Citations (36)
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Read on this site (5)
H. Zhang & C. Y. Yu. (2006) Laser shock processing of holes. Surface Engineering 22:2, pages 153-156.
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K. Ding. (2003) Three-dimensional Dynamic Finite Element Analysis of Multiple Laser Shock Peening Processes. Surface Engineering 19:5, pages 351-358.
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C.S. Montross, M. Brandt & M.V. Swain. (2001) Self-Limiting Hardness Changes in Laser Peened 6061-T6 Aluminium. Surface Engineering 17:6, pages 477-482.
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C.S. Montross, V. Florea, M. Brandt & M.V. Swain. (2000) Subsurface properties of laser peened 6061–T6 Al weldments. Surface Engineering 16:2, pages 116-121.
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H. Zhang. (1999) Surface treatment of aluminium alloy by laser shock processing. Surface Engineering 15:6, pages 454-456.
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Articles from other publishers (31)
Mohammad Rezayat, Mojtaba Karamimoghadam, Mahmoud Moradi, Giuseppe Casalino, Joan Josep Roa Rovira & Antonio Mateo. (2023) Overview of Surface Modification Strategies for Improving the Properties of Metastable Austenitic Stainless Steels. Metals 13:7, pages 1268.
Crossref
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Zhifen Zhang, Rui Qin, Geng Li, Zimin Liu, Guangrui Wen & Weifeng He. (2022) Online Evaluation of Surface Hardness for Aluminum Alloy in LSP Using Modal Acoustic Emission. IEEE Transactions on Instrumentation and Measurement 71, pages 1-10.
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Pratik Shukla, X. Shen, Ric Allott, Klaus Ertel, S. Robertson, R. Crookes, H. Wu, A. Zammit, P. Swanson & M.E. Fitzpatrick. (2021) Response of silicon nitride ceramics subject to laser shock treatment. Ceramics International 47:24, pages 34538-34553.
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Luoxian Zhou, Chengyu Zhu, Hang Yuan & Xin Sun. (2021) Study on the correlation between external plasma plumes and stress distribution inside a target immediately after surface laser loading. Optics & Laser Technology 141, pages 107096.
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Zhaopeng Tong, Jiafei Jiao, Wangfan Zhou, Yu Yang, Lan Chen, Huaile Liu, Yuzhou Sun & Xudong Ren. (2019) Improvement in cavitation erosion resistance of AA5083 aluminium alloy by laser shock processing. Surface and Coatings Technology 377, pages 124799.
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Rujian Sun, Liuhe Li, Ying Zhu, Lixin Zhang, Wei Guo, Peng Peng, Bo Li, Chao Guo, Lei Liu, Zhigang Che, Weidong Li, Jianfei Sun & Hongchao Qiao. (2017) Dynamic response and residual stress fields of Ti6Al4V alloy under shock wave induced by laser shock peening. Modelling and Simulation in Materials Science and Engineering 25:6, pages 065016.
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Pratik Shukla, Subhasisa Nath, Guanjun Wang, Xiaojun Shen & Jonathan Lawrence. (2017) Surface property modifications of silicon carbide ceramic following laser shock peening. Journal of the European Ceramic Society 37:9, pages 3027-3038.
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Pratik Shukla, Graham C. Smith, David G. Waugh & Jonathan Lawrence. Development in laser peening of advanced ceramics. Development in laser peening of advanced ceramics.
Pratik P. Shukla, Philip T. Swanson & Colin J. Page. (2013) Laser shock peening and mechanical shot peening processes applicable for the surface treatment of technical grade ceramics: A review. Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture 228:5, pages 639-652.
Crossref
Crossref
Yongkang Zhang, Jinzhong Lu & Kaiyu LuoYongkang Zhang, Jinzhong Lu & Kaiyu Luo. 2013. Laser Shock Processing of FCC Metals. Laser Shock Processing of FCC Metals
15
51
.
Bang Fu Wang, Xue Li Zhu, Ou Xie & Zhen Yin. (2012) Based on Microscale Laser Shock Processing of Metal Material Characteristics Analysis and Prospect. Advanced Materials Research 450-451, pages 273-276.
Crossref
Crossref
M. Morales, J.A. Porro, M. Blasco, C. Molpeceres & J.L. Ocaña. (2009) Numerical simulation of plasma dynamics in laser shock processing experiments. Applied Surface Science 255:10, pages 5181-5185.
Crossref
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Omar Hatamleh. (2008) The Effects of Laser Peening and Shot Peening on Mechanical Properties in Friction Stir Welded 7075-T7351 Aluminum. Journal of Materials Engineering and Performance 17:5, pages 688-694.
Crossref
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M. Morales, J.L. Ocaña, C. Molpeceres, J.A. Porro & A. García-Beltrán. (2008) Model based optimization criteria for the generation of deep compressive residual stress fields in high elastic limit metallic alloys by ns-laser shock processing. Surface and Coatings Technology 202:11, pages 2257-2262.
Crossref
Crossref
. 2008. Handbook of Liquids-Assisted Laser Processing. Handbook of Liquids-Assisted Laser Processing
387
422
.
Q. LIU, C. H. YANG, K. DING, S. A. BARTER & L. YE. (2007) The effect of laser power density on the fatigue life of laser-shock-peened 7050 aluminium alloy. Fatigue & Fracture of Engineering Materials and Structures 30:11, pages 1110-1124.
Crossref
Crossref
. 2006. Laser Shock Peening. Laser Shock Peening
151
157
.
J.L. Ocaña, C. Molpeceres, J.A. Porro, G. Gómez & M. Morales. (2004) Experimental assessment of the influence of irradiation parameters on surface deformation and residual stresses in laser shock processed metallic alloys. Applied Surface Science 238:1-4, pages 501-505.
Crossref
Crossref
Vitaly Yakovyna, Nicolas Berchenko, Yuriy Nikiforov & Alexandr Izhnin. (2004) Dissipation of inclusions in HgCdTe/CdTe films under the influence of laser shock waves. physica status solidi (c) 1:4, pages 682-685.
Crossref
Crossref
Hongqiang Chen & Y. Lawrence Yao. (2004) Modeling Schemes, Transiency, and Strain Measurement for Microscale Laser Shock Processing. Journal of Manufacturing Processes 6:2, pages 155-169.
Crossref
Crossref
V. S. Yakovyna, D. M. Zayachuk & N. N. Berchenko. (2003) Defect formation in PbTe under the action of a laser shock wave. Semiconductors 37:11, pages 1275-1277.
Crossref
Crossref
J. Dutta Majumdar & I. Manna. (2003) Laser processing of materials. Sadhana 28:3-4, pages 495-562.
Crossref
Crossref
Jon E. Rankin, Michael R. Hill & Lloyd A. Hackel. (2003) The effects of process variations on residual stress in laser peened 7049 T73 aluminum alloy. Materials Science and Engineering: A 349:1-2, pages 279-291.
Crossref
Crossref
Wenwu Zhang & Y. Lawrence Yao. (2001) Modeling and simulation improvement in laser shock processing. Modeling and simulation improvement in laser shock processing.
Wenwu Zhang & Y. Lawrence Yao. (2001) Microscale Laser Shock Processing—Modeling, Testing, and Microstructure Characterization. Journal of Manufacturing Processes 3:2, pages 128-143.
Crossref
Crossref
Y. Nikiforov, V. Yakovyna & N. Berchenko. (2000) Laser shock waves as a tool of changing the strains in materials. Materials Science and Engineering: A 288:2, pages 173-176.
Crossref
Crossref
J. Kaspar, A. Luft & W. Skrotzki. (2000) Deformation Modes and Structure Evolution in Laser-Shock-Loaded Molybdenum Single Crystals of High Purity. Crystal Research and Technology 35:4, pages 437-448.
Crossref
Crossref
T. Schmidt-Uhlig, P. Karlitschek, M. Yoda, Y. Sano & G. Marowsky. (2000) Laser shock processing with 20 MW laser pulses delivered by optical fibers. The European Physical Journal Applied Physics 9:3, pages 235-238.
Crossref
Crossref
J.Senthil Selvan, G Soundararajan & K Subramanian. (2000) Laser alloying of aluminium with electrodeposited nickel: optimisation of plating thickness and processing parameters. Surface and Coatings Technology 124:2-3, pages 117-127.
Crossref
Crossref
T. Schmidt-Uhlig, G. Marowsky, M. Yoda & Y. Sano. (2000) Fiber transmission of high-power laser pulses for laser shock processing. Fiber transmission of high-power laser pulses for laser shock processing.
J. A. Bolger, C. S. Montross & A. V. Rode. (1999) Shock waves in basalt rock generated with high-powered lasers in a confined geometry. Journal of Applied Physics 86:10, pages 5461-5466.
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