Abstract
The design and performance of a room temperature electrical substitution radiometer for use as an absolute standard for measuring continuous-wave laser power over a wide range of wavelengths, beam diameters, and powers are described. The standard achieves an accuracy of 0.46% (k = 2) for powers from 10 mW to 100 mW and 0.83% (k = 2) for powers from 1 mW to 10 mW and can accommodate laser beam diameters (1/e2) up to 11mm and wavelengths from 300nm to 2 μm. At low power levels, the uncertainty is dominated by sensitivity to fluctuations in the thermal environment. The core of the instrument is a planar, silicon microfabricated bolometer with vertically aligned carbon nanotube absorbers, commercial surface mount thermistors, and an integrated heater. Where possible, commercial electronics and components were used. The performance was validated by comparing it to a National Institute of Standards and Technology primary standard through a transfer standard silicon trap detector and by comparing it to the legacy "C-series" standards in operation at the U.S. Air Force Metrology and Calibration Division (AFMETCAL).
Highlights
Electrical substitution radiometers (ESRs) serve as primary standards for optical power at National Metrology Institutes around the world.[1,2,3,4,5,6] At the NIST, calibrations of laser powermeters at continuous-wave (CW) powers ranging from 100 μW to 2 W are performed using “C-series” calorimeters.[7]
The core of the instrument is a planar, silicon microfabricated bolometer with vertically aligned carbon nanotube absorbers, commercial surface mount thermistors, and an integrated heater
The performance was validated by comparing it to a National Institute of Standards and Technology primary standard through a transfer standard silicon trap detector and by comparing it to the legacy “C-series” standards in operation at the U.S Air Force Metrology and Calibration Division (AFMETCAL)
Summary
Electrical substitution radiometers (ESRs) serve as primary standards for optical power at National Metrology Institutes around the world.[1,2,3,4,5,6] At the NIST, calibrations of laser powermeters at continuous-wave (CW) powers ranging from 100 μW to 2 W are performed using “C-series” calorimeters.[7] These calorimeters operate at room temperature and provide calibrations with an expanded uncertainty of 0.6%–0.8%, (k = 2).[8]. The first thermal loop maintains the base of the bolometer chip at a constant temperature near 20 ○C It uses the thermistor at the base of the heat link as the feedback sensor and the TEC underneath the copper block as the actuator. The second thermal loop maintains the absorber near 35 ○C by using the thermistor at the top of the heat link as the sensor
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