Influence of heat accumulation during laser micromachining of CoCrMo alloy with ultrashort pulses in burst mode

“…Both fluences are smaller than the ablation threshold of CoCrMo [13] and thus in the non-ablation regime. Due to the high intra-burst pulse repetition rate of 80 MHz, residual heat is accumulated, which exceeds the boiling temperature in this regime after a certain number of pulses and material is removed by evaporation.…”

“…The applied fluences in the range between 0.2 and 0.75 J/cm 2 per pulse in a burst were chosen to ensure that the absorbed laser radiation is smaller but also larger than the ablation threshold of the investigated materials [13,14]. Experiments at fluences per pulse above the ablation threshold are designated in this paper as "ablation regime" and the fluences below the ablation threshold as "non-ablation regime".…”

“…Due to the short intra-burst pulse repetition time of 12.5 ns, the laser-induced heat induced by each laser pulse in the interaction zone cannot completely dissipate within the material before the subsequent pulse interacts with the material surface [13,16]. As a result, heat is accumulated and the temperature in the interaction zone increases with an increase in the number of pulses in the burst.…”

“…By using an eight-pulse burst with an intra-burst pulse repetition time of 12.5 ns, the burst has a time width of 87.5 ns. In conclusion, melting films can be formed which, depending on the number of pulses and fluence per pulse in the burst, [13] remain for a period of a few picoseconds to over 100 ns until they solidify [13,16]. The movement within the melt film is described in terms of melt convection [17,18].…”

“…In conclusion, different surface structures caused by the dynamics of the melt film can be produced. These melting dynamics can induce a smoothing effect to obtain structured surfaces with a very low roughness [13,24,25]. In the case of a further increase of the surface temperature by accumulated heat, the boiling temperature can be exceeded even in the non-ablation regime and material can be removed by evaporation [16].…”

Surface treatment on cobalt and titanium alloys using picosecond laser pulses in burst mode

“…Both fluences are smaller than the ablation threshold of CoCrMo [13] and thus in the non-ablation regime. Due to the high intra-burst pulse repetition rate of 80 MHz, residual heat is accumulated, which exceeds the boiling temperature in this regime after a certain number of pulses and material is removed by evaporation.…”

“…The applied fluences in the range between 0.2 and 0.75 J/cm 2 per pulse in a burst were chosen to ensure that the absorbed laser radiation is smaller but also larger than the ablation threshold of the investigated materials [13,14]. Experiments at fluences per pulse above the ablation threshold are designated in this paper as "ablation regime" and the fluences below the ablation threshold as "non-ablation regime".…”

“…Due to the short intra-burst pulse repetition time of 12.5 ns, the laser-induced heat induced by each laser pulse in the interaction zone cannot completely dissipate within the material before the subsequent pulse interacts with the material surface [13,16]. As a result, heat is accumulated and the temperature in the interaction zone increases with an increase in the number of pulses in the burst.…”

“…By using an eight-pulse burst with an intra-burst pulse repetition time of 12.5 ns, the burst has a time width of 87.5 ns. In conclusion, melting films can be formed which, depending on the number of pulses and fluence per pulse in the burst, [13] remain for a period of a few picoseconds to over 100 ns until they solidify [13,16]. The movement within the melt film is described in terms of melt convection [17,18].…”

“…In conclusion, different surface structures caused by the dynamics of the melt film can be produced. These melting dynamics can induce a smoothing effect to obtain structured surfaces with a very low roughness [13,24,25]. In the case of a further increase of the surface temperature by accumulated heat, the boiling temperature can be exceeded even in the non-ablation regime and material can be removed by evaporation [16].…”

Surface treatment on cobalt and titanium alloys using picosecond laser pulses in burst mode

Process limits for percussion drilling of stainless steel with ultrashort laser pulses at high average powers

Ablation characteristics on silicon from ultrafast laser radiation containing single MHz and GHz burst pulses