. 96(2-3), 167-178.
  4. Liu Z.S., Swaddiwudhipong S. and Koh C.G. (2002), Stress wave propagation in 1-D and 2-D media using Smooth Particle Hydrodynamics method,Structural Engineering and Mechanics, Vol. 14(4), 455-472.
  5. SwaddiwudhipongS., Koh C.G. andLiu Z.S. (2002) Numerical Study Of Shell Structures Under Low Velocity Impact,Journal of the International Association for Shell and Spatial Structures, Vol. 43(3), 159-170.
  6. Liu Z.S. and SwaddiwudhipongS., (1997). Dynamic Response of Plate and Shell Structures under Low Velocity Impact,Journal of Engineering Mechanics ASCE, Vol. 123(12), 1230-1237.
  7. SwaddiwudhipongS., andLiu Z.S. (1997), Response of Laminated Composite Plate and Shell,Composite Structures, Vol. 37(1), 21-32.
  8. SwaddiwudhipongS. andLiu Z.S. (1996). Dynamic Response of Large Strain Elasto-Plastic Plate and Shell Structures,Thin-Walled Structures, Vol. 26(4), 223-239.
  9. 刘子顺(Liu Z.S.),乐美峰(1995),利用边界积分法计算截面图形的几何性质力学与实践(Mechanics In Engineering), Vol. 17(4), 68-70.
  10. 刘子顺(Liu Z.S.),殷家驹,赵挺 (1994),壳体结构弹塑性大应变动态响应分析,应用力学学报(Chinese Journal of Applied Mechanics), Vol. 11(1), 102-122.
  11. 毛祖德,马贵发,刘子顺(Liu Z.S.) (1993)110KV等级电力变压器油箱结构形式的探讨,变压器(Transformer), Vol. 30(1), 15-18.
  12. 刘子顺(Liu Z.S.),殷家驹,赵挺(1993), 计算板壳结构大应变动态问题的新型有限元法,南洋理工学院学报(Journal of Nanyang Institute of Science and Technology), Vol. 1(1), 66-72. (创刊号).
  13. 刘子顺(Liu Z.S.),闵行,楼志文 (1990),利用固有应变理论计测对节焊钢管残余应力场的实验研究,应用力学学报(Chinese Journal of Applied Mechanics), Vol. 7(2), 48-55.
  14. 刘子顺(Liu Z.S.),闵行,楼志文,(1987),计测残余应力场的固有应变法研究,西安交通大学学报(Journal of Xi’an Jiaotong University), Vol. 21(4), 47-54.