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New generation of metallic implants through capability of absorption within biological environment\udhas been introduced in recent researches. Although, magnesium implant with proper\udbiocompatibility has been proposed as biodegradable metallic implant, its insufficient mechanical\udattributes must be enhanced for implantation within human body. Laser shock peening has been\udsuccessfully conducted for modification of magnesium implant. Overall, laser shock peening can be\udperformed by low repetition rate (less than 30 Hz) and high power pulsed laser which needs\udexpensive devices. In order to laser shock peen magnesium alloys that have a lower mechanical\udstrength, it is better to use high repetition pulsed laser which is much faster and economical.\udRecently, high repetition rate laser shock peening of magnesium has been theoretically found\udfeasible in previous research of authors. In order to validate occurrence of high repetition rate laser\udshock peening, changes in surface topography and hardness are evaluated on the magnesium\udspecimen

High Repetition Laser Shock Peening on Magnesium Based Biodegradable Alloys