Solar irradiance in the heterogeneous albedo environment of the Arctic coast: measurements and a 3-D model study

Abstract. We present a unique case study of the solar global irradiance in a highly heterogeneous albedo environment at the Arctic coast. Diodearray spectroradiometers were deployed at three sites around Ny Alesund, Svalbard, and spectral irradiances were simultaneously measured under clear-sky conditions during a 24 h period. The 3-D radiative transfer model MYSTIC is applied to simulate the measurements in various model scenarios. First, we model the effective albedos of ocean and snow and consequently around each measurement site. The effective albedos at 340 nm increase from 0.57 to 0.75, from the coastal site in the west towards the site 20 km east, away from the coast. The observed ratios of the global irradiance indicate a 15% higher average irradiance, at 340 nm east relative to west, due to the higher albedo. The comparison of our model scenarios suggest a snow albedo of > 0.9 and confirm the observation that drift ice has moved into the Fjord during the day. The local time shift between the locations causes a hysteresis-like behavior of these east–west ratios with solar zenith angle (SZA). The observed hysteresis, however, is larger and, at 340 nm, can be explained by the drift ice. At 500 nm, a plausible explanation is a detector tilt of about 1°. The ratios between afternoon and morning irradiances at the same SZA are investigated, which confirm the above conclusions. At the coastal site, the measured irradiance is significantly higher in the afternoon than in the morning. Besides the effect of changing drift ice and detector tilt, the small variations of the aerosol optical depth have to be considered also at the other stations to reduce the discrepancies between model and observations. Remaining discrepancies are possibly due to distant high clouds.

[1]  Charles S. Zender,et al.  Arctic and Antarctic diurnal and seasonal variations of snow albedo from multiyear Baseline Surface Radiation Network measurements , 2011 .

[2]  Bernhard Mayer,et al.  Efficient unbiased variance reduction techniques for Monte Carlo simulations of radiative transfer in cloudy atmospheres: The solution , 2011 .

[3]  B. Mayer,et al.  Validating the MYSTIC three-dimensional radiative transfer model with observations from the complex topography of Arizona's Meteor Crater , 2010 .

[4]  J. Gröbner,et al.  Quality assurance of solar UV irradiance in the Arctic. , 2010, Photochemical & photobiological sciences : Official journal of the European Photochemistry Association and the European Society for Photobiology.

[5]  C. Zender,et al.  Arctic and Antarctic Diurnal and Seasonal Variations of Snow Albedo from Multi-year BSRN Measurements , 2010 .

[6]  Mario Blumthaler,et al.  Stray light correction for solar measurements using array spectrometers. , 2009, The Review of scientific instruments.

[7]  Mario Blumthaler,et al.  All-sky imaging: a simple, versatile system for atmospheric research. , 2009, Applied optics.

[8]  B. Mayer Radiative transfer in the cloudy atmosphere , 2009 .

[9]  L. Ylianttila,et al.  Diurnal variations in the UV albedo of arctic snow , 2008 .

[10]  A. Bais,et al.  Charge-coupled device spectrograph for direct solar irradiance and sky radiance measurements. , 2008, Applied optics.

[11]  Robert S. Stone,et al.  Ultraviolet and visible radiation at Barrow, Alaska: Climatology and influencing factors on the basis of version 2 National Science Foundation network data , 2007 .

[12]  Joachim Reuder,et al.  Investigations on the effect of high surface albedo on erythemally effective UV irradiance: results of a campaign at the Salar de Uyuni, Bolivia. , 2007, Journal of photochemistry and photobiology. B, Biology.

[13]  M. Blumthaler Factors, trends and scenarios of UV radiation in arctic-alpine environments , 2007 .

[14]  Gert König-Langlo,et al.  Measurements of spectral snow albedo at Neumayer, Antarctica , 2006 .

[15]  Bernhard Mayer,et al.  Atmospheric Chemistry and Physics Technical Note: the Libradtran Software Package for Radiative Transfer Calculations – Description and Examples of Use , 2022 .

[16]  G. König‐Langlo,et al.  Bipolar Intercomparison of Long-Term Solar Radiation Measurements from two BSRN Stations , 2005 .

[17]  Martin Huber,et al.  Effect of inhomogeneous surface albedo on diffuse UV sky radiance at a high‐altitude site , 2004 .

[18]  I. Reda,et al.  Solar position algorithm for solar radiation applications , 2004 .

[19]  C. Gautier,et al.  A test of three‐dimensional radiative transfer simulation using the radiance signatures and contrasts at a high latitude coastal site , 2002 .

[20]  Ultraviolet radiation in partly snow covered terrain: Observations and three‐dimensional simulations , 2001 .

[21]  M. Blumthaler,et al.  Modeling the effect of an inhomogeneous surface albedo on incident UV radiation in mountainous terrain: Determination of an effective surface albedo , 2001 .

[22]  Teodoro López-Moratalla,et al.  Computing the solar vector , 2001 .

[23]  B. Mayer,et al.  Comment on “Measurements of erythemal irradiance near Davis Station, Antarctica: Effect of inhomogeneous surface albedo” , 2000 .

[24]  Markus Degünther,et al.  Influence of inhomogeneous surface albedo on UV irradiance: Effect of a stratus cloud , 2000 .

[25]  K. Michael,et al.  Measurements of erythemal irradiance near Davis Station, Antarctica: Effect of inhomogeneous surface albedo , 1999 .

[26]  S. Madronich,et al.  Effects of snow cover on UV irradiance and surface albedo: A case study , 1998 .

[27]  Stephen G. Warren,et al.  Effect of surface roughness on bidirectional reflectance of Antarctic snow , 1998 .

[28]  M. Degünther,et al.  Case study on the influence of inhomogeneous surface albedo on UV irradiance , 1998 .

[29]  J. Lenoble,et al.  Modeling of the influence of snow reflectance on ultraviolet irradiance for cloudless sky. , 1998, Applied optics.

[30]  C. Gautier,et al.  Investigation of the effect of surface heterogeneity and topography on the radiation environment of Palmer Station, Antarctica, with a hybrid 3-D radiative transfer model , 1998 .

[31]  Biologically active insolation over Antarctic waters: Effect of a highly reflecting coastline , 1998 .

[32]  Piers M. Forster,et al.  Modeling Ultraviolet Radiation at the Earth's Surface. Part I: The Sensitivity of Ultraviolet Irradiances to Atmospheric Changes , 1995 .

[33]  Martin Huber,et al.  Comparing ground‐level spectrally resolved solar UV measurements using various instruments: A technique resolving effects of wavelength shift and slit width , 1995 .

[34]  J. Overland,et al.  Preface [to special section on Leads and Polynyas] , 1995 .

[35]  H. Rahman,et al.  Coupled surface-atmosphere reflectance (CSAR) model: 2. Semiempirical surface model usable with NOAA advanced very high resolution radiometer data , 1993 .

[36]  E. Shettle Models of aerosols, clouds, and precipitation for atmospheric propagation studies , 1990 .

[37]  M. Blumthaler,et al.  SOLAR UVB‐ALBEDO OF VARIOUS SURFACES , 1988, Photochemistry and photobiology.

[38]  F. X. Kneizys,et al.  AFGL atmospheric constituent profiles (0-120km) , 1986 .

[39]  B. Osborne,et al.  Light and Photosynthesis in Aquatic Ecosystems. , 1985 .

[40]  J. Carroll,et al.  Effects of solar elevation and cloudiness on snow albedo at the South Pole , 1981 .

[41]  S. Warren,et al.  A Model for the Spectral Albedo of Snow. I: Pure Snow , 1980 .

[42]  P A H Seymour Practical Astronomy with Your Calculator , 1980 .

[43]  Boris A. Kargin,et al.  The Monte Carlo Methods in Atmospheric Optics , 1980 .

[44]  G. M. Hale,et al.  Optical Constants of Water in the 200-nm to 200-microm Wavelength Region. , 1973, Applied optics.

[45]  W. Munk,et al.  Measurement of the Roughness of the Sea Surface from Photographs of the Sun’s Glitter , 1954 .

[46]  N. Metropolis,et al.  The Monte Carlo method. , 1949, Journal of the American Statistical Association.