Aerosol sounding with a lidar system based on a DF laser

被引：19

作者：

Agroskin, VY ^{[1
]}

Bravy, BG ^{[1
]}

Chernyshev, YA ^{[1
]}

Kashtanov, SA ^{[1
]}

Kirianov, VI ^{[1
]}

Makarov, EF ^{[1
]}

Papin, VG ^{[1
]}

Sotnichenko, SA ^{[1
]}

Vasiliev, GK ^{[1
]}

机构：

[1] Russian Acad Sci, Inst Problems Chem Phys, Moscow 142432, Russia

来源：

APPLIED PHYSICS B-LASERS AND OPTICS | 2005年 / 81卷 / 08期

关键词：

D O I：

10.1007/s00340-005-1955-6

中图分类号：

O43 [光学];

学科分类号：

070207 ; 0803 ;

摘要：

These are the first experimental data obtained with a mobile aerosol lidar system based on a multiwavelength DF laser (lambda=3.6-4.2 mu m). The use of a polychromator and 10-channel recording system allowed us to determine the spectrum of aerosol backscattering by using only a single pulse of sounding laser radiation. The backscattering signals have been obtained from simulated aerosol clouds of different substances at a distance of 0.7 km. The obtained data confirm the applicability of aerosol backscattering spectra for recognition of aerosol impurities in the atmosphere. Satisfactory agreement between the measured and theoretically predicted spectral behavior of backscattering was attained under the assumption that our aerosol particles had been coated with a water layer 10 mu m thick.

引用

页码：1149 / 1154

页数：6

共 50 条

[31] Retrieval of integral parameters of tropospheric aerosol from two-wavelength lidar sounding
Korshunov, V. A.
IZVESTIYA ATMOSPHERIC AND OCEANIC PHYSICS, 2007, 43 (05) : 618 - 633
[32] Range-resolved atmospheric aerosol monitoring by a Scheimpflug lidar system based on a continuous-wave laser diode
Guan, Peng
Mei, Liang
2016 ASIA COMMUNICATIONS AND PHOTONICS CONFERENCE (ACP), 2016,
[33] Laser frequency converters for aerosol and gas lidar systems
Andreev, YM
Geiko, PP
SEVENTH INTERNATIONAL SYMPOSIUM ON ATMOSPHERIC AND OCEAN OPTICS, 2000, 4341 : 420 - 425
[34] A pulsed diode laser for tectonic aerosol lidar sensing
Pershin, S. M.
Dolgikh, G., I
Makarov, V. S.
Turin, A., V
Grishin, M. Ya
Zavozin, V. A.
Lednev, V. N.
Plotnikov, A. A.
2019 IEEE 8TH INTERNATIONAL CONFERENCE ON ADVANCED OPTOELECTRONICS AND LASERS (CAOL), 2019, : 75 - 78
[35] SIBERIAN LIDAR STATION: THE BASIC COMPLEX OF REMOTE LASER SOUNDING OF THE ATMOSPHERE
Romanovskii, O. A.
Matvienko, G. G.
Balin, Yu. S.
Bobrovnikov, S. M.
Nevzorov, A. V.
LIDAR TECHNOLOGIES, TECHNIQUES, AND MEASUREMENTS FOR ATMOSPHERIC REMOTE SENSING XIII, 2017, 10429
[36] Lidar sounding of turbulence based on the backscatter enhancement effect
Gurvich, A. S.
IZVESTIYA ATMOSPHERIC AND OCEANIC PHYSICS, 2012, 48 (06) : 585 - 594
[37] Lidar sounding of turbulence based on the backscatter enhancement effect
A. S. Gurvich
Izvestiya, Atmospheric and Oceanic Physics, 2012, 48 : 585 - 594
[38] Aerosol layers in the atmosphere observed by vertical-sounding lidar as an indication of mixing layer height - comparison with acoustic sounding data
Walczewski, J
Bielak, A
Kaszowski, W
OPTICA APPLICATA, 1999, 29 (04) : 449 - 459
[39] A Study of the Characteristics of Highly Spatially Resolved CW-laser-based Aerosol Lidar
Sim, Juhyeon
Kim, Taekeong
Ju, Sohee
Noh, Youngmin
Kim, Dukhyeon
KOREAN JOURNAL OF OPTICS AND PHOTONICS, 2022, 33 (01) : 1 - 10
[40] Stable procedure for retrieving optical characteristics of aerosol fields from combination lidar sounding data
Samoilova, SV
Balin, YS
Ershov, AD
IZVESTIYA ATMOSPHERIC AND OCEANIC PHYSICS, 2003, 39 (03) : 346 - 354

← 1 2 3 4 5 →