Single laser-based differential absorption lidar (DIAL) for remote profiling atmospheric oxygen
Single laser-based differential absorption lidar (DIAL) for remote profiling atmospheric oxygen
Recently, we have demonstrated a longitudinally pumped tunable
dual-wavelength Ti:sapphire laser that can operate at simultaneous
dual-wavelength (765.0, 771.3 nm), (763.9, 772.2 nm), (763.5, 772.2 nm)
and (762.4, 773.7 nm) with a pulse width of ∼20 ns and a maximum
average power of ∼2.98 W at 1-kHz pulse repetition rate,
corresponding to a slope efficiency of ∼34.7% [1]. In this paper,
the feasibility of the contactless differential absorption lidar (DIAL)
equipped with the dual-wavelength laser emitting at 762 nm
(on-wavelength) and 773 nm (off-wavelength) on remote 3D-measurement of
molecular oxygen, O2, has been investigated. Absorption by
atmospheric oxygen A-band at 761.9 nm corresponds to the magnetic dipole
transition b1
Σb+(v‧ = 0)
←X3 Σg-(v″
= 0) with absorption cross section of 5.749 ×
10-3 cm-2 atm-1 at STP. The
accuracy and dynamic range of the DIAL measurement can be extended by
simultaneous transmission and detection the spectrally close "on" and
"off" wavelengths generated in a compact single laser, in addition to
reduce the cost, volume, and weight of the system. The results
demonstrate that a concentration of less than 1 ppm by volume is
detectable by the system if a path length of 1 km is used. It is
noticeable that the wavelengths 762 nm and 773 nm in the near-infrared
window spectral range (650-950 nm) allow lidar system to monitor
dissolved oxygen in ambient water. This system can also be used from a
satellite to quickly characterize O2 in H2O
matrices in the outer solar system bodies.
DIAL, Dual-wavelength laser, Laser remote sensing, Near-infrared (NIR) window, Oxygen (O), Oxygen A-band absorption
80-85
Shayeganrad, Gholamreza
8ea55a9a-4fe2-49df-a0f4-55fa81596dab
1 December 2018
Shayeganrad, Gholamreza
8ea55a9a-4fe2-49df-a0f4-55fa81596dab
Shayeganrad, Gholamreza
(2018)
Single laser-based differential absorption lidar (DIAL) for remote profiling atmospheric oxygen.
Optics and Lasers in Engineering, 111 (12), .
(doi:10.1016/j.optlaseng.2018.07.015).
Abstract
Recently, we have demonstrated a longitudinally pumped tunable
dual-wavelength Ti:sapphire laser that can operate at simultaneous
dual-wavelength (765.0, 771.3 nm), (763.9, 772.2 nm), (763.5, 772.2 nm)
and (762.4, 773.7 nm) with a pulse width of ∼20 ns and a maximum
average power of ∼2.98 W at 1-kHz pulse repetition rate,
corresponding to a slope efficiency of ∼34.7% [1]. In this paper,
the feasibility of the contactless differential absorption lidar (DIAL)
equipped with the dual-wavelength laser emitting at 762 nm
(on-wavelength) and 773 nm (off-wavelength) on remote 3D-measurement of
molecular oxygen, O2, has been investigated. Absorption by
atmospheric oxygen A-band at 761.9 nm corresponds to the magnetic dipole
transition b1
Σb+(v‧ = 0)
←X3 Σg-(v″
= 0) with absorption cross section of 5.749 ×
10-3 cm-2 atm-1 at STP. The
accuracy and dynamic range of the DIAL measurement can be extended by
simultaneous transmission and detection the spectrally close "on" and
"off" wavelengths generated in a compact single laser, in addition to
reduce the cost, volume, and weight of the system. The results
demonstrate that a concentration of less than 1 ppm by volume is
detectable by the system if a path length of 1 km is used. It is
noticeable that the wavelengths 762 nm and 773 nm in the near-infrared
window spectral range (650-950 nm) allow lidar system to monitor
dissolved oxygen in ambient water. This system can also be used from a
satellite to quickly characterize O2 in H2O
matrices in the outer solar system bodies.
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More information
Accepted/In Press date: 26 July 2018
e-pub ahead of print date: 9 August 2018
Published date: 1 December 2018
Additional Information:
Publisher Copyright:
© 2018 Elsevier Ltd
Keywords:
DIAL, Dual-wavelength laser, Laser remote sensing, Near-infrared (NIR) window, Oxygen (O), Oxygen A-band absorption
Identifiers
Local EPrints ID: 479089
URI: http://eprints.soton.ac.uk/id/eprint/479089
ISSN: 0143-8166
PURE UUID: 5e0b0b89-d750-4bca-b99d-773528c7e2fe
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Date deposited: 20 Jul 2023 16:32
Last modified: 17 Mar 2024 03:53
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