• Title/Summary/Keyword: Raman Lidar

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The Measurement of the LIDAR Ratio by Using the Rotational Raman LIDAR

  • Choi, Sung-Chul;Baik, Sung-Hoon;Park, Seung-Kyu;Cha, Hyung-Ki;Song, Im-Kang;Kim, Duk-Hyeon
    • Journal of the Optical Society of Korea
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    • v.14 no.3
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    • pp.174-177
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    • 2010
  • The rotational Raman LIDAR technique has been used to accurately measure aerosol optical properties such as backscatter coefficient, extinction coefficient, and LIDAR ratio. In the case of the vibrational Raman technique, the ${\AA}$ngstr$\ddot{o}$om exponent, which has wavelength dependence on the particle properties, is assumed to obtain the extinction coefficient. However, this assumed ${\AA}$ngstr$\ddot{o}$m exponent can cause systematic errors in retrieving aerosol optical properties. In the case of the rotational Raman technique, the aerosol optical properties can be measured without any assumptions about the ${\AA}$ngstr$\ddot{o}$m exponent. In this paper, the LIDAR ratio was measured by using the rotational Raman LIDAR and vibrational Raman LIDAR in the troposphere. And, the LIDAR ratios measured by these two methods were compared.

Measurements of the Lidar Ratio for Asian Dust and Pollution Aerosols with a Combined Raman and Back-scatter Lidar (라만-탄성 라이다를 이용한 황사 및 오염 에어러솔의 라이다 비 측정 연구)

  • Yoon, S.C.;Lee, Y.J.;Kim, S.W.;Kim, M.H.;Sugimoto, N.
    • Atmosphere
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    • v.20 no.4
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    • pp.483-494
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    • 2010
  • The vertical profiles of the extinction coefficient, the backscatter coefficient, and the lidar ratio (i.e., extinction-to-backscattering ratio) for Asian dust and pollution aerosols are determined from Raman (inelastic) and elastic backscatter signals. The values of lidar ratios during two polluted days is found between 52 and 82 sr (July 22, 2009) and 40~60 sr (July 31, 2009) at 52 nm, with relatively low value of particle depolarization ratio (<5%) and high value of sun photometer-derived Angstrom exponent (> 1.2). However, lidar ratios between 25 and 40 sr are found during two Asian dust periods (October 20, 2009 and March 15, 2010), with 10~20% of particle depolarization ratio and the relatively low value of sun photometer-derived Angstrom exponent (< 0.39). The lidar ratio, particle depolarization ratio and color ratio are useful optical parameter to distinguish non-spherical coarse dust and spherical fine pollution aerosols. The comparison of aerosol extinction profiles determined from inelastic-backscatter signals by the Raman method and from elastic-backscatter signals by using the Fernald method with constant value of lidar ratio (50 sr) have shown that reliable aerosol extinction coefficients cannot be determined from elastic-backscatter signals alone, because the lidar ratio varies with aerosol types. A combined Raman and elastic backscatter lidar system can provide reliable information about the aerosol extinction profile and the aerosol lidar ratio.

Development of a Raman Lidar System Using the Photon-counting Method to Measure Carbon Dioxide (이산화탄소 원격 계측을 위한 광 계수 방식의 라만 라이다 장치 개발)

  • Sun Ho Park;In Young Choi;Moon Sang Yoon
    • Korean Journal of Optics and Photonics
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    • v.35 no.2
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    • pp.71-80
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    • 2024
  • We developed a Raman lidar system for remote measurement of carbon dioxide present in atmospheric space. An air-cooled laser with 355-nm wavelength and a 6-inch optical receiver was used to miniaturize the Raman lidar system, and a scanning Raman lidar system was developed using a two-axis scanning device and a photon counter. To verify the performance of the developed Raman lidar system, a gas chamber capable of maintaining a concentration was located at a distance of about 87 m, and the change in Raman signal according to the change in the concentration of carbon dioxide was measured. As a result, it was confirmed that the change in the Raman scattering signal of carbon dioxide that appeared for a change in carbon dioxide concentration from about 0.67 to 40 vol% was linear, and the coefficient of determination (R2) value, which indicates the correlation between the carbon dioxide concentration and Raman scattering signal, showed a high linearity of 0.9999.

Ambient CO2 Measurement Using Raman Lidar (라만 라이다를 이용한 대기 중 이산화탄소 혼합비 측정)

  • Kim, Daewon;Lee, Hanlim;Park, Junsung;Choi, Wonei;Yang, Jiwon;Kang, Hyeongwoo
    • Korean Journal of Remote Sensing
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    • v.35 no.6_3
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    • pp.1187-1195
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    • 2019
  • We, for the first time, developed a Raman lidar system which can remotely detect surface CO2 volume mixing ratio (VMR). The Raman lidar system consists of the Nd: YAG laser of wavelength 355 nm with 80 mJ, an optical receiver, and detectors. Indoor CO2 cell measurements show that the accuracy of the Raman lidar system is calculated to be 99.89%. We carried out the field measurement using our Raman lidar at Pukyong National University over a seven-day period in October 2019. The results show good agreement between CO2 VMRs measured by the Raman lidar (CO2 Raman Lidar) and those measured by in situ instruments (CO2 In situ) which located 300 m and 350 m away from the Raman lidar system. The correlation coefficient (R), mean absolute error (MAE), and root mean square error (RMSE) between CO2 In situ and CO2 Raman Lidar are 0.67, 2.78 ppm, and 3.26 ppm, respectively.

Study of a Method for Measuring Hydrogen Gas Concentration Using a Photon-counting Raman Lidar System (광 계수 방식의 라만 라이다 시스템을 이용한 원격 수소 가스 농도 계측 방법에 대한 연구)

  • Choi, In Young;Baik, Sung Hoon;Cha, Jung Ho;Kim, Jin Ho
    • Korean Journal of Optics and Photonics
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    • v.30 no.3
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    • pp.114-119
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    • 2019
  • This paper discusses the development of a Raman lidar system for remote detection and measurement of hydrogen gas by using a photon counter. The Raman signal of the hydrogen gas is very weak and has a very low signal-to-noise ratio. The photon counter has the advantage of improving the signal-to-noise ratio, because it has a discriminator to eliminate the background noise from the Raman signal of the hydrogen gas. Therefore, a small and portable Raman lidar system was developed using a low-power pulsed laser and a photon-counter system to measure the hydrogen gas concentration remotely. To verify the capability of measuring hydrogen gas using the developed photon-counting Raman lidar system, experiments were carried out using a gas chamber in which it is possible to adjust the hydrogen gas concentration. As a result, our photon-counting Raman lidar system is seen to measure a minimum concentration of 0.65 vol.% hydrogen gas at a distance of 10 m.

Retrieval of Lidar Overlap Factor using Raman Lidar System (라만 라이다 시스템을 이용한 라이다 중첩함수 산출)

  • Noh, Young-M.;Muller, Detlef;Shin, Dong-Ho;Lee, Kyung-Hwa
    • Journal of Korean Society for Atmospheric Environment
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    • v.25 no.5
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    • pp.450-458
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    • 2009
  • The range-dependent overlap factor of a lidar system can be determined experimentally if a Raman backscatter signal by molecule is measured in addition to the usually observed elastic backscatter signal, which consists of a molecular component and a particle component. The direct determination of the overlap profile is presented and applied to a lidar measurement according to variation of telescope field-of-view and distance between telescope and transmitting laser. The retrieval of extinction coefficient by Raman method can generate high errors for heights below planetary boundary layer if the overlap effect is ignored. The overlap correction method presented here has been successfully applied to experimental data obtained in Gwangju, Korea.

A Retrieval of Vertically-Resolved Asian Dust Concentration from Quartz Channel Measurements of Raman Lidar (라만 라이다의 석영 채널을 이용한 고도별 황사 농도 산출)

  • Noh, Young-Min;Lee, Kwon-Ho;Lee, Han-Lim
    • Journal of Korean Society for Atmospheric Environment
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    • v.27 no.3
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    • pp.326-336
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    • 2011
  • The Light Detection and Ranging (Lidar) observation provides a specific knowledge of the temporal and vertical distribution and the optical properties of the aerosols. Unlike typical Mie scattering Lidars, which can measure backscattering and depolarization, the Raman Lidar can measure the quartz signal at the ultra violet (360 nm) and the visible (546 nm) wavelengths. In this work, we developed a method for estimating mineral quartz concentration immersed in Asian dust using Raman scattering of quartz (silicon dioxide, silica). During the Asian dust period of March 15, 16, and 21 in 2010, Raman lidar measurements detected the presence of quartz, and successfully showed the vertical profile of the dust concentrations. The satellite observations such as the Moderate Resolution Imaging Spectroradiometer (MODIS) and the Cloud-Aerosol Lidar and Infrared Pathfinder Satellite Observations (CALIPSO) confirmed spatial distribution of Asian dust. This approach will be useful for characterizing the quartz dominated in the atmospheric aerosols and the investigations of mineral dust. It will be especially applicable for distinguishing the dust and non-dust aerosols in studies on the mixing state of Asian aerosols. Additionally, the presented method combined with satellite observations is enable qualitative and quantitative monitoring for Asian dust.

A Basic Study for the Performance Evaluation of a Raman LiDAR Detector for Detecting Hydrogen Gas (수소 가스 검출용 라만 라이다 측정기의 성능 평가를 위한 기초 연구)

  • WONBO CHO;YUNKYU LIM;YANGKYUN KIM;BYOUNGJIK PARK
    • Journal of Hydrogen and New Energy
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    • v.34 no.2
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    • pp.205-211
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    • 2023
  • Hydrogen gas is light and diffuses very quickly. Therefore, when a leakage accident occurs, the damage is great, so a technology that can quickly measure the leakage in the air at a long distance is needed. In order to develop hydrogen gas leaked in the atmosphere in a non-contact manner, an experiment was performed to measure hydrogen gas using a lidar technology using the Raman effect. Hydrogen Raman signals were detected using a UV LED light source, which is a Raman light source, and a spectrometer in the ultraviolet region including an optical filter in the 400-430 nm band. To develop this, a Raman lidar optical structure was designed to measure the hydrogen Raman signal at a certain distance, and the hydrogen Raman spectrum was confirmed using a standard gas to evaluate the performance of this optical structure. The linearity was found to be 0.99 using hydrogen standard gas (10, 50, 100, 500, 1,000 ppm). Accordingly, a Raman lidar capable of measuring hydrogen gas rapidly diffusing in the air in an open state was developed to improve the limitations of existing hydrogen sensors.

Development of Raman LIDAR System to Measure Vertical Water Vapor Profiles and Comparision of Raman LIDAR with GNSS and MWR Systems (수증기의 연직 분포 측정을 위한 라만 라이다 장치의 개발 및 GNSS, MWR 장비와 상호 비교연구)

  • Park, Sun-Ho;Kim, Duk-Hyeon;Kim, Yong-Gi;Yun, Mun-Sang;Cheong, Hai-Du
    • Korean Journal of Optics and Photonics
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    • v.22 no.6
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    • pp.283-290
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    • 2011
  • A Raman LIDAR system has been designed and constructed for quantitative measurement of water vapor mixing ratio. The comparison with commercial microwave radiometer and global navigation satellite system(GNSS) was performed for the precipitable water vapor(PWV) profile and total PWV. The result shows that the total GNSS-PWV and LIDAR-PWV have good correlation with each other. But, there is small difference between the two methods because of maximum measurement height in LIDAR and the GNSS method. There are some significant differences between Raman and MWR when the water vapor concentration changes quickly near the boundary layer or at the edge of a cloud. Finally we have decided that MWR cannot detect spatial changes but LIDAR can measure spatial changes.