Mean monthly incoming atmospheric longwave radiation modelled using the 1" DEM-S - 3" mosaic

Mean monthly solar radiation was modelled across Australia using topography from the 1 arcsecond resolution SRTM-derived DEM-S and climatic and land surface data. The SRAD model (Wilson and Gallant, 2000) was used to derive:\n•\tIncoming short-wave radiation on a sloping surface\n•\tShort-wave radiation ratio (shortwave on sloping surface / shortwave on horizontal surface)\n•\tIncoming long-wave radiation\n•\tOutgoing long-wave radiation\n•\tNet long-wave radiation\n•\tNet radiation\n•\tSky view factor\nAll radiation values are in MJ/m2/day except for short-wave radiation ratio which has no units. The sky view factor is the fraction of the sky visible from a grid cell relative to a horizontal plane.\n\nThe radiation values are determined for the middle day of each month (14th or 15th) using long-term average atmospheric conditions (such as cloudiness and atmospheric transmittance) and surface conditions (albedo and vegetation cover). They include the effect of terrain slope, aspect and shadowing (for sun positions at 5 minute intervals from sunrise to sunset), direct and diffuse radiation and sky view.\n\nThe monthly data in this collection are available at 3 arcsecond resolution as single (mosaicked) grids for Australia in TIFF format. \n\nThe 3 arcsecond resolution versions of these radiation surfaces have been produced from the 1 arcsecond resolution surfaces, by aggregating the cells in a 3x3 window and taking the mean value.\n\nThe 1 arcsecond tiled data can be found here: https://data.csiro.au/dap/landingpage?pid=csiro:9632 . The 1 arcsecond mosaic data can be found here: https://data.csiro.au/dap/landingpage?pid=csiro:18491\nLineage: Source data\n1. 1 arcsecond SRTM-derived Smoothed Digital Elevation Model (DEM-S; ANZCW0703014016)\n2. Aspect derived from the 1 arcsecond SRTM DEM-S\n3. Slope derived from the 1 arcsecond SRTM DEM-S\n4. Monthly cloud cover fraction (Jovanovic et al., 2011)\n5. Monthly albedo derived from AVHRR (Donohue et al., 2010)\n6. Monthly minimum and maximum air temperature (Bureau of Meteorology)\n7. Monthly vapour pressure (Bureau of Meteorology)\n8. Monthly fractional cover (Donohue et al., 2010)\n9. Monthly black-sky and white-sky albedo from MODIS (MCD43A3, B3) (Paget and King, 2008; NASA LP DAAC, 2013)\n10. Measurements of daily sunshine hours, 9 am and 3pm cloud cover, and daily solar radiation from meteorological stations around Australia (Bureau of Meteorology)\n\nSolar radiation model\nSolar radiation was calculated using the SRAD model (Wilson and Gallant, 2000), which accounts for:\n\tAnnual variations in sun-earth distance\n\tSolar geometry based on latitude and time of year\n\tThe orientation of the land surface relative to the sun\n\tShadowing by surrounding topography\n\tClear-sky and cloud transmittance\n\tSunshine fraction (cloud-free fraction of the day) in morning and afternoon\n\tSurface albedo\n\tThe effects of surface temperature on outgoing long-wave radiation, which is modulated by incoming radiation and moderated by vegetation cover\n\tAtmospheric emissivity based on vapour pressure\n\nAll input parameters were long-term averages for each month, i.e., monthly climatologies of cloud cover, air temperature, vapour pressure, fractional cover, AVHRR albedo and MODIS albedo.\n\nCircumsolar coefficient was fixed both spatially and temporally at 0.25, while clear sky atmospheric transmissivity and cloud transmittance were varied. Transmittance measures the fraction of radiation passing through a material (air or clouds in this case), while transmissivity measures that fraction for a specified amount of material. SRAD uses a transmittance parameter for cloud, representing an average of all cloud types during cloudy periods, and a transmissivity parameter for clear sky so that the transmittance can vary with the position of the sun in the sky and hence the thickness of atmosphere that radiation passes through on its way to the ground. The clear sky transmissivity τ and cloud transmittance β were calibrated using observed daily radiation and sunshine hours. \n\nReferences\nDonohue R. J., McVicar T. R. and Roderick M. L. (2010a). Assessing the ability of potential evaporation formulations to capture the dynamics in evaporative demand within a changing climate. Journal of Hydrology, 386, 186-197, doi:10.1016/j.jhydrol.2010.03.020.\n\nDonohue, R. J., T. R. McVicar, L. Lingtao, and M. L. Roderick (2010b). A data resource for analysing dynamics in Australian ecohydrological conditions, Austral Ecol, 35, 593–594, doi: 10.1111/j.1442-9993.2010.02144.x.\n\nErbs, D. G., S. A. Klein, and J. A. Duffie (1982), Estimation of the diffuse radiation fraction for hourly, daily and monthly-average global radiation, Solar Energy, 28(4), 293-302.\n\nJovanovic, B., Collins, D., Braganza, K., Jakob, D. and Jones, D.A. (2011). A high-quality monthly total cloud amount dataset for Australia. Climatic Change, 108, 485-517.\n\nNASA Land Processes Distributed Active Archive Center (LP DAAC) (2013). MCD43A3, B3. USGS/Earth Resources Observation and Science (EROS) Center, Sioux Falls, South Dakota\n\nPaget, M.J. and King, E.A. (2008). MODIS Land data sets for the Australian region. CSIRO Marine and Atmospheric Research Internal Report No. 004. https://remote-sensing.nci.org.au/u39/public/html/modis/lpdaac-mosaics-cmar\n\nWilson, J.P. and Gallant, J.C. (2000) Secondary topographic attributes, chapter 4 in Wilson, J.P. and Gallant, J.C. Terrain Analysis: Principles and Applications, John Wiley and Sons, New York.

本数据集基于1角秒分辨率航天飞机雷达地形测绘任务（SRTM）衍生的DEM-S地形数据，以及气候与地表数据，对澳大利亚全域的月均太阳辐射开展建模。本研究采用SRAD模型（Wilson与Gallant，2000）推导得到以下参数： • 倾斜地表入射短波辐射 • 短波辐射比值（倾斜地表短波辐射/水平地表短波辐射） • 入射长波辐射 • 出射长波辐射 • 净长波辐射 • 净辐射 • 天空视域因子（Sky View Factor） 所有辐射量的单位均为MJ/m²/日，仅短波辐射比值无单位。天空视域因子指某栅格单元相对于水平面所能看到的天空占比。 本数据集的辐射量以每月中旬（14日或15日）为代表日，基于长期平均大气条件（如云量、大气透射率）与地表条件（反照率、植被覆盖度）计算得到，其涵盖了地形坡度、坡向与遮蔽效应（以日出至日落期间每5分钟间隔的太阳位置为基准）、直接辐射与散射辐射，以及天空视域的影响。 本数据集提供3角秒分辨率的澳大利亚全域月均辐射数据，格式为镶嵌式单栅格TIFF文件。 该3角秒分辨率的辐射栅格数据集由1角秒分辨率数据通过3×3窗口聚合取均值生成。 1角秒分幅数据可通过以下链接获取：https://data.csiro.au/dap/landingpage?pid=csiro:9632；1角秒镶嵌数据可通过以下链接获取：https://data.csiro.au/dap/landingpage?pid=csiro:18491 数据来源谱系： 1. 1角秒分辨率SRTM衍生平滑数字高程模型（DEM-S；ANZCW0703014016） 2. 由1角秒分辨率SRTM DEM-S提取得到的坡向 3. 由1角秒分辨率SRTM DEM-S提取得到的坡度 4. 月均云量占比（Jovanovic等，2011） 5. 基于AVHRR提取的月均反照率（Donohue等，2010） 6. 月均最高、最低气温（澳大利亚气象局） 7. 月均水汽压（澳大利亚气象局） 8. 月均植被覆盖度（Donohue等，2010） 9. 基于MODIS MCD43A3产品B3波段提取的月均黑空反照率与白空反照率（Paget与King，2008；NASA陆地过程分布式数据归档中心（LP DAAC），2013） 10. 澳大利亚境内气象站观测的日均日照时数、上午9时与下午3时云量及日均太阳辐射数据（澳大利亚气象局） 太阳辐射模型 太阳辐射计算采用SRAD模型（Wilson与Gallant，2000），该模型考虑了以下因素： • 日地距离的年际变化 • 基于纬度与季节的太阳几何关系 • 地表相对于太阳的朝向 • 周边地形造成的遮蔽效应 • 晴空与云层的辐射透射率 • 上午与下午的日照占比（当日无云时段占比） • 地表反照率 • 地表温度对出射长波辐射的影响，该效应受入射辐射调控并通过植被覆盖度调节 • 基于水汽压的大气发射率 所有输入参数均为各月的长期平均数据，即云量、气温、水汽压、植被覆盖度、AVHRR反照率与MODIS反照率的月均气候态数据。 环太阳系数在空间与时间维度均固定为0.25，而晴空大气透射率与云层透射率则为可变参数。其中，透射率（Transmittance）指辐射穿过某一介质（此处为大气或云层）的比例；透射性（Transmissivity）指特定厚度介质的辐射穿透比例。SRAD模型采用云层透射率参数表征多云时段内所有云型的平均穿透特性，并采用晴空透射率参数以适配太阳在天空中的位置变化，进而匹配辐射抵达地表所穿过的大气厚度。本研究通过实测日均太阳辐射与日照时数对晴空透射率τ及云层透射率β进行了校准。 参考文献 1. 多诺休 R.J.、麦克维卡 T.R. 与罗德里克 M.L.（2010a）：《评估潜在蒸发公式在气候变化背景下捕捉蒸发需求动态的能力》，《水文学报》，第386卷，186-197页，DOI:10.1016/j.jhydrol.2010.03.020. 2. 多诺休 R.J.、麦克维卡 T.R.、林涛 L. 与罗德里克 M.L.（2010b）：《用于分析澳大利亚生态水文条件动态的数据资源》，《澳大利亚生态学》，第35卷，593–594页，DOI:10.1111/j.1442-9993.2010.02144.x. 3. 厄布斯 D.G.、克莱因 S.A. 与达菲 J.A.（1982）：《逐时、逐日与逐月总辐射散射辐射占比的估算方法》，《太阳能》，第28卷第4期，293-302页。 4. 约万诺维奇 B.、柯林斯 D.、布拉甘扎 K.、雅各布 D. 与琼斯 D.A.（2011）：《澳大利亚高质量月均总云量数据集》，《气候变化》，第108卷，485-517页。 5. NASA陆地过程分布式数据归档中心（LP DAAC）（2013）：MCD43A3产品B3波段，美国地质调查局/地球资源观测与科学中心（EROS），南达科他州苏福尔斯。 6. 佩奇 M.J. 与金 E.A.（2008）：《澳大利亚区域MODIS陆地数据集》，澳大利亚联邦科学与工业研究组织海洋与大气研究内部报告第004号，https://remote-sensing.nci.org.au/u39/public/html/modis/lpdaac-mosaics-cmar 7. 威尔逊 J.P. 与加兰特 J.C.（2000）：《次级地形属性》，载于威尔逊 J.P. 与加兰特 J.C. 主编的《地形分析：原理与应用》第4章，约翰威立国际出版公司，纽约。