{"title":"西北喜马拉雅地区气溶胶光学深度和气溶胶辐射强迫的变率","authors":"Shaik Darga Saheb, Y. Kant, D. Mitra","doi":"10.1117/12.2223641","DOIUrl":null,"url":null,"abstract":"In recent years, the aerosol loading in India is increasing that has significant impact on the weather/climatic conditions. The present study discusses the analysis of temporal (monthly and seasonal) variation of aerosol optical depth(AOD) by the ground based observations from sun photometer and estimate the aerosol radiative forcing and heating rate over selected station Dehradun in North western Himalayas, India during 2015. The in-situ measurements data illustrate that the maximum seasonal average AOD observed during summer season AOD at 500nm ≈ 0.59±0.27 with an average angstrom exponent, α ≈0.86 while minimum during winter season AOD at 500nm ≈ 0.33±0.10 with angstrom exponent, α ≈1.18. The MODIS and MISR derived AOD was also compared with the ground measured values and are good to be in good agreement. Analysis of air mass back trajectories using HYSPLIT model reveal that the transportation of desert dust during summer months. The Optical Properties of Aerosols and clouds (OPAC) model was used to compute the aerosol optical properties like single scattering albedo (SSA), Angstrom coefficient (α) and Asymmetry(g) parameter for each day of measurement and they are incorporated in a Discrete Ordinate Radiative Transfer model, i.e Santa Barbara DISORT Atmospheric Radiative Transfer (SBDART) to estimate the direct short-wave (0.25 to 4 μm) Aerosol Radiative forcing at the Surface (SUR), the top-of-atmosphere (TOA) and Atmosphere (ATM). The maximum Aerosol Radiative Forcing (ARF) was observed during summer months at SUR ≈ -56.42 w/m2, at TOA ≈-21.62 w/m2 whereas in ATM ≈+34.79 w/m2 with corresponding to heating rate 1.24°C/day with in lower atmosphere.","PeriodicalId":165733,"journal":{"name":"SPIE Asia-Pacific Remote Sensing","volume":"48 1","pages":"0"},"PeriodicalIF":0.0000,"publicationDate":"2016-05-06","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Variability of aerosol optical depth and aerosol radiative forcing over Northwest Himalayan region\",\"authors\":\"Shaik Darga Saheb, Y. Kant, D. Mitra\",\"doi\":\"10.1117/12.2223641\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"In recent years, the aerosol loading in India is increasing that has significant impact on the weather/climatic conditions. The present study discusses the analysis of temporal (monthly and seasonal) variation of aerosol optical depth(AOD) by the ground based observations from sun photometer and estimate the aerosol radiative forcing and heating rate over selected station Dehradun in North western Himalayas, India during 2015. The in-situ measurements data illustrate that the maximum seasonal average AOD observed during summer season AOD at 500nm ≈ 0.59±0.27 with an average angstrom exponent, α ≈0.86 while minimum during winter season AOD at 500nm ≈ 0.33±0.10 with angstrom exponent, α ≈1.18. The MODIS and MISR derived AOD was also compared with the ground measured values and are good to be in good agreement. Analysis of air mass back trajectories using HYSPLIT model reveal that the transportation of desert dust during summer months. The Optical Properties of Aerosols and clouds (OPAC) model was used to compute the aerosol optical properties like single scattering albedo (SSA), Angstrom coefficient (α) and Asymmetry(g) parameter for each day of measurement and they are incorporated in a Discrete Ordinate Radiative Transfer model, i.e Santa Barbara DISORT Atmospheric Radiative Transfer (SBDART) to estimate the direct short-wave (0.25 to 4 μm) Aerosol Radiative forcing at the Surface (SUR), the top-of-atmosphere (TOA) and Atmosphere (ATM). 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引用次数: 0
摘要
近年来,印度的气溶胶负荷不断增加,对天气/气候条件产生了重大影响。本文利用太阳光度计地面观测资料分析了气溶胶光学深度(AOD)的时间(月和季节)变化,并估算了2015年印度喜马拉雅山西北部德拉敦站气溶胶辐射强迫和升温速率。实测数据表明,夏季平均AOD最大值为500nm≈0.59±0.27,平均埃指数为α≈0.86;冬季平均AOD最小值为500nm≈0.33±0.10,平均埃指数为α≈1.18。MODIS和MISR计算的AOD也与地面测量值进行了比较,结果吻合较好。利用HYSPLIT模式对气团反轨迹进行分析,揭示了夏季沙尘的输送。利用OPAC (Optical Properties of aerosol and cloud)模式计算了每天的气溶胶光学特性,如单散射反照率(SSA)、埃斯特系数(α)和不对称性(g)参数,并将其纳入离散坐标辐射传输模型,即圣巴巴拉DISORT大气辐射传输(SBDART),以估计直接短波(0.25 ~ 4 μm)气溶胶在地表的辐射强迫(SUR)。大气顶(TOA)和大气(ATM)。夏季气溶胶辐射强迫(ARF)最大值为:SUR≈-56.42 w/m2, TOA≈-21.62 w/m2,而ATM≈+34.79 w/m2,对应的升温速率为1.24℃/d,低层大气。
Variability of aerosol optical depth and aerosol radiative forcing over Northwest Himalayan region
In recent years, the aerosol loading in India is increasing that has significant impact on the weather/climatic conditions. The present study discusses the analysis of temporal (monthly and seasonal) variation of aerosol optical depth(AOD) by the ground based observations from sun photometer and estimate the aerosol radiative forcing and heating rate over selected station Dehradun in North western Himalayas, India during 2015. The in-situ measurements data illustrate that the maximum seasonal average AOD observed during summer season AOD at 500nm ≈ 0.59±0.27 with an average angstrom exponent, α ≈0.86 while minimum during winter season AOD at 500nm ≈ 0.33±0.10 with angstrom exponent, α ≈1.18. The MODIS and MISR derived AOD was also compared with the ground measured values and are good to be in good agreement. Analysis of air mass back trajectories using HYSPLIT model reveal that the transportation of desert dust during summer months. The Optical Properties of Aerosols and clouds (OPAC) model was used to compute the aerosol optical properties like single scattering albedo (SSA), Angstrom coefficient (α) and Asymmetry(g) parameter for each day of measurement and they are incorporated in a Discrete Ordinate Radiative Transfer model, i.e Santa Barbara DISORT Atmospheric Radiative Transfer (SBDART) to estimate the direct short-wave (0.25 to 4 μm) Aerosol Radiative forcing at the Surface (SUR), the top-of-atmosphere (TOA) and Atmosphere (ATM). The maximum Aerosol Radiative Forcing (ARF) was observed during summer months at SUR ≈ -56.42 w/m2, at TOA ≈-21.62 w/m2 whereas in ATM ≈+34.79 w/m2 with corresponding to heating rate 1.24°C/day with in lower atmosphere.
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