Aerosol Vertical Structure and Optical Properties during Two Dust and Haze Episodes in a Typical Valley Basin City, Lanzhou of Northwest China

Ma, Junyang; Bi, Jianrong; Li, Bowen; Zhu, Di; Wang, Xiting; Meng, Zhaozhao; Shi, Jinsen

doi:10.3390/rs16050929

Cited by 2 publications

(2 citation statements)

References 53 publications

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“…For example, Ma et al analyzed the atmospheric backscattering signals at three wavelengths, 266 nm, 289 nm, and 316 nm, to obtain ozone concentrations. They then used the backscattered signal at 532 nm to correct for the aerosol optical effects [34]. Lei et al studied the impact of aerosols emitted from wildfires on ozone concentration inversion using Differential Absorption Lidar.…”

Section: Discussionmentioning

confidence: 99%

Research on the Correction Algorithm for Ozone Inversion in Differential Absorption Lidar

Li,

Xie,

et al. 2024

Photonics

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Due to the complex and variable nature of the atmospheric conditions, traditional multi-wavelength differential absorption lidar (DIAL) methods often suffer from significant errors when inverting ozone concentrations. As the detection range increases, there is a higher demand for Signal to Noise Ratio (SNR) in lidar signals. Based on this, the paper discusses the impact of different atmospheric factors on the accuracy of ozone concentration inversion. It also compares the advantages and disadvantages of the two-wavelength differential method and the three-wavelength dual-differential method under both noisy and noise-free conditions. Firstly, the errors caused by air molecular extinction, aerosol extinction, and backscatter terms in the inversion using the two-wavelength differential method were simulated. Secondly, the corrected inversion errors were obtained through direct correction and the introduction of a three-wavelength dual differential correction. Finally, addressing the issue of insufficient SNR in practical inversions, the inversion errors of the two correction methods were simulated by constructing lidar parameters and incorporating appropriate noise. The results indicate that the traditional two-wavelength differential algorithm is significantly affected by aerosols, making it more sensitive to aerosol concentration and structural changes. On the other hand, the three-wavelength dual differential algorithm requires a higher SNR in lidar signals. Therefore, we propose a novel strategy for inverting atmospheric ozone concentration, which prioritizes the use of the three-wavelength dual-differential method in regions with high SNR and high aerosol concentration. Conversely, the direct correction method utilizing the two-wavelength differential approach is used. This approach holds the potential for high-precision ozone concentration profile inversion under different atmospheric conditions.

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Section: Discussionmentioning

confidence: 99%

Research on the Correction Algorithm for Ozone Inversion in Differential Absorption Lidar

Li,

Xie,

et al. 2024

Photonics

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“…A differential absorption ozone lidar (DIAL, LGO-01) manufactured by Anhui Landun Photoelectron Ltd., China, is deployed at the rooftop of an 8-story multifunctional office building in the main campus of Lanzhou University, which is located about 1 km east of the CE318-T photometer. The DIAL is a highly integrated instrument for synchronously detecting the vertical structures of ozone concentration within 3 km and aerosol extinction coefficient and depolarization ratio within 10 km (Ma et al, 2024). The DIAL shoots four pulse laser beams at nominal wavelengths of 266, 289, 316, and 532 nm into the atmosphere after laser collimation and beam expansion, and then collects the attenuated backscattering signals from atmospheric aerosol and ozone molecule with a 7.5-m spatial resolution and a 15-min time resolution.…”

Section: Ozone and Aerosol Lidarmentioning

confidence: 99%

Evaluation of Nocturnal Aerosol Optical Depth Determining From a Lunar Photometry in Lanzhou of Northwest China

Bi,

Li,

et al. 2024

JGR Atmospheres

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A Cimel Sun‐sky‐lunar photometer (CE318‐T) is designed to perform daytime and nighttime photometric measurements and calculate diurnal cycle of aerosol optical depth (AOD). Nevertheless, the determination of nocturnal AOD from CE318‐T requires a precise knowledge of extraterrestrial lunar irradiance, which significantly changes with moon's phase angle (MPA) and lunar libration in a single night. This study evaluated the 1‐year nocturnal AODs at Lanzhou by using three different methods, which were validated by collocated measurements of DIAL Lidar (as a reference) and Cimel software (as a proxy). The results indicated that three independent approaches could implement a similar performance to compute nocturnal AOD near full moon phase (i.e., MPA = 0°) under moderate aerosol loading. The spectral AOD values at nighttime calculated by ROLO Lunar Langley (Robotic Lunar Observatory model) and Sun‐moon Gain Factor (SMGF) methods are significantly underestimated under low moon's illumination or high MPA (MPA < −47° or MPA > 47°) and distinctly dependent on MPA. The RIMO correction factor (RCF) (ROLO Implementation for Moon photometry Observation correction factor) method could compensate the underestimated extraterrestrial lunar irradiances of ROLO model for about 6.76%–9.78%, and thus greatly improve the calculation accuracy of nighttime AOD. The day/night coherence transition test has demonstrated that we would obtain a good diurnal variation of AODs at Lanzhou after RCF correction. The overall averages of nocturnal AOD440nm differences between Cimel software and ROLO model and SMGF method are 0.064 ± 0.024 and 0.052 ± 0.022, respectively, while the corresponding difference of RCF is less than 0.021 ± 0.014 for all wavelengths, falling within uncertainty range of AERONET AOD products (∼±0.02). The diurnal variations of AODs determined from RCF method agree well with synchronous results of DIAL Lidar, with total mean AOD532nm differences of 0.038 ± 0.024 and 0.023 ± 0.017 in daytime and nighttime, respectively. The spectral AODs computed from RCF method are well consistent with Cimel software, although there are some discrepancies under low AOD cases (AOD440nm < 0.30), and the overall average of AOD440nm differences are less than −0.0053 ± 0.002 and −0.0185 ± 0.013 in daytime and nighttime, respectively. Our results confirmed that the CE318‐T photometer can be reasonably calculated nighttime AOD and Ångström exponent (AE440–870nm) at urban Lanzhou by using three independent methods, although the former two need to be greatly improved under low moon's illumination. The RCF method was proved to reliably calculate nocturnal AOD from moonlight irradiance, which didn't rely on MPA. A more accurate lunar irradiance model needs to be developed to improve the underestimation of current ROLO model. Long‐term climatological information of nocturnal AOD is crucial for comprehensively characterizing the diurnal variations of aerosol optical properties and atmospheric boundary layer structure during the winter at typical northern city of China, which deserves to be further investigated in the future.

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Aerosol Vertical Structure and Optical Properties during Two Dust and Haze Episodes in a Typical Valley Basin City, Lanzhou of Northwest China

Cited by 2 publications

References 53 publications

Research on the Correction Algorithm for Ozone Inversion in Differential Absorption Lidar

Research on the Correction Algorithm for Ozone Inversion in Differential Absorption Lidar

Evaluation of Nocturnal Aerosol Optical Depth Determining From a Lunar Photometry in Lanzhou of Northwest China

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