Lawrence Livermore National Laboratory



Scientists Take Aim at ‘Eye-Safer’ Lasers

Most people probably recognize the dire consequences of looking directly into a high-power laser. Less well understood, however, are the dangers to eyesight from light reflected, or “scattered,” off of objects illuminated by those lasers.

Just like secondhand smoke from cigarettes, scattered high-power laser light at wavelengths shorter than 1.4 microns (millionths of a meter) poses a health risk because the light passes through the cornea, focuses onto the retina, and can burn holes in the retina. You can’t see the light, so your eyes don’t know to blink for protection.

To address this issue, a team of NIF & Photon Science researchers is developing lasers that are both high powered and “eye safer” to reduce the danger of retinal damage to bystanders from exposure to scattered laser light. The lasers are designed to transmit light above 1.4 microns, in the infrared portion of the electromagnetic spectrum. At these longer wavelengths, the cornea absorbs the light and it’s never focused on the retina.

Members of the Team Developing Eye-safer LasersMembers of the team developing eye-safer lasers in LLNL’s Fiber Draw Tower (from left): Nick Schenkel, Mike Messerly, Matthew Cook, Leily Kiani, Diana VanBlarcom, Reggie Drachenberg, Paul Pax, and Cody Mart. Not shown: Victor Khitrov, Diana Chen, and Charles Yu. Credit: Mark Meamber

Substantial progress has been made on two such lasers based on unique fiber designs that can achieve wavelengths in the eye-safer region, where the safety threshold is 100 to 1,000 times higher than at shorter wavelengths, according to NIF&PS physicist Reggie Drachenberg.

“This is a new area,” said Drachenberg, the team’s principal investigator of the latest results using a neodymium-fiber laser. “Nobody has gotten to one watt at this wavelength in a fiber and we have gotten to 10 watts—1,000 times higher than the previous record for neodymium at 1.4 microns—so we’re leading the pack by far.”

The immense potential power of laser light comes from its highly directional and coherent nature, with all the photons at the same wavelength and the crests and troughs of the light wave in lockstep. Laser light can remain concentrated for great distances and is able, for example, to reach to the moon and back.

The team has been working on Laboratory Directed Research and Development (LDRD) projects utilizing three commonly used laser materials: neodymium, erbium and ytterbium.

A 1.4-micron Neodymium FiberEnd-on photo of a neodymium optical fiber. The fiber has an outer diameter of 185 microns and a 21-micron-diameter neodymium-doped core at a wavelength of 1.4 microns.

Laser gain is achieved when the electrons in rare-earth fibers such as neodymium and erbium are excited by photons and jump to higher orbits around the nucleus. They eventually relax and emit light through a process called spontaneous emission. If relaxation is induced by interaction with an already generated “signal” photon, the process is called stimulated emission (laser is an acronym for “light amplification by stimulated emission of radiation”). Gain occurs when more energy is emitted than is lost due to waveguide and material losses.

Laser intensity typically is highest at the source and slowly decreases as it propagates over a long distance, Drachenberg explained. Any laser used near bystanders would need to be safe for a person to observe the scattering of light from a target while standing near the source, the location of highest intensity. Because this threshold increases at longer wavelengths, more power can be used and the capability to reach longer distances is increased.

Ytterbium lasers currently hold a dominant position in high-power fiber lasers due in part to their ability to absorb high-power pump light at the pump wavelength and efficiently emit light at one micron. But they have been shown to cause retinal damage by people looking either directly at the laser or at the scattered light at wavelengths shorter than 1.4 microns.

One of the two new laser designs calls for utilizing erbium, which is normally used for low-power telecommunications applications, because glass is most transparent where erbium emits light at 1.55 microns, in the eye-safer region. Erbium, however, has limited ability to absorb high-power pump light at the pump wavelength.

Combining Erbium and Ytterbium

A key to previous efforts in high-power erbium lasers has been to combine erbium and ytterbium in the same fiber. This has led to a 300-watt result at the University of Southampton in the UK. High power is achieved by pumping the ytterbium and transferring the energy to nearby erbium ions; this transfer is limited, however, and creates a bottleneck. At a high enough pump power, the ytterbium begins to lase, or emit light, at one micron. The researchers aim to improve this transfer efficiency and achieve higher power in erbium at 1.55 microns.

“The trick we’re trying to play,“ said NIF&PS physicist Victor Khitrov, “is that the energy has to transfer efficiently from the excited ytterbium atom to the erbium atom without bottlenecking at high powers.“

A Stretch of Eyesafer FiberA defect-free stretch of fiber co-doped with erbium (Er) and ytterbium (Yb). The Yb allows absorption of commonly available high-power diode pump light at .98 microns, and the Er allows for emission at 1.55 microns in the eyesafer region after an ion-ion energy transfer.

This is important to the eye-safer laser development, Drachenberg explained, because the amplifier will emit most of its power at the wavelength with the most gain. The waveguide designs increase waveguide losses at undesired wavelengths to suppress gain at that wavelength, allowing a different and more desirable wavelength to have the most gain.

The researchers developed a process that selectively suppresses the gain below 1.4 microns, using a diode to amplify the power and essentially tricking the laser ions into emitting more light at longer wavelengths, Khitrov said. “Unlike previous efforts in erbium,” he said, “we will use wavelength selective waveguide designs to suppress one-micron gain and promote additional energy transfer from the ytterbium to the erbium for emission at 1.55 microns.”

The researchers have employed the materials in unique combinations or fiber designs they call “recipes.” They are developing one neodymium-based fiber laser at a wavelength of 1.4 microns and a power of 10 watts—the highest power to date for a neodymium-based fiber laser at that wavelength.

Neodymium at eye-safer wavelengths is new territory, and demonstrating moderate power scaling to tens or hundreds of watts is the team’s current goal, with kilowatt (1,000-watt) scaling reserved for future projects. For the erbium-ytterbium combination, the plan is to demonstrate power scaling beyond the record of 300 watts previously achieved at other institutions, Drachenberg said. With LLNL’s unique capabilities, the team members believe they can demonstrate power scaling up to one kilowatt.

While these lasers are in the eye-safer region, the scientists warn, they aren’t safe for a direct look straight into the laser. It’s the equivalent of looking at the lighted glow from a shaded lamp, but not directly at the bare bulb under the shade.

The many technology applications for these lasers include telecommunications, medicine, bioscience, materials processing, metrology, spectroscopy, and directed energy with important national defense applications. Another is LiDAR (light detection and ranging), a remote-sensing method that uses light from a pulsed laser to measure ranges, or variable distances, to the Earth or to surrounding objects. LiDAR is in demand for such newly emerging technologies as self-driving vehicles and airborne and ground-based archeology.

LiDAR Reveals Ancient CivilizationUsing LiDAR technology, archeologists recently discovered more than 60,000 hidden Maya ruins in Guatemala near the city of Tikal (left). The technology was used to survey digitally beneath the thick forest canopy, revealing houses, palaces, elevated highways, and defensive fortifications. Credit: Wild Blue Media

The waveguide design that enables this progress entails actually degrading guidance at selected wavelengths; that is, making them “leaky.” This is accomplished by connecting the core of the waveguide to the cladding by a “bridge” of wavelength-dependent resonant elements.

The designs were analyzed and developed by LLNL scientist Paul Pax, who has worked on related NIF&PS laser LDRD programs using a FEM (finite element method)-based mode-solving code and post-processing. This approach provided insight and resulted in designs tailored to the neodymium and erbium-ytterbium recipes. Drachenberg and Khitrov said using Pax’s modeling saved them considerable experimental time that could have taken weeks or even months for each laser.

The team credits another key solution to chemical engineer Diana VanBlarcom and the NIF Optics Processing Team. VanBlarcom saw that fibers were being contaminated by particulates when the rods were stacked outside a cleanroom. Particulate contamination in fiber lasers can result in many detrimental effects including energy losses, poor strength, and failure (breakage) at high power.

VanBlarcom developed a cleaning process for the individual laser rods which mimicked the cleaning and etching done on NIF’s ultraviolet optics. She also moved the stacking activity into a Class 100 cleanroom to maintain the cleanliness of components and prevent particulate contamination.

“I was happy I could leverage my knowledge of NIF optic processing,” VanBlarcom said, “and help the fiber laser team tackle some of their problems with fiber performance and reliability.”

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