The AOTF-based NO<sub>2</sub> camera

The AOTF-based NO<sub>2</sub> camera

The abundance of NO<sub>2</sub> in the boundary layer relates to air quality and pollution source monitoring. Observing the spatiotemporal distribution of NO<sub>2</sub> above well-delimited (flue gas stacks, volcanoes, ships) or more extended sources (cities) allows for appl...

Full description

Bibliographic Details
Main Authors: E. Dekemper, J. Vanhamel, B. Van Opstal, D. Fussen
Format: Article
Language:English
Published: Copernicus Publications 2016-12-01
Series:Atmospheric Measurement Techniques
Online Access:http://www.atmos-meas-tech.net/9/6025/2016/amt-9-6025-2016.pdf
id doaj-35a0676db21843c08df1a7ccfd67d15b
record_format Article
spelling doaj-35a0676db21843c08df1a7ccfd67d15b2020-11-24T22:43:25ZengCopernicus PublicationsAtmospheric Measurement Techniques1867-13811867-85482016-12-019126025603410.5194/amt-9-6025-2016The AOTF-based NO<sub>2</sub> cameraE. Dekemper0J. Vanhamel1B. Van Opstal2D. Fussen3Royal Belgian Institute for Space Aeronomy (BIRA-IASB), Avenue Circulaire 3, 1180 Brussels, BelgiumRoyal Belgian Institute for Space Aeronomy (BIRA-IASB), Avenue Circulaire 3, 1180 Brussels, BelgiumRoyal Belgian Institute for Space Aeronomy (BIRA-IASB), Avenue Circulaire 3, 1180 Brussels, BelgiumRoyal Belgian Institute for Space Aeronomy (BIRA-IASB), Avenue Circulaire 3, 1180 Brussels, BelgiumThe abundance of NO<sub>2</sub> in the boundary layer relates to air quality and pollution source monitoring. Observing the spatiotemporal distribution of NO<sub>2</sub> above well-delimited (flue gas stacks, volcanoes, ships) or more extended sources (cities) allows for applications such as monitoring emission fluxes or studying the plume dynamic chemistry and its transport. So far, most attempts to map the NO<sub>2</sub> field from the ground have been made with visible-light scanning grating spectrometers. Benefiting from a high retrieval accuracy, they only achieve a relatively low spatiotemporal resolution that hampers the detection of dynamic features. <br><br> We present a new type of passive remote sensing instrument aiming at the measurement of the 2-D distributions of NO<sub>2</sub> slant column densities (SCDs) with a high spatiotemporal resolution. The measurement principle has strong similarities with the popular filter-based SO<sub>2</sub> camera as it relies on spectral images taken at wavelengths where the molecule absorption cross section is different. Contrary to the SO<sub>2</sub> camera, the spectral selection is performed by an acousto-optical tunable filter (AOTF) capable of resolving the target molecule's spectral features. <br><br> The NO<sub>2</sub> camera capabilities are demonstrated by imaging the NO<sub>2</sub> abundance in the plume of a coal-fired power plant. During this experiment, the 2-D distribution of the NO<sub>2</sub> SCD was retrieved with a temporal resolution of 3 min and a spatial sampling of 50 cm (over a 250 × 250 m<sup>2</sup> area). The detection limit was close to 5 × 10<sup>16</sup> molecules cm<sup>−2</sup>, with a maximum detected SCD of 4 × 10<sup>17</sup> molecules cm<sup>−2</sup>. Illustrating the added value of the NO<sub>2</sub> camera measurements, the data reveal the dynamics of the NO to NO<sub>2</sub> conversion in the early plume with an unprecedent resolution: from its release in the air, and for 100 m upwards, the observed NO<sub>2</sub> plume concentration increased at a rate of 0.75–1.25 g s<sup>−1</sup>. In joint campaigns with SO<sub>2</sub> cameras, the NO<sub>2</sub> camera could also help in removing the bias introduced by the NO<sub>2</sub> interference with the SO<sub>2</sub> spectrum.http://www.atmos-meas-tech.net/9/6025/2016/amt-9-6025-2016.pdf
collection DOAJ
language English
format Article
sources DOAJ
author E. Dekemper
J. Vanhamel
B. Van Opstal
D. Fussen
spellingShingle E. Dekemper
J. Vanhamel
B. Van Opstal
D. Fussen
The AOTF-based NO<sub>2</sub> camera
Atmospheric Measurement Techniques
author_facet E. Dekemper
J. Vanhamel
B. Van Opstal
D. Fussen
author_sort E. Dekemper
title The AOTF-based NO<sub>2</sub> camera
title_short The AOTF-based NO<sub>2</sub> camera
title_full The AOTF-based NO<sub>2</sub> camera
title_fullStr The AOTF-based NO<sub>2</sub> camera
title_full_unstemmed The AOTF-based NO<sub>2</sub> camera
title_sort aotf-based no<sub>2</sub> camera
publisher Copernicus Publications
series Atmospheric Measurement Techniques
issn 1867-1381
1867-8548
publishDate 2016-12-01
description The abundance of NO<sub>2</sub> in the boundary layer relates to air quality and pollution source monitoring. Observing the spatiotemporal distribution of NO<sub>2</sub> above well-delimited (flue gas stacks, volcanoes, ships) or more extended sources (cities) allows for applications such as monitoring emission fluxes or studying the plume dynamic chemistry and its transport. So far, most attempts to map the NO<sub>2</sub> field from the ground have been made with visible-light scanning grating spectrometers. Benefiting from a high retrieval accuracy, they only achieve a relatively low spatiotemporal resolution that hampers the detection of dynamic features. <br><br> We present a new type of passive remote sensing instrument aiming at the measurement of the 2-D distributions of NO<sub>2</sub> slant column densities (SCDs) with a high spatiotemporal resolution. The measurement principle has strong similarities with the popular filter-based SO<sub>2</sub> camera as it relies on spectral images taken at wavelengths where the molecule absorption cross section is different. Contrary to the SO<sub>2</sub> camera, the spectral selection is performed by an acousto-optical tunable filter (AOTF) capable of resolving the target molecule's spectral features. <br><br> The NO<sub>2</sub> camera capabilities are demonstrated by imaging the NO<sub>2</sub> abundance in the plume of a coal-fired power plant. During this experiment, the 2-D distribution of the NO<sub>2</sub> SCD was retrieved with a temporal resolution of 3 min and a spatial sampling of 50 cm (over a 250 × 250 m<sup>2</sup> area). The detection limit was close to 5 × 10<sup>16</sup> molecules cm<sup>−2</sup>, with a maximum detected SCD of 4 × 10<sup>17</sup> molecules cm<sup>−2</sup>. Illustrating the added value of the NO<sub>2</sub> camera measurements, the data reveal the dynamics of the NO to NO<sub>2</sub> conversion in the early plume with an unprecedent resolution: from its release in the air, and for 100 m upwards, the observed NO<sub>2</sub> plume concentration increased at a rate of 0.75–1.25 g s<sup>−1</sup>. In joint campaigns with SO<sub>2</sub> cameras, the NO<sub>2</sub> camera could also help in removing the bias introduced by the NO<sub>2</sub> interference with the SO<sub>2</sub> spectrum.
url http://www.atmos-meas-tech.net/9/6025/2016/amt-9-6025-2016.pdf
work_keys_str_mv AT edekemper theaotfbasednosub2subcamera
AT jvanhamel theaotfbasednosub2subcamera
AT bvanopstal theaotfbasednosub2subcamera
AT dfussen theaotfbasednosub2subcamera
AT edekemper aotfbasednosub2subcamera
AT jvanhamel aotfbasednosub2subcamera
AT bvanopstal aotfbasednosub2subcamera
AT dfussen aotfbasednosub2subcamera
_version_ 1725696052312408064

Similar Items