As shown, after the laser gas undergoes emission it passes over a series of heat exchangers. At repetition rates greater than 3 Hz a cooling unit must be run which passes 30◦ C de-ionized water through these heat exchangers. Once the hot gas is cooled it passes through particulate filters and is sent back into the laser tube to begin the cycle again. As this process continues the halogen component of the lasing medium reacts with the non-passivated metal released by the discharge of the laser cavity’s pre-ionization pins and other contaminants within the laser cavity. This contamination of the halogen gas reduces the average pulse energy of the laser until no lasing occurs and the 4 gas mixture must be completely replaced. For the purposes of laser ablating diamond, the laser gas medium is replaced when the average pulse energy is less than 50 mJ. Lambda Physik specifies this model laser can fire 400,000 pulses before the specified power reaches 50%. Assuming the laser starts at a maximum power of 120 mJ the laser would produce 480,000 pulses before it reached the minimum pulse energy of 50 mJ and had to be refilled. A 7.2 x 7.2 x 0.25 mm^3 diamond thinned with a central region of dimensions 6.7 x 6.7 x 0.02 mm^3 would require approximately 450,000 pulses per single complete pass over the diamond (assuming 0.5 mm s motor speed in x direction, 50 Hz laser repetition rate, and 0.01 mm motor step in y axis). | As shown, after the laser gas undergoes emission it passes over a series of heat exchangers. At repetition rates greater than 3 Hz a cooling unit must be run which passes 30◦ C de-ionized water through these heat exchangers. Once the hot gas is cooled it passes through particulate filters and is sent back into the laser tube to begin the cycle again. As this process continues the halogen component of the lasing medium reacts with the non-passivated metal released by the discharge of the laser cavity’s pre-ionization pins and other contaminants within the laser cavity. This contamination of the halogen gas reduces the average pulse energy of the laser until no lasing occurs and the 4 gas mixture must be completely replaced. For the purposes of laser ablating diamond, the laser gas medium is replaced when the average pulse energy is less than 50 mJ. Lambda Physik specifies this model laser can fire 400,000 pulses before the specified power reaches 50%. Assuming the laser starts at a maximum power of 120 mJ the laser would produce 480,000 pulses before it reached the minimum pulse energy of 50 mJ and had to be refilled. A 7.2 x 7.2 x 0.25 mm^3 diamond thinned with a central region of dimensions 6.7 x 6.7 x 0.02 mm^3 would require approximately 450,000 pulses per single complete pass over the diamond (assuming 0.5 mm s motor speed in x direction, 50 Hz laser repetition rate, and 0.01 mm motor step in y axis). |