Laser Gold Properties

The following is a detailed listing of the salient properties of Laser Gold.
In our experience, it answers most of the “frequently asked questions.

Reflectivity BRDF Emissivity Hardness Stability Overcoat Thickness Laser Damage Threshold

Uniformity Temperature Purity Size Polarization Plane Substrates Laser Black Properties How to Specify Application Examples

Laser Damage Threshold :
Courtesy of Big Sky Laser (Data and Graph)

Reflectivity:
Laser Gold plating reflectivity is greater than 97% at 0.7 microns and greater than 99% at 10.6 microns when measured on a low-scatter substrate. The reflectivity in the infrared equals and often exceeds that of a freshly vapor-deposited gold. Because of its outstanding cleanability, stability and reflectivity, the National Bureau of Standards, (NIST), chose Laser Gold plating as the Standard IR reference material (#2011). For more than fifteen years Epner Technology has been the sole source supplier of these standards. (Tabular Data) | (Reflectance Graph)

Bi-directional Reflectance Distribution Function (BRDF):
Epner's diffuse Lasergold coating specified primarily on integrating spheres, has been measured at Schmitt Measurement Systems, Inc. The measurements were made at 10.6 microns on a mechanically diffused surface. (Graph)

Emissivity:
Measurements made by a variety of aerospace companies confirm Laser Gold’s theoretically low emissivity. While a value of .02 is consistently obtained on polished substrates, ETI has been able to modify, electrochemically, sufaces that are too delicate or too convoluted to permit physical polishing. The surface of machined materials, Be or Al, for example, can achieve a consistent emissivity of .03 to .05.
Indeed, the ability to achieve a repeatable emissivity value, whatever the substrate, has made Laser Gold the coating specified on an impressive array of military and space programs. (Emissivity Test Data)

Hardness:
Laser Gold plating hardness exceeds 180 on the Knoop scale when measured by the diamond-indenter method of ASTM-B-578-87. Laser Gold passes the 50-rub test of Mil-O-13830 and paragraph 3.8 and 4.4.5 of Mil-M-13508. It will withstand judicious cleaning … indefinitely.

Stability:
Laser Gold has been the NIST (NBS) IR Reflectance Standard (#2011) for nearly20 years.

Overcoat:
None, and none required. It exhibits the broadband reflectivity of a pure gold surface, except that this surface can be physically wiped clean.

Thickness:
Laser Gold plating can be applied from 0.1 micron to 100 microns or more. The heavier deposits have been used for single point diamond turning directly into the Laser Gold plated surface and for ruling diffraction gratings. The thinner coatings are used when the optical figure is critical.

Uniformity:
Laser Gold plating can be applied with remarkable uniformity across surfaces as large a 1-meter in diameter. Because it is electrolytically deposited, Laser Gold can exhibit high current density “runout” but special tooling and years of experience permit Epner Technology to eliminate the effect of this phenomenon. Because Laser Gold plating is not line-of-sight dependent, it can thus coat the inside of lightpipes or other deep cavities with parallel walls.

Temperature:
There is virtually no risk of optical distortion during processing since metal substrates are never subjected to more than 70°C (150°F) Non-metal optics will see temperatures that are typical of vacuum coating chambers.
Laser Gold plating itself is qualified to meet the thermal stresses of space.

Purity:
Laser Gold is a pure (.9999). Combining this purity with a hardness of almost 200 Knoop is what makes Laser Gold plating unique in the world of optical coatings.

Size:
The largest beryllium mirror (0.9 meter diameter) ever gold coated was plated with Laser Gold. It was the Vegetation Canopy Lidar mirror for NASA Goddard. Prior to that, the largest mirrors gold coated at Epner were the KECK Telescope IR Secondary Mirror and the Mars Observer Laser Altimeter Mirror both 0.5-meter in diameter.

Polarization Plane and Scatter:
When applied to metal optics, there is no perceptible change in performance in either the S or P polarization plane. Laser Gold plating does not increase scatter, in fact, certain customers have actually reported reduced scatter after Laser Gold plating.

When Laser Gold is applied over glass, Zerodur, BK7 substrates, differences in the S & P polarization plane have been detected.

Certain customers have detected a difference in the S & P polarization plane when laser gold is applied over glass, Zerodure or BK7 substrates. In other words processes that involve vapor deposition prior to the Laser Gold application.

Substrates:
Laser Gold is usually applied over metal substrates including, but not limited to, aluminum, beryllium, copper, stainless, molybdenum, titanium. Non-metallic substrates such as Zerodur, silicon, quartz, BK7 etc. can also achieve the durability and reflectivity of Laser Gold by first applying a binder coating (usually chromium) by sputtering or vacuum deposition. (see specification plating and substrates)

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