A researcher from NIST (National Institute of Standards and Technology), the national measurement institute of the USA, recently visited the UK to utilise NPL's world-leading facilities for measuring the optical properties of materials, and specifically for measuring reflectance of samples in the infrared.
Out of all the measurement institutes around the world, NPL is capable of making these measurements over the widest range of infrared wavelengths.
In the USA, NIST is developing a fibre-coupled cryogenic radiometer that links optical fibre power measurements directly to fundamental electrical units at the 10 nW power level.
Such a device could have a role in telecommunications, medical devices and other industries that require ultra low power calibrations.
Cryogenic radiometry was first developed at NPL. It works by absorbing optical power which causes a temperature rise in the absorber.
The amount of electrical power needed to induce the same temperature rise is then measured. To make the most accurate measurements, the device needs to employ a surface that absorbs the largest amount of optical energy possible, and reflects the least.
A coating of carbon nanotubes, arranged so that they stand vertically on the surface like a forest of trees, provide this surface.
The arrangement forms the lowest reflective, or darkest, surface known to man and only NPL's facilities are capable of making the required measurements of reflected infrared light to test it.
Two facilities were used at NPL: the first, based on a grating spectrometer and integrating sphere, covers the range of the electromagnetic spectrum from visible light to a wavelength of 2.5 µm; and the second facility uses a Fourier transform spectrometer and reflecting hemisphere to cover the range from 2.5 µm to 50 µm.
The measurements made during this project represent the first ever reflectance measurements of materials with reflectance less than 1% in the 15–50 µm region and confirm that the NIST carbon nanotube coatings have the lowest known reflectance in the infrared region.
NPL and NIST have collaborated since 2003 to assess the benefits to the performance of thermal detectors obtained by using carbon nanotube coatings, and half a dozen papers have been jointly authored reporting those findings.
The current work has expanded NPL's collaboration with NIST and is described in a paper submitted for publication in a peer-reviewed journal.
More on NPL's work on Optical Radiation and Photonics
More on NPL's work on Reflected Light
For further information, please contact Christopher Chunnilall or Theo Theocharous
Out of all the measurement institutes around the world, NPL is capable of making these measurements over the widest range of infrared wavelengths.
In the USA, NIST is developing a fibre-coupled cryogenic radiometer that links optical fibre power measurements directly to fundamental electrical units at the 10 nW power level.
Such a device could have a role in telecommunications, medical devices and other industries that require ultra low power calibrations.
Cryogenic radiometry was first developed at NPL. It works by absorbing optical power which causes a temperature rise in the absorber.
The amount of electrical power needed to induce the same temperature rise is then measured. To make the most accurate measurements, the device needs to employ a surface that absorbs the largest amount of optical energy possible, and reflects the least.
A coating of carbon nanotubes, arranged so that they stand vertically on the surface like a forest of trees, provide this surface.
The arrangement forms the lowest reflective, or darkest, surface known to man and only NPL's facilities are capable of making the required measurements of reflected infrared light to test it.
Two facilities were used at NPL: the first, based on a grating spectrometer and integrating sphere, covers the range of the electromagnetic spectrum from visible light to a wavelength of 2.5 µm; and the second facility uses a Fourier transform spectrometer and reflecting hemisphere to cover the range from 2.5 µm to 50 µm.
The measurements made during this project represent the first ever reflectance measurements of materials with reflectance less than 1% in the 15–50 µm region and confirm that the NIST carbon nanotube coatings have the lowest known reflectance in the infrared region.
NPL and NIST have collaborated since 2003 to assess the benefits to the performance of thermal detectors obtained by using carbon nanotube coatings, and half a dozen papers have been jointly authored reporting those findings.
The current work has expanded NPL's collaboration with NIST and is described in a paper submitted for publication in a peer-reviewed journal.
More on NPL's work on Optical Radiation and Photonics
More on NPL's work on Reflected Light
For further information, please contact Christopher Chunnilall or Theo Theocharous
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