Radiation-Pressure-Enabled Traceable Laser Sources at CW Powers up to 50 kW

Radiation pressure has recently been shown to have practical application for multikilowatt continuous wave (CW) laser power measurement. One key advantage lies in its ability to measure without absorbing the laser beam. This enables a new measurement paradigm where laser power can be measured traceable to the SI without perturbing the beam. Combining this measurement scheme with a laser constitutes a “traceable source” where laser output power is traceable to the SI in real time. This greatly simplifies the calibration process for multikilowatt laser power meters and yields a path to high-accuracy laser-based material processing. Here, we discuss the state of the art of this approach by describing recent results from calibrations of laser power meters performed using a radiation-pressure-enabled traceable source at CW powers from 1 to 50 kW. We describe measurement results and uncertainty contributions with expanded uncertainties at or below 1.7% for powers above 10 kW. We also briefly discuss the status of development of a radiation-pressure-based technology designed to provide source traceability in the laser manufacturing environment.

[1]  Jon R. Pratt,et al.  A self-calibrating optomechanical force sensor with femtonewton resolution , 2014, 1410.5725.

[2]  J. Lehman,et al.  Flowing-water optical power meter for primary-standard, multi-kilowatt laser power measurements , 2018 .

[3]  Yipeng Yuan A new pulse laser energy meter , 1990 .

[4]  H. Kellock A calorimeter for infra-red laser power measurement , 1969 .

[5]  J. Lehman,et al.  Use of radiation pressure for measurement of high-power laser emission. , 2013, Optics letters.

[6]  J. Lehman,et al.  Onsite multikilowatt laser power meter calibration using radiation pressure. , 2017, Applied optics.

[7]  Dakang Ma,et al.  Quantitative measurement of radiation pressure on a microcantilever in ambient environment , 2015 .

[8]  Michelle Stephens,et al.  Micromachined Force Scale for Optical Power Measurement by Radiation Pressure Sensing , 2018, IEEE Sensors Journal.

[9]  Barry N. Taylor,et al.  Guidelines for Evaluating and Expressing the Uncertainty of Nist Measurement Results , 2017 .

[10]  Michelle Stephens,et al.  Portable, high-accuracy, non-absorbing laser power measurement at kilowatt levels by means of radiation pressure. , 2017, Optics express.

[11]  Alvin L. Rasmussen,et al.  A Calorimeter for High-Power CW Lasers , 1972 .

[12]  K. Agatsuma,et al.  Precise measurement of laser power using an optomechanical system. , 2013, Optics express.

[13]  Alexandra B. Artusio-Glimpse,et al.  Progress Toward Radiation-Pressure-Enabled Traceable Laser Sources , 2018, 2018 Conference on Precision Electromagnetic Measurements (CPEM 2018).

[14]  Uwe Brand,et al.  A new facility to realize a nanonewton force standard based on electrostatic methods , 2009 .

[15]  Z. I. Slawsky,et al.  Torsion Pendulum Photometer , 1964 .

[16]  A. Nath,et al.  Spinning cone water film power meter for high-power CO2 lasers , 2007 .

[17]  J. Cook,et al.  MEASUREMENT OF LASER OUTPUT BY LIGHT PRESSURE , 1962 .

[18]  D Villate,et al.  RLCYC 75 : a 2 kW electrically calibrated laser calorimeter designed for Laser MegaJoule diagnostics calibration , 2013 .