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New Laser Technologies Displacing Old

Photonics Spectra
Jan 2018
High-power fiber and diode lasers are reshaping the materials processing sector, while powerful blue lasers are finding their niche in select welding applications.


For some CO2 laser applications, the end is at hand, with fiber lasers having almost totally replaced the older technology. Another shift currently brewing is due to the arrival of high-power diode lasers, which are impacting materials processing and driving down the cost of ultrafast lasers through the advent of direct diode pumping. In these transitions, the lasers that win out typically cost less, are easier to operate and are more robust. They also may offer other advantages: a wavelength that materials absorb more readily or that lends itself to greater precision. But these newcomers shouldn’t get too comfortable. Exotic technologies — like powerful blue lasers today and organic lasers years down the road — are likely to make their mark. In part, this will be by displacing, to some degree, today’s winners. The recent replacement of CO2 lasers by fiber systems is illustrated by the shift in the mix at Bystronic Laser AG for its sheet metal cutting systems. “Two years ago, we were probably already at 70 percent fiber. Now, we’re probably almost 100 percent fiber for the North American market,” said Frank Arteaga, the company’s head of product marketing for the NAFTA region. That is telling because Bystronic, a Niederönz, Switzerland-based manufacturer of materials processing systems, started out in 1986 with a CO2 laser sheet metal cutting machine. The company stayed with the technology until sufficiently powerful, single-mode fiber lasers were available. Bystronic offered its first fiber laser sheet metal cutting system in 2009. The new laser technology offered advantages, Arteaga said. The systems were more robust and required less maintenance than those based on the older technology. Together, that cut the operational cost per hour in half. As for throughput, that ranged anywhere from two to five times faster with the switchover to fiber lasers.

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A device which operates under the processes of absorption and stimulated emission and by the condition that gain exceeds loss in order to sustain amplification. The term laser is the acronym for Light Amplification by the Stimulated Emission of Radiation.  The standard components of a laser include: 1.) a lasing material known as the gain medium. 2.) a pump source. 3.) laser cavity To achieve lasing, the atoms of a material such as crystal, glass, liquid, dye or gas are excited by...
system on chip
Abbreviated SoC. A single chip containing all the electronic circuits required for a complete, working product. SoCs are similar to microcontroller technology but provide additional components. A SoC for a smartphone can include graphics, audio, video and camera processing in addition to all the microcontroller circuit. By compacting more electronic circuits onto one chip, miniaturizing and creating power efficient technology becomes feasible.  
fiber laser
A laser in which the lasing medium is an optical fiber doped with low levels of rare-earth halides to make it capable of amplifying light. Output is tunable over a broad range and can be broadband. Laser diodes can be used for pumping because of the fiber laser's low threshold power, eliminating the need for cooling.
laserCO2 laserBystronicHank HoganTi:sapphiresystem on chipfiber laserIPGCenter for Organic Photonics and Electronics ResearchNuburublue laserFeatures

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