Tracing the physical signatures among the calculated global clear-sky spectral shortwave radiative flux distribution

IF 2.3 3区 物理与天体物理 Q2 OPTICS
Xiang Zhong , Xiquan Dong , Baike Xi , Jordann Brendecke , Peter Pilewskie
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Abstract

This study utilized the high-spectral resolution radiative transfer model (MODerate resolution atmospheric TRANsmission, MODTRAN6.0.2.5) to compute global clear-sky shortwave (SW) radiative flux and compared it with NASA’s Clouds and the Earth’s Radiant Energy System (CERES) Synoptic Radiative Fluxes and Clouds (SYN1deg) product. The comparison revealed that the global distributions of clear-sky downwelling SW fluxes at the surface from the M6.0 calculations and SYN1 results are similar, with annual means of 246.51 Wm-2 and 242.42 Wm-2, respectively. Analysis further showed that most of the M6.0 calculations are slightly higher from low to mid-latitudes, particularly in the Northern Hemisphere (NH), but lower in higher latitudes compared to SYN1 results. However, these differences mostly fall within the CERES estimated uncertainty (6 Wm-2) of monthly mean clear-sky downwelling SW flux at the surface. The sensitivity of clear-sky SW/μ0 fluxes to changes in Precipitable Water Vapor (PWV), represented by the clear-sky water vapor radiative kernel, is about -0.7 Wm-2/(kgm-2) over oceans for both M6.0 and CERES SYN1 products, except for SYN1 results over the Southern Hemisphere (SH) ocean. Additionally, the zonal means of land coverage and SW/VIS/NIR albedos from M6.0 calculations indicate that VIS albedos are highest in polar regions (>60°), followed by SW and NIR albedos, while NIR albedos become highest from low to mid-latitudes (<60°). Generally, SW/VIS/NIR albedos and their differences increase monotonically with increased land coverage from 60°S to 60°N. The consistent clear-sky water vapor radiative kernels derived from both products exceeded our expectations, suggesting their potential use to trace physical signatures in climate model calculations. It is recommended that these model-derived radiative kernels should be validated by the long-term global and regional surface observations in order to enhance confidence to implement these radiative kernels in climate models.

在计算出的全球晴空光谱短波辐射通量分布中追踪物理特征
本研究利用高光谱分辨率辐射传输模式(中分辨率大气传输模式,MODTRAN6.0.2.5)计算全球晴空短波辐射通量,并与美国国家航空航天局(NASA)的云和地球辐射能量系统(CERES)综合辐射通量和云(SYN1deg)产品进行比较。比较结果表明,M6.0 计算结果和 SYN1 结果得出的地表晴空下沉 SW 通量的全球分布相似,年平均值分别为 246.51 Wm-2 和 242.42 Wm-2。进一步分析表明,与 SYN1 结果相比,M6.0 计算结果在中低纬度地区,特别是北半球(NH),大多略偏高,但在高纬度地区则偏低。不过,这些差异大多在 CERES 估计的地表月平均晴空下沉 SW 通量的不确定性(6 Wm-2)范围内。在 M6.0 和 CERES SYN1 产品中,晴空 SW/μ0 通量对晴空水汽辐射核所代表的可降水水汽(PWV)变化的敏感性在海洋上空约为 -0.7 Wm-2/(kgm-2),南半球(SH)海洋上空的 SYN1 结果除外。此外,M6.0 计算得出的陆地覆盖率和西南/可见光/近红外反照率的地带平均值表明,可见光反照率在极地地区(60°)最高,其次是西南和近红外反照率,而近红外反照率在中低纬度地区(60°)最高。一般来说,从南纬 60 度到北纬 60 度,随着陆地覆盖范围的增加,西南/垂直/近红外反照率及其差异单调增加。从这两种产品中得出的一致的晴空水汽辐射核超出了我们的预期,表明它们有可能在气候模式计算中用于追踪物理特征。建议应通过长期的全球和区域地表观测来验证这些模式得出的辐射核,以增强在气候模式中实施这些辐射核的信心。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
5.30
自引率
21.70%
发文量
273
审稿时长
58 days
期刊介绍: Papers with the following subject areas are suitable for publication in the Journal of Quantitative Spectroscopy and Radiative Transfer: - Theoretical and experimental aspects of the spectra of atoms, molecules, ions, and plasmas. - Spectral lineshape studies including models and computational algorithms. - Atmospheric spectroscopy. - Theoretical and experimental aspects of light scattering. - Application of light scattering in particle characterization and remote sensing. - Application of light scattering in biological sciences and medicine. - Radiative transfer in absorbing, emitting, and scattering media. - Radiative transfer in stochastic media.
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