起伏地形中的散射辐射及其计算模式

本文根据对丘陵山区地形参数的数值模拟结果,应用野外试验观测资料,较详细地讨论了起伏山区散射辐射计算模式。主要讨论三个问题:天穹散射各向异性下的坡地散射辐射计算;实际地形遮蔽下的坡地散射辐射计算;由周围山地反射而到达坡面的散射辐射计算。最终分析了散射辐射在大别山南段赵公岭山区的分布特点。结果表明,山区散射辐射场与地形要素场配合较好,其中冬季以坡向影响为主,夏季则以地形遮蔽为最重要。     

我国散射辐射的气候计算及其分布

本文利用我国61个日射站的实测资料,讨论了太阳散射辐射的气候计算方法。在详细分析云对散射辐射影响的基础上,提出了半理论、半经验散射辐射气候计算式,并利用全国206个站的云量资料,计算并分析了散射辐射的全国分布。     

复杂地形下黑河流域的太阳辐射计算

基于数字高程模型(DEM)数据,在充分考虑了地形因子对太阳直接辐射和散射辐射的影响后,实际计算了起伏地形下黑河流域的太阳辐射。在忽略地表和大气之间的多次反射后,地表太阳总辐射计为三项:按起伏坡面上实际入射角考虑的太阳直接辐射、经过下垫面天空视角因子订正的坡面天空散射辐射和考虑周围地形反射效应的附加辐射。计算结果表明:局地地形起伏对太阳直接辐射、总辐射空间分布的影响非常强烈,使得复杂地形下不同坡向间总辐射和直接辐射平均计算差额十分显著,且太阳天顶角从较小增大至中等大小时,这两种平均计算差额均加大一倍多;在较小和中等大小太阳天顶角下,不同坡向间总辐射平均计算差额,均较相同条件下直接辐射平均计算差额为小,这是因为总辐射还包括了天空漫射和邻近地形反射辐射因子,这两个因子和坡面上太阳入射方位的变化共同影响地表入射太阳辐射;起伏地形主要使得太阳辐射在局地区域内背阴、向阳坡向间发生显著的重新分配。因此,在复杂地形地区进行太阳辐射计算时必须考虑地形的影响。     

坡面辐射场的模式计算及结果分析

本文旨在建立一个不依靠地面辐射观测资料的坡面辐射场的计算模式。在全国范围内均匀地选取74个气象台站,计算了我国1、7月份8个坡向和8个坡度的坡面辐射平衡及其分量,并进行了分析,揭示了一些规律。     

青藏高原夏季的散射辐射

本文讨论了青藏高原夏季的散射辐射状况,着重分析了太阳高度角、大气透明度、拔海高度和云状、云量对散射辐射的影响,计算并分析了Berlage系数α和散射辐射日总量的变化特点。     

青藏高原夏季的散射辐射

本文讨论了青藏高原夏季的散射辐射状况,着重分析了太阳高度角、大气透明度、拔海高度和云状、云量对散射辐射的影响,计算并分析了Berlage系数α和散射辐射日总量的变化特点。     

福建省散射辐射的计算方法及其分布特征

提出了综合考虑日照百分率和总云量来计算散射辐射的公式。将散射辐射Ｄ除以日照百分率Ｓ１，称其为净散射辐射。同时求出各月及年的净散射辐射与当地天文辐射的比值和总云量的相关系数ｒ。各月与年的相关系数均为正值，且ｒ均大于ｒ０．０１。在此基础上建立计算散射辐射的经验公式：Ｄ＝Ｓ１Ｑｏｅ＾ａ＋ｂＮ，式中Ｄ为散射辐射；Ｓ１为日照百分率；Ｑｏ为天文辐射；Ｎ为总云量；ａ和ｂ为经验系数。使用该经验公式求得福建省所有市     

广东省太阳辐射候总量计算及光能利用分析

太阳辐射能的研究,愈来愈受到人们的重视。本文讨论了太阳直接辐射和散射辐射候总量的计算方法,并分析了本省的光能利用率和光合生产潜力。 一、直接辐射和散射辐射候总量的计算 碧空条件下,直接辐射和散射辐射日总量的理论计算式可写成:     

由卫星资料估算晴空大气太阳直接辐射和散射辐射

根据光的多次散射理论 ,对水汽、气溶胶、臭氧、混合气体等实行辐射参数化处理 ;利用中国探空站资料和诺阿 ( NOAA)气象卫星垂直业务探测器 ( TOVS)资料反演的探空资料 ,由离散纵标法计算了大气各高度上的太阳直接辐射和散射辐射 ,并与此同时的和同站点位置的卫星可见光、红外测值进行统计回归拟合 ,建立卫星测值与大气中太阳直接辐射和散射辐射的计算模式 ,据此可以利用卫星资料估算太阳直接辐射和太阳散射辐射 ,这对于大气环境光学特性和大气环流、气候变化的研究有重要意义。     

散射辐射计算方法和气溶胶的气候效应

本文详细地介绍了大气散射辐射和辐射变温率的计算方法,并就气溶胶的概念、辐射特征以及气候效应进行了讨论。文中提出了求解辐射通量密度的迭代方法。本文是在各类数值模式中引入气溶胶气候效应的理论基础。     

太阳散射辐射的分光测量及其能量分配

近十余年来，国内外不少学者先后研究了散射辐射与总辐射的关系［１－６］，建立了各种计算散射辐射的经验公式，但有关分光散射辐射分量的测量和研究为数甚少。为此，我们于１９８９－１９９０年在北京对３００－２８００ｎｍ光谱范围内的７个波段的散射分量进行测量，并研究了各分量与全谱段散射总量间的定量关系。     

A Generalized Layered Radiative Transfer Model in the Vegetation Canopy

In this paper, a generalized layered model for radiation transfer in canopy with high vertical resolution is developed. Differing from the two-stream approximate radiation transfer model commonly used in the land surface models, the generalized model takes into account the effect of complicated canopy morphology and inhomogeneous optical properties of leaves on radiation transfer within the canopy. In the model, the total leaf area index （LAI） of the canopy is divided into many layers. At a given layer, the influences of diffuse radiation angle distributions and leaf angle distributions on radiation transfer within the canopy are considered. The derivation of equations serving the model are described in detail, and these can deal with various diffuse radiation transfers in quite broad categories of canopy with quite inhomogeneons vertical structures and uneven leaves with substantially different optical properties of adaxial and abaxial faces of the leaves. The model is used to simulate the radiation transfer for canopies with horizontal leaves to validate the generalized model. Results from the model are compared with those from the two-stream scheme, and differences between these two models are discussed.     

Estimating solar radiation on tilted surfaces with various orientations: a study case in Karaj (Iran)

Summary The aim of this study is the evaluation of models that estimate daily global solar radiation on tilted surfaces from that measured on horizontal surfaces. Global solar radiation incident on a tilted plane consists of three components: beam radiation, diffuse radiation and reflected radiation from the ground. The Klein (1977) method, modified by Andersen (1980), was used for estimating direct solar radiation incident on tilted surfaces and an isotropic model was used for estimating reflected solar radiation incident on a tilted plane. In contrast models for the diffuse radiation component show major differences, which justifies a validation study which has been done. Eight models for derivation of daily slope diffuse irradiance from daily horizontal diffuse irradiance were tested against recorded slope irradiances at Karaj (35°55′ N; 50°56′ E), Iran. The following models were included: Badescu (2002), Tian et al. (2001), Reindl et al. (1990), Skartveit and Olseth (1986), Koronakis (1986), Steven and Unsworth (1980), Hay (1979) and Liu and Jordan (1962). All the models use the same method for calculating beam radiation as well as ground reflected radiation. However, only diffuse component of radiation was compared. Statistical indices showed that Reindl’s model gives the most accurate prediction for the south-facing surface and Koronakis’s model performs best for the west-facing surface. The Relative Root Mean Square Errors (%RMSE), except for Steven and Unsworth’s model that has unacceptable results, for whole data range from 1.02 to 10.42%. In general, Reindl’s model produces the best agreement with the measured tilted data.     

Measurements of chemically and biologically effective radiation reaching the ground

Solar ultraviolet radiation at the surface has been measured at Potsdam on cloudless days by spectrometer OL 752/10. The measurements are compared with broad-band filter measurements and with model calculations using a modified version of Green's model, which is independent of the measurements. Input data to the model such as atmospheric ozone and aerosol optical thicknesses were measured by a Dobson and Brewer spectrophotometer as well as a Linke Feussner pyrheliometer, respectively. Differences between the model and the measurements are discussed in terms of uncertainties in the calibration and errors of instruments as well as uncertainties in the model calculations including the errors of input data. It is demonstrated that different chemically and biologically effective radiances can be determined from only one set of measured spectral irradiance components, i.e. global radiation and diffuse downward and upward directed radiation. Examples of diurnal variations of the photochemical production of ozone and hydroxyl radicals as determined from spectral irradiance measurements and measured concentrations of relevant trace gases are given.It is shown from the measured irradiance that relations between different effects of radiation to the biosphere depend on solar zenith angle, and to a certain extent also on atmospheric ozone. This has to be taken into account when adverse effects of changing UV radiation are evaluated. Radiation Amplification Factors derived from measurements correspond to those determined from model calculations.     

Energy Balance Of A Sparse Coniferous High-Latitude Forest Under Winter Conditions

Measurements carried out in Northern Finland on radiation and turbulent fluxes over a sparse, sub-arctic boreal forest with snow covered ground were analysed. The measurements represent late winter conditions characterised by low solar elevation angles. During the experiment (12–24 March 1997) day and night were about equally long. At low solar elevation angles the forest shades most of the snow surface. Therefore an important part of the radiation never reaches the snow surface but is absorbed by the forest. The sensible heat flux above the forest was fairly large, reaching more than 100 W m^-2. The measurements of sensible heat flux within and above the forest revealed that the sensible heat flux from the snow surface is negligible and the sensible heat flux above the forest stems from warming of the trees. A simple model for the surface energy balance of a sparse forest is presented. The model treats the diffuse and direct shortwave (solar) radiation separately. It introduces a factor that accounts for the shading of the ground at low solar elevation angles, and a parameter that deals with the partial transparency of the forest.Input to the model are the direct and diffuse incoming shortwave radiation.Measurements of the global radiation (direct plus diffuse incoming shortwaveradiation) above the forest revealed a considerable attenuation of the globalradiation at low solar elevation. A relation for the atmospheric turbidity asfunction of the solar elevation angle is suggested. The global radiation wassimulated for a three month period. For conditions with a cloud cover of lessthan 7 oktas good agreement between model predictions and measurementswere found. For cloud cover 7 and 8 oktas a considerable spread can beobserved. To apply the proposed energy balance model, the global radiationmust be separated into its diffuse and direct components. We propose a simpleempirical relationship between diffuse shortwave and global radiation asfunction of cloud cover.     

A Comparison of Two Canopy Radiative Models in Land Surface Processes

This paper compares the predictions by two radiative transfer models-the two-stream approximation model and the generalized layered model （developed by the authors） in land surface processes -for different canopies under direct or diffuse radiation conditions. The comparison indicates that there are significant differences between the two models, especially in the near infrared （NIR） band. Results of canopy reflectance from the two-stream model are larger than those from the generalized model. However, results of canopy absorptance from the two-stream model are larger in some cases and smaller in others compared to those from the generalized model, depending on the cases involved. In the visible （VIS） band, canopy reflectance is smaller and canopy absorptance larger from the two-stream model compared to the generalized model when the Leaf Area Index （LAI） is low and soil reflectance is high. In cases of canopies with vertical leaf angles, the differences of reflectance and absorptance in the VIS and NIR bands between the two models are especially large. Two commonly occurring cases, with which the two-stream model cannot deal accurately, are also investigated. One is for a canopy with different adaxial and abaxial leaf optical properties; and the other is for incident sky diffuse radiation with a non-uniform distribution. Comparison of the generalized model within the same canopy for both uniform and non-uniform incident diffuse radiation inputs shows smaller differences in general. However, there is a measurable difference between these radiation inputs for a canopy with high leaf angle. This indicates that the application of the two-stream model to a canopy with different adaxial and abaxial leaf optical properties will introduce non-negligible errors.     

A Comparison of Two Canopy Radiative Models in Land Surface Processes

This paper compares the predictions by two radiative transfer models-the two-stream approximation model and the generalized layered model (developed by the authors) in land surface processes-for different canopies under direct or diffuse radiation conditions. The comparison indicates that there are significant differences between the two models, especially in the near infrared (NIR) band. Results of canopy reflectance from the two-stream model are larger than those from the generalized model. However, results of canopy absorptance from the two-stream model are larger in some cases and smaller in others compared to those from the generalized model, depending on the cases involved. In the visible (VIS) band, canopy reflectance is smaller and canopy absorptance larger from the two-stream model compared to the generalized model when the Leaf Area Index (LAI) is low and soil reflectance is high. In cases of canopies with vertical leaf angles, the differences of reflectance and absorptance in the VIS and NIR bands between the two models are especially large.Two commonly occurring cases, with which the two-stream model cannot deal accurately, are also investigated. One is for a canopy with different adaxial and abaxial leaf optical properties; and the other is for incident sky diffuse radiation with a non-uniform distribution. Comparison of the generalized model within the same canopy for both uniform and non-uniform incident diffuse radiation inputs shows smaller differences in general. However, there is a measurable difference between these radiation inputs for a canopy with high leaf angle. This indicates that the application of the two-stream model to a canopy with different adaxial and abaxial leaf optical properties will introduce non-negligible errors.     

起伏地形下浙江省散射辐射时空分异规律模拟

结合影响起伏地形下太阳散射辐射的天空因素与地面因素,通过基于数字高程模型（DEM）数据的起伏地形下天文辐射模型和地形开阔度模型,综合考虑地面因素对散射辐射的影响;基于常规地面气象站观测资料建立的水平面散射辐射模型,考虑天空因素对散射辐射的影响;建立了起伏地形下浙江省散射辐射分布式估算模型;逐月计算了浙江省散射辐射（100m×100m）的空间分布。结果表明：散射分量分布与地理地形因子、季风影响、大气透明程度有关,由高纬向低纬逐渐增加;季节分布特点为,夏季〉春季〉秋季〉冬季;坡度、坡向对散射辐射的分布影响小,但辐射值与开阔度呈正相关,各季辐射最大值分布在开阔度大处,最小值在开阔度最小处,不同季节有所伸缩。计算结果可以为气候变化和环境资源研究提供基础数据。     

Aerosols and their influence on radiation partitioning and savanna productivity in northern Australia

Aerosols have been shown to affect the quantity and quality of solar radiation on the Earth’s surface. Savanna regions are subject to frequent burning and release of aerosols that may impact on radiation components and possibly vegetation productivity in this region. Therefore, in this study, we have analyzed the optical properties of aerosols (aerosol optical depth (AOD) and Angstrom coefficient) from the Atmospheric Radiation Measurement site in Darwin for the periods from April 2002 to June 2005 as measured by a multifilter rotating shadowband radiometer. The influence of aerosols and their effect on surface shortwave incoming solar radiation and savanna productivity were examined for the dry season using sky radiation collection of radiometers and eddy covariance measurements from the Howard Springs flux site. Results indicated that aerosol concentrations in the region were relatively low compared to other savanna regions with the maximum monthly average AOD over the period being the greatest in October (0.29?±?0.003 standard error at 500 nm). The highest monthly average Angstrom exponent was also found in October (1.38?±?0.008). The relatively low aerosol concentration in this region can be attributed to the mixture of smoke aerosols with humidity haze and local circulations. Over a range of AODs from 0.1 to 0.4, we found a modest increase in the fraction of diffuse radiation to total radiation from 11% to 21%. This small increase in diffuse fraction did not affect the carbon flux significantly. However, because the current range of AOD in the region is relatively low, the region could be sensitive to increases in aerosols and diffuse fraction in the future.     

东亚地区大气辐射能收支(三)--云天大气的地气系统热量收支

本文是东亚地区大气辐射能收支”的第三部分,讨论了如下几个问题: 1.云天大气长波辐射和辐射差额分布。结果指出,除7月份西藏高原地区外,云天和晴天长波辐射分布特征基本相同,而其辐射差额分布又和相应月份的大气长波辐射分布特征基本一致。 2.东亚地区对流层大气热源热汇分布:8月份整个东亚地区都是冷源,在新疆地区和中国东部北纬32°—25°之间有两个冷中心。在7月份整个东亚地区都是热源,在西藏高原东南部有一个最强的热源中心。新疆北部有一个小的热源中心。 3.东亚各地区的地气系统各种热量收支。首先就整个东亚地区地气系统而言,7月份得到热量基本上补偿了1月份损失的热量,但就大气而言,1月份热量损失大于7月份热量的获得。其次各地区各种热量收支特征并不一致。