The phenomenon of laser supported absorption (LSA) of CO2 laser radiation is investigated with spatially and temporally resolved plasma spectroscopy in Argon as ambient gas at pressures of 1 -iO Pa. A TB-CO2 laser with a gas mixture of C021N2/He = 114/4 at a total pressure of half an atmosphere is used. The pulse length of the Th-C02 Laser is about 6 ts at a mean power of some 100 kW. LSA-phenomena and material ablation processes are compared with that of a con ventional TEA-CO2 short pulse laser. It could be shown that longer pulses of less mean power make material ablation more efficient ifthe absorption wave becomes transparent within the pulse time ofthe laser. Maximum electron density of 2.5 .1017 and a temperature of 3 eV were measured 1.5 is after the begin of the irradiation for an expanding aluminium plasma into vacuum. 1.ThE LASER SYSTEMBy using a non conventional gas mixture and total pressures of about half an atmosphere in a modified TEA-C02-Laser, see fig. 1, pulse-durations in the range of some hundred nanoseconds to 10 p.s could be produced. As the pulse-length we define the time within which 85 % ofthe total pulse energy has been emiued by the laser. On the one hand the CO2 molecule is excited directly by electron impact and on the other by energy transfer from the excited nitrogen molecule. The rate ofenergy transfer' is 1.4 x iO mbar1 s .The laser pulse consists of a 50 -100 ns peak of high amplitude corresponding to the direct excitation mechanism and a 1 -10 ts part of lower amplitude due to the energy transfer from the nitrogen molecule. 1) By lowering the partial pressure of CO2 as well as the total pressure the pulse length is prolonged, the laser efficiency however decreases. The total pulse energy amounts 500 mJ to 3J at pulse lengths of 10 ts to some 100 ns, respectively, see fig 2. A stable resonator is used, consisting of a gold coated copper mirror with 10 m focal length and a plane ZnSe output coupler with a reflectivity of 60 %. In multimode operation the measured beam divergence was approximately 3 mrad. At a CO2 partial pressure of less than ca. 25.102 Pa (about 8 % of the total pressure) the threshold gain condition is no longer fuffilled. For pulse durations exceeding 10 psthere must be used an output coupler with higher reflectivity or a folded resonator.2'3) The efficiency ofthe laser would be much lower then. The electrical circuit is a simple charge transfer circuit. The capacity of the main discharge capacitor bank is 60 uP. The switch element is a pseudo spark switch.4 IGNITION OF A PLASMA AND ABSORPTION WAVESInvestigations were made on the plasma formation and absorption waves. In air there is a plasma generated at irradiation with pulsed CO1 lasers above an threshold power density of W/cm2 which decreases in the vicinity of surfaces to about i07 W/cm"6. From this initial plasma a laser supported absorption wave (LSAW) starts and moves towards the incoming laser beam. As the duration of the laser pulse is in our case one order of magnitude longer than that of the TEA CO ...
The experimental results of high-repetition rate pseudospark switch testing are reported, with particular interest in applications like high repetition rate, high-average power excimer lasers and pulsed TEA C02 lasers. Typical test parameters are hold-off voltage of about 20 kV, peak currents around 15 kA, and pulse durations of less than 100 ns, discharge conditions that are typical for high average power excimer lasers.These were realized in a low inductive discharge circuit using discrete ceramic capacitors of up to 10 nF total capacitance and an impedance of about 1 Q. The resulting peak currents were about 19 kA in the short-circuited, ringing discharge. A special feature of the switch is being capable to withstand severe current reversal, high rates of current rise of about 5*1011 A/s and peak currents above 20 kA. Some 1O shots have been performed with a sealed-off metal-ceramic pseudospark switch with integrated hydrogen reservoir without degradation of the switch performance. In this setup repetition rates of up to 1.8 kHz were achieved. The switch triggering behaviour and measurements of the switch resistance in dependence of the peak current are reported about.
Results ofmvestigations on pulse lengthening of a TE-C02-laser for materials processing will be reported. The laser is used in two main modifications both working at an absolute pressure of lower than 300 mbar. With a folded resonator pulse durations up to 20 sec have been achieved. As there is no longer the initial peak but a descending saw-tooth like form, one can get mean powers up to 100 kW and maximum powers up to 300 kW. Using a so-called hybrid-resonator containing a cwCO2-laser-section,there are even better pulse shapes within about 10-15 jisec, but containing lower pulse energies up to /2 Joule. The influence ofparameters e.g. absolute pressure of working gas or gas mixture on pulse form and duration and results of cutting and drilling of metals like Al or Cu will be presented.
The TEA-C02-laser (ransverse1y xcited atmospheric pressure) is a tool for the pulsed processing of materials with peak power densities up to 1O" W/cm2 and a FWHM of 70 ns. The interaction between the laser beam, the surface of the work piece and the surrounding atmosphere as well as gas pressure and the formation of an induced plasma influences the response of the target. It was found that depending on the power density and the atmosphere the response can take two forms. (1) No target modification due to optical break through of the atmosphere and therefore shielding of the target (air pressure above 10 mbar, depending on the material).(2) Processing of materials (air pressure below 10 mbar, depending on the material) with melting of metallic surfaces (power density above 0.5 lO W/cm2), hole formation (power density of 5 iO W/cm2) and shock hardening (power density of 3 .5 lO W/cm2). All those phenomena are usually linked with the occurance of laser upported combustion waves (LSC) and laser upported detonation waves (LSD), respectively for which the mechanism is still not completely understood. The present paper shows how short time photography and spatial and temporal resolved spectroscopy can be used to better understand the various processes that occur during laser beam interaction. The spectra of titanium and aluminum are observed and correlated with the modification of the target. If the power density is high enough and the gas pressure above a material and gas composition specific threshold, the plasma radiation shows only spetral lines of the background atmosphere. If the gas pressure is below this threshold, a modification of the target surface (melting, evaporation and solid state transformation) with TEA-C02-laser pulses is possible and the material specific spectra is observed. In some cases spatial and temporal resolved spectroscopy of a plasma allows the calculation of electron temperatures by comparison of two spectral lines.
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