Hostname: page-component-7c8c6479df-ws8qp Total loading time: 0 Render date: 2024-03-28T11:44:43.561Z Has data issue: false hasContentIssue false

Remote sensing of snow grain-size and impurities from Airborne Multispectral Scanner data using a snow bidirectional reflectance distribution function model

Published online by Cambridge University Press:  14 September 2017

Tomonori Tanikawa
Affiliation:
Graduate School of Life and Environmental Sciences, University of Tsukuba, Ibaraki 305-8571, Japan
Teruo Aoki
Affiliation:
Meteorological Research Institute, Ibaraki 305-0052, Japan
Fumihiko Nishio
Affiliation:
Center for Environmental Remote Sensing, Chiba University, Chiba 263-8522, Japan
Rights & Permissions [Opens in a new window]

Abstract

Algorithms to retrieve the snow grain-size and the concentration of snow impurities were developed using a theoretical bidirectional reflectance distribution function (BRDF) model of the snow surface. In this model, snow grains are assumed to be independent spherical ice particles, and the BRDF is calculated with multiple scattering by snow particles. Using these algorithms, the snow grain-size and snow impurities were retrieved from Airborne Multispectral Scanner (AMSS) images at the visible (λ = 0.545 μm) and near-infrared (λ =1.24,1.64 and 2.23 μm) wavelengths observed over the flat snowfield in eastern Hokkaido, Japan, in February 1998. The estimated snow grain-size and impurities were consistent with the results of in situ measurements on the snow surface. For snow grain-size, measured reflectances in the different near-infrared AMSS channels indicated grain-size differences in the vertical profile of the snowpack.

Type
Research Article
Copyright
Copyright © The Author(s) [year] 2002 

Introduction

The large seasonal variation of snow-covered areas and very high snow albedos play a significant role in the Earth’s radiation balance, making the cryosphere act as a cold source on the global scale. The snow albedo in the visible region depends strongly on the concentration of impurities (Reference Warren and W.J.Warren and Wiscombe, 1980). These effects could cause an increase in themelting rate of snow in cold regions. The snow albedo in the visible region is reduced by 0.005–0.028 for fine-grained snow and by 0.015–0.08 for coarse-grained snow, with the observed concentration of soot, which is the most sensitive absorptive constituent of the Arctic snowpack, originating from Arctic haze (Reference Warren and ClarkeWarren and Clarke, 1986). On the other hand, the albedo in the near-infrared region depends on the near-surface snow grain-size (Reference Wiscombe and WarrenWiscombe and Warren, 1980). Spatial and temporal changes in near-surface snow grain-size can help characterize the thermal history of the snowpack because the rate of grain growth is exponentially proportional to snow temperature (Reference JordanJordan, 1991). Therefore, estimation of these parameters is important in monitoring the climate change in the cryosphere.

Remote sensing, using visible and near-infrared wavelengths, is one of the most suitable techniques for monitoring snow parameters at regional and global scales. For example, Reference Sydor, Sorensen and ShuterSydor and others (1979) retrieved the dustfall from Landsat Multispectral Scanner (MSS) data, but the sensor accuracy was not sufficient for detailed work. Reference Bourdelles and FilyBourdelles and Fily (1993) and Reference Fily, Bourdelles, Dedieu and SergentFily and others (1997) retrieved snow grain-size from Landsat Thematic Mapper (TM) data, and Reference Nolin and DozierNolin and Dozier (1993, Reference Nolin and Dozier2000) retrieved it from Airborne Visible/Infrared Imaging Spectrometer (AVIRIS) data. In these studies, the snow reflectance in the near-infrared regions that was calculated with the radiative transfer model was a function of equivalent grain-size for solar incident angle. The effects of snow impurities have not been considered in these models because snowpacks at observation sites were very clean. However, the snow reflectance in the near-infrared region is affected by the presence of absorbing impurities as well as snow grain-size (Reference Warren and W.J.Warren and Wiscombe, 1980). For example, in snowfields such as Barrow in Alaska, U.S.A., and Hokkaido in Japan, high concentrations of snow impurities were observed (Reference AokiAoki and others, 1998, Reference Aoki, Aoki, Fukabori, Hachikubo, Tachibana and Nishio2000), and snow-grain retrieval must take account of the effect of snow impurities.

Field experiments have shown the high anisotropic reflectance of snow (Reference Grenfell, Warren and MullenGrenfell and others, 1994; Reference Aoki, Aoki, Fukabori, Hachikubo, Tachibana and NishioAoki and others, 2000). The satellite sensor collects only a small portion of the energy reflected in all directions from a surface such as a snowfield. The assumption of isotropic reflectance of snow is too simple to retrieve the snow physical parameters, the results of which may contain large errors because the effects of bidirectional reflectance are generally not considered nor well corrected. Recently a digital elevation model has been used in the retrieval of snow grain-size (Reference Nolin and DozierNolin and Dozier, 1993). Reference Nolin and LiangNolin and Liang (2000) demonstrated the use of bidirectional reflectance modeling and surface particulate media modeling approaches for snow and soils. Therefore, we need to consider anisotropic snow-reflectance properties to retrieve the snow physical parameters from remote-sensing data.

The objective of this study is to develop an algorithm, the bidirectional reflectance distribution function (BRDF), which takes into account the anisotropic reflectance of snow surface in determining the snow grain-size and the concentration of impurities. Using Airborne Multispectral Scanner (AMSS) data at the visible and near-infrared wavelengths, these snow parameters are retrieved and we verified the algorithm from the AMSS data and in situ snow-pitmeasurements.

AMSS And Field Data

AMSS is an optical sensor installed on an aircraft which observes the radiance reflected from snow surface. This instrument acquires high-spatial-resolution images at 46 spectral channels in the wavelength region ranging from 0.40 to 12.45 μm with a swath angle of ±35°. AMSS is developed as a preparatory simulator of the spaceborne optical sensors and to validate the remote-sensing algorithms with optical sensors such as the Advanced Earth Observing Satellite-II/Global Imager (ADEOS-II/GLI). In this study, the wavelengths (bandwidth) of AMSS selected to retrieve the snow physical parameters were 0.545 μm (0.541–0.550μm) in the visible regions and 1.24 μm (1.23–1.25 μm),1.64mm (1.52–1.74 μm) and 2.23 μm (2.13–2.33 μm) in the near-infrared regions. Figure 1 shows the coordinate system for the AMSS observation.

Fig. 1. Coordinate systems for the observations by the AMSS sensor. The symbols θ0 and θv are the solar zenith angle and the viewing angle from the sensor, respectively; Δϕ is the relative azimuth angle of the viewing direction from the solar direction. AMSS flew from south to north and observed the upward reflected radiance I(θ0; θv;Δϕ; λ) from the snow surface.

The AMSS observations were made on the flat snowfield of eastern Hokkaido (Fig. 2), at 1100 h local time (LT) on 25 February 1998, when the solar zenith angle was 53.5° at approximately local solar noon. The flight course was from south to north, and the spatial resolution was about 1.2 62.0 m at nadir with an aircraft height of 930m and a ground speed of 280 kmh–1.

Fig. 2. Map showing the locations of the AMSS flight course in eastern Hokkaido. The AMSS observation was made at 1100 h LT, 25 February 1998. Solar zenith angle θ0 was 53.5°.

Figure 3 shows the results of snow-pit work coincident with the AMSS observation. The sky condition was clear and the air temperature was –9.9°C at 0920 h LT. Before the AMSS observation, a 10 cm new snowfall was observed on 20 February, and on 21 February a new snowfall of <1cm was measured. The snow depth was 27 cm, the snow types at the snow surface consisted of faceted crystals and granular snow, and those of lower parts were depth hoar and crust. The snowpack temperature was below freezing and there was no free water in the snowpack. The measured snow grain-sizes in deep layers were larger than those at the surface. Reference Aoki, Aoki, Fukabori, Hachikubo, Tachibana and NishioAoki and others (2000), using the results of the same snow-pit work, concluded that the optically equivalent snow grain-size was not the geometric radius (r1) but the branch width of the dendrites (r2) from the comparison between the measured spectral albedo and the theoretically calculated one. The concentration of snow impurities in the 0–5cm layer was 5.2 ppmw, which was higher than that in the 5–10 cm layer, with 0.84 ppmw. From the electron micrograph of the impurities, the spherical particles and coagulated particles were recognized. Reference Aoki, Aoki, Fukabori, Hachikubo, Tachibana and NishioAoki and others (2000) mentioned that these particles may be dust (soil particle) and soot, respectively.

Fig. 3. Vertical profiles of snow parameters observed from snow-pit work on 25 February 1998. Snow grain-sizes (radius) were measured with about 10 μm resolution using a hand-held lens. There were two kinds of dimensions of grain-sizes: one was one-half the length of the major axis of crystals or dendrites (r1), and the other was one-half the branch width of dendrites or one-half the dimension of the narrower portion of broken crystals (r2). Snow impurities were collected on the Nuclepore filters, and the concentration was estimated with a balance.

Definition Of BRDF

BRDF at wavelength λ is defined by the upward reflected radiance I(θvv,λ) from the snow surface contributed only by direct solar beam and the incident flux F000,λ)(on the surface normal to the beam) given by Reference WarrenWarren (1982):

(1)

where (°0; ϕ0) are incoming solar zenith and azimuth angles; μ0 = cos θ0; and (θv; ϕv) are outgoing (reflected) zenith and azimuth angles. Since the observed snow surface was completely flat and free of azimuthally oriented features, the snow reflectance was assumed to depend on the relative azimuth angle between the viewing direction and the solar direction. Consequently, two variables (ϕ0; ϕv) of BRDF can be replaced by azimuth difference Δϕ = ϕ0 - ϕv. As AMSS observes the reflected radiance contributed from direct solar beam and downward diffuse radiation, it is impossible to

observe the BRDF defined by Equation (1) under the field observation with AMSS. Therefore, we assumed BRDF as defined by the upward reflected radiance I(θ0v,Δϕ,λ) from the snow surface to direct and diffuse illuminations and the downward solar flux F (θ0; λ):

(2)

To compare with the snow isotropic reflectance that is described later, we used bidirectional reflection factor (BRF) given by:

(3)

The merit of BRF is that it is a dimensionless value normalized by the multiplication by π.

Snow BRF Model And Retrieval Algorithm

Theoretical snow BRFs at visible and near-infrared wavelengths were calculated using a multiple scattering radiative transfer model for the atmosphere–snow system. Radiative transfer calculation assumes that snow grains consist of spherical particles and are based on the Mie theory for single scattering and the doubling and addingmethod for multiple scattering, omitting polarization (Reference Aoki, Aoki, Fukabori and UchiyamaAoki and others, 1999, Reference Aoki, Aoki, Fukabori, Hachikubo, Tachibana and Nishio2000). According to Reference Aoki, Aoki, Fukabori, Hachikubo, Tachibana and NishioAoki and others (2000), smooth phase function such as Henyey–Greenstein (HG) is more suitable

than the Mie phase function to simulate the BRDF of the snow surface. So we calculated BRDF using the HG phase function obtained from the asymmetry factor as in the Mie theory.

The values of BRFs varied as functions of effective snow-grain radius and concentration of snow impurities. The refractive indices of ice used to calculate the snow BRFs were taken from the data compiled by Reference WarrenWarren (1984) and Reference Kou, Labrie and ChýlekKou and others (1993). The types of snow impurities were assumed to be a dust-like model (United States Air Force, 1985) and a soot model (United States Air Force, 1985); these impurities are, respectively, weak and strong absorbers, mixing with snow particles as an external mixture as in Reference Warren and W.J.Warren and Wiscombe (1980). The reason we assumed these to be the external mixture is that, in general, clean snow is carried by the north wind from the Sea of Okhotsk (Fig. 2) where there is no source of impurities. There are many farms around the observation site, hence the snow could be polluted with a dry deposition of local soil particles rather than soot.

The method of our algorithm for retrieving snow grain-size and the concentration of snow impurities is based on the look-up tables of the BRF at the visible and near-infrared wavelengths. The table was calculated for different snow grain-sizes, concentrations of snow impurities, viewing angles (ϕv = 0 ± 35°) and azimuth angles. Solar geometric conditions are the same as those with the AMSS observation, where θ0 = 53.5˚ and Δϕ = ± 90° We used the channels at λ = 0.545 μm for the visible and λ = 1.24, 1.64 and 2.23 μm for the near-infrared regions. Atmospheric correction at each wavelength was not made, for two reasons: (1) the atmospheric effect at a flying height of 930m is considered to be negligible; and (2) for the near-infrared regions, the effect of Rayleigh scattering would be weak. Although Rayleigh scattering is influenced by the atmospheric effect in the visible region, the BRDF pattern is not so anisotropic. Accordingly, the effect of Rayleigh scattering on the BRDF pattern in the visible region would be weak. Figure 4 shows the relationship between BRF at λ = 0.545 μm and BRF at λ = 1.64 μm at θ0 = 53.5˚ which are the same as those of the AMSS observation. The values of BRFs decrease with the increase in snow grain-size and snow impurities, and vary with the viewing angle at ϕv = 0° through 35°. When the reflectance at visible and near-infrared channels is determined from the AMSS data, the effective snow grain-size and snow impurities can be retrieved from the corresponding BRF look-up tables. For example, in Figure 4a, when the measured values of the AMSS are 0.05 at λ = 1.64 μm and 0.88 at λ = 0.545 μm at θv = 0°, the effective snow-grain radius and the concentration of impurities of dust-like particles can be retrieved as 100 μm and 10 ppmw, respectively.

Fig. 4. The relationships of theoretical BRFs between the visible (λ =0.545 μm) and the near-infrared (λ =1.64 μm) wave-lengths as functions of the concentration of snow impurities (cd and cs ) and the effective snow-grain radius (reff ). For snow impurities, (a) dust-like and (b) soot particles are assumed to contain snow particles as an external mixture. Thick lines indicate BRFs for the viewing angle θv = 0° (nadir), and broken lines the maximum viewing angles θv =\ 35°.

To verify the BRF model, the retrieved snow grain-size from the algorithm using the BRF model was compared with that from the algorithm using the isotropic reflectance model. The isotropic reflectance α(θ0, λ) is calculated by:

(4)

In the BRF (BRDF) and isotropic reflectance models, spherical ice particles were assumed, while the surface snow condition was faceted crystals (Fig. 3). According to Aoki and others (2000), the optically equivalent snow grain-size for the calculation of snow albedo by spherical ice particles is of the order of a branch width of dendrites or of a dimension of the narrower portion of broken crystals. However, for the BRDF of the snow surface consisting of non-spherical ice particles such as faceted crystal, further studies are necessary.

Result And Discussion

Effects of BRF

The AMSS channels were chosen for 0.545 μm of the visible and 1.64 μm of the near-infrared. The reason for using the channel at 1.64 μm for the near-infrared is that snow is more anisotropically reflective at λ =1.64 and 2.23 μm than at shorter wavelengths (Reference Aoki, Aoki, Fukabori, Hachikubo, Tachibana and NishioAoki and others, 2000), and the signal-to-noise ratio of the AMSS data at λ =1.64 μm is better than that at λ = 2.23 mm.

The RGB composite image observed with the AMSS is shown in Figure 5a. The results of effective snow-grain radius retrieved from the AMSS using the isotropic reflectance model and the BRF model are shown in Figure 5b and c, respectively. In this figure, white areas indicate forests, houses, roads and irrigation canals, which were masked using the difference in normalized-difference vegetation index between snow and other surfaces (Reference Saito and YamazakiSaito and Yamazaki, 1999). However, these areas would not be masked completely due to the mixture with snow. The retrieved effective snow-grain radii using the isotropic reflectance model (Fig. 5b) are generally larger than those obtained from the BRF model (Fig.5c) in a widespread area of the AMSS image, because the isotropic reflectance is higher than the BRF around nadir.

Fig. 5. (a) RGB composite image observed with AMSS. Across indicates the site of the snow-pit work shown in Figure 4. Parameters at the pixels along line A are discussed in Figures 6 and 7. Swath is 1.2 km (east–west), and the observation distance (north–south) is 4.0 km. (b, c) Effective snow-grain radius retrieved from the AMSS data with the channel combination of λ = 0.545 and 1.64 μm using the isotropic reflectance (ITR) model and the BRF model, respectively. (d, e) Same as (c), but retrieved from the channel combinations of λ =0.545 and 1.24 μmand λ =0.545 and 2.23 μm, respectively.

The observed and calculated BRFs for pixels along line A of the AMSS image in Figure 5a are shown in Figure 6a. The observed BRF of snow surface with the AMSS at λ =1.64 μm is higher at the viewing angle θv = ±35˚ than at θv = 0°. This tendency is well simulated by the BRF model, while the isotropic reflectance is constant for θv. If the snow surface is assumed to be uniform across the AMSS field of view, the retrieved snow grain-size would be a constant, independent of viewing angle. The retrieved effective snow grain-size (Fig. 6b) using the BRF model was in a narrow range of 60–74mm for the field. Using the isotropic reflectance model, grain-size varied widely, ranging from 89 to 125 mm. On the other hand, the ground-truth data (snow-pit work) show that the measured snow-grain radius (r2) at the surface layer ranged from 50 to 150 μm as shown in Figure 3. The effective snow-grain radii retrieved from the AMSS data using the two different models are 66 μm (BRF) and 114 μm (isotropic reflectance) around the site of snow-pit work indicated by a cross in Figure 5a. These retrieved results are in the range of snow-pit work results (50–150 μm). However, the retrieved snow grain-size using the isotropic reflectance model was larger around the nadir than the edge of the image. This result is unnatural for the condition of flat snowfield where observation was made only 4 days after the snowfall. Thus, we can conclude that the algorithm to retrieve the snow grain-size using the BRF model works well for the AMSS data.

Fig. 6. (a) The theoretically calculated BRFs at λ = 1.64 μm for reff = 50, 75 and 100 μm with the soot concentration of 0.1ppmw, and the observed BRF with AMSS along line A in Figure 5a. The calculated BRFs are indicated by the characters, + and 6, and the observed BRFis indicated by a solid line. (*) indicates irrigation canal. (b) Retrieved effective snow-grain radii along line A in Figure 5a using the ITR model and the BRF model.

Effective snow-grain radius and concentration of snow impurities retrieved from the AMSS data

The retrieved results of snow-grain radius using the BRF model from the AMSS data with the channel combinations of λ = 0.545 and 1.24 μm, and λ = 0.545 and 2.23 μmare shown in Figure 5d and e, respectively. Comparing these results with Figure 5c, it can be pointed out that the snow grain-size becomes smaller when using the channels of longer wavelengths in the near-infrared region. The histograms of the retrieved snow grain-size in the area of 2500 (50650) pixels around the cross in Figure 5a are shown in Figure 7. The retrieved snow grain-size is smallest when using the channel of 2.23 μm, and is largest with 1.24 μm. This can be explained by the difference in absorptivity of ice. Figure 8 shows the imaginary part of the refractive index of ice, which indicates the degree of absorption. Since the light absorption by ice is weaker at shorter wavelength in these three channels, the sunlight penetrates into deeper layers, and the reflected light conveys information on snow physical parameters from a relatively deep layer. For the channels at longer wavelengths, the light absorption is stronger, and reflected light contains information from the top layer. On the other hand, the results of snow-pit work (Fig. 3) show that the measured snow grain-sizes at the surface are smaller than those at the deeper layers. Thus, the effective snow-grain radius retrieved from the AMSS data of different near-infrared channels are related with the vertical profile of snow grain-size. Reference Li, Stamnes and ChenLi and others (2001) demonstrated the effect of photon penetration depth in the model calculation as the e-folding flux attenuation depth at wavelengths of 0.86,1.05,1.24 and 1.73 μm. Their theoretical results showed that photons with longer wavelengths penetrate less deeply into snow than those with shorter wavelengths, and therefore longer wavelengths carry information for a shallower layer of the snow. Our field results are congruent with the theoretical work of Reference Li, Stamnes and ChenLi and others (2001).

Fig. 7. Histograms of retrieved effective snow-grain radius from the AMSS data with the channel combinations of λ = 0.545 and 1.24 μm, λ =0.545 and 1.64 μm and λ = 0.545 and 2.23 μ m in the area of 2500 (50650) pixels around the cross indicated in Figure 5a.

Fig. 8. Imaginary parts of refractive index of ice, dust-like model and soot model. The stippled rectangles indicate the half-width of each AMSS channel.

Figure 9a and b show the concentrations of snow impurities retrieved from the AMSS data using the two kinds of snow-impurity models, in which dust-like and soot are weak and strong absorbers, respectively, as shown in Figure 8. The results of snow impurities retrieved from the AMSS data were about 2–5 ppmw for the dust-like model and 0.0–0.2 ppmw for the soot model. Since our observation site is in a rural area, it is possible that snow was polluted with a dry deposition of local soil particles rather than soot. The concentration of snow impurities measured from snow-pit work on 25 February 1998 was 5.2 ppmw in the layer 0–5 cm (Fig. 3). Moreover, in the electron micrograph analysis of the sampled snow impurities, many soil particles with a small amount of soot particles were observed. The absorption of general soil particles is similar to that of the dust-like model. Therefore, our retrieved results of snow impurities were roughly consistent with the results of snow-pit work. The results using the dust-like model suggest that the snowpack was contaminated with the external mixture of soil particles.

Fig. 9. The concentration of snow impurities (a) using dust-like and (b) using soot particles with the BRF model. The AMSS channel was λ = 0.545 and 1.64 μm.

Conclusion

We developed the algorithms which take into account the snow anisotropic reflectance and retrieved snow grain-size and the concentration of snow impurities using the BRDF model from the AMSS data. The retrieved results of snow grain-size and snow impurities are consistent with those of ground-truth data. In particular, the different near-infrared channels of AMSS were found to contain the information on the vertical profile of snow grain-size.

In this study, we used a one-snow-layer model to calculate the look-up table of snow BRF. However, snow is generally inhomogeneous in the vertical direction. This effect should be considered in the future. The anisotropic reflectance property of snow surface is more significant for the forward scattering direction. This correction is also an important issue for the remote sensing of snow.

Acknowledgements

We would like to thank M. Aniya (University of Tsukuba, Japan) and M. Ishizaki (Nano-electronics Research Institute, Japan) for invaluable discussion and advice. This work was conducted as part of the ADEOS-II/GLI Cal/Val experiments supported by the National Space Development Agency of Japan.

References

Aoki, T. and 6 others. 1998. Spectral albedo observations on the snow field at Barrow, Alaska. Polar Meteorol. Glaciol., 12, 1–9.Google Scholar
Aoki, T., Aoki, T., Fukabori, M. and Uchiyama, A.. 1999. Numerical simulation of the atmospheric effects on snow albedo with a multiple scattering radiative transfer model for the atmosphere–snow system. J. Meteorol. Soc. Jpn, 77(2), 595–614.Google Scholar
Aoki, T., Aoki, T., Fukabori, M., Hachikubo, A., Tachibana, Y. and Nishio, F.. 2000. Effects of snow physical parameters on spectral albedo and bi-directional reflectance of snow surface. J. Geophys. Res., 105(D8), 10,219–10,236.Google Scholar
Bourdelles, B. and Fily, M.. 1993. Snow grain-size determination from Landsat imagery over Terre Adélie, Antarctica. Ann. Glaciol., 17, 86–92.Google Scholar
Fily, M., Bourdelles, B., Dedieu, J.-P. and Sergent, C.. 1997. Comparison of in situ and Landsat thematic mapper derived snow grain characteristics in the Alps. Remote Sensing Environ., 59(3), 452–460.Google Scholar
Grenfell, T.C., Warren, S.G. and Mullen, P.C.. 1994. Reflection of solar radiation by the Antarctic snow surface at ultraviolet, visible, and near-infrared wavelengths. J. Geophys. Res., 99(D9), 18,669–18, 684.Google Scholar
Jordan, R. 1991. A one-dimensional temperature model for a snow cover: technical documentation for SNTHERM.89. CRREL Spec. Rep. 91-16.Google Scholar
Kou, L.H., Labrie, D. and Chýlek, P.. 1993. Refractive indices of water and ice in the 0.65 to 2.5 μm spectral range. Appl. Opt., 32(19), 3531–3540.Google Scholar
Li, W., Stamnes, K. and Chen, B.. 2001. Snow grain size retrieved from near-infrared radiances at multiple wavelengths. Geophys. Res. Lett., 28(9), 1699–1702.Google Scholar
Nolin, A.W. and Dozier, J.. 1993. Estimating snow grain size using AVIRIS data. Remote Sensing Environ., 44(2–3), 231–238.Google Scholar
Nolin, A.W. and Dozier, J.. 2000. A hyperspectral method for remotely sensing the grain size of snow. Remote Sensing Environ., 74(2), 207–216.Google Scholar
Nolin, A.W. and Liang, S.. 2000. Progress in bidirectional reflectance modeling and applications for surface particulate media: snow and soils. Remote Sensing Rev., 18, 307–342.Google Scholar
Saito, A. and Yamazaki, T.. 1999. [Characteristics of spectral reflectance for vegetation ground surface with snow-cover, vegetation indices and snow indices.] J. Jpn Soc. Hydrol. Water Res., 12(1), 28–38. [InJapanese.]Google Scholar
Sydor, M., Sorensen, J.A. and Shuter, V.. 1979. Remote sensing of snow albedo for determination of dustfall. Appl. Opt., 18(21), 3574–3578.Google Scholar
United States Air Force. 1985. Handbook of geophysics and the space environment. Hanscom, United States Air Force. Air Force Geophysics Laboratory.Google Scholar
Warren, S.G. 1982. Opticalproperties of snow. Rev. Geophys. SpacePhys., 20(1), 67–89.Google Scholar
Warren, S.G. 1984. Optical constants of ice from the ultraviolet to the microwave. Appl. Opt., 23(8), 1206–1225.Google Scholar
Warren, S.G. and Clarke, A.D.. 1986. Soot from Arctic haze: radiative effects on the Arctic snowpack. World Data Center A for Glaciology 〈Snow and Ice〉, Boulder, CO, Glaciological Data 18, 73–77.Google Scholar
Warren, S.G. and W.J., Wiscombe. 1980. A model for the spectral albedo of snow. II. Snow containing atmospheric aerosols. J. Atmos. Sci., 37(12), 2734–2745.Google Scholar
Wiscombe, W.J. and Warren, S.G.. 1980. A model for the spectral albedo of snow. I. Pure snow. J. Atmos. Sci., 37(12), 2712–2733.Google Scholar
Figure 0

Fig. 1. Coordinate systems for the observations by the AMSS sensor. The symbols θ0and θvare the solar zenith angle and the viewing angle from the sensor, respectively; Δϕ is the relative azimuth angle of the viewing direction from the solar direction. AMSS flew from south to north and observed the upward reflected radiance I(θ0; θv;Δϕ; λ) from the snow surface.

Figure 1

Fig. 2. Map showing the locations of the AMSS flight course in eastern Hokkaido. The AMSS observation was made at 1100 h LT, 25 February 1998. Solar zenith angle θ0 was 53.5°.

Figure 2

Fig. 3. Vertical profiles of snow parameters observed from snow-pit work on 25 February 1998. Snow grain-sizes (radius) were measured with about 10 μm resolution using a hand-held lens. There were two kinds of dimensions of grain-sizes: one was one-half the length of the major axis of crystals or dendrites (r1), and the other was one-half the branch width of dendrites or one-half the dimension of the narrower portion of broken crystals (r2). Snow impurities were collected on the Nuclepore filters, and the concentration was estimated with a balance.

Figure 3

Fig. 4. The relationships of theoretical BRFs between the visible (λ =0.545 μm) and the near-infrared (λ =1.64 μm) wave-lengths as functions of the concentration of snow impurities (cdand cs) and the effective snow-grain radius (reff). For snow impurities, (a) dust-like and (b) soot particles are assumed to contain snow particles as an external mixture. Thick lines indicate BRFs for the viewing angle θv = 0° (nadir), and broken lines the maximum viewing angles θv =\ 35°.

Figure 4

Fig. 5. (a) RGB composite image observed with AMSS. Across indicates the site of the snow-pit work shown in Figure 4. Parameters at the pixels along line A are discussed in Figures 6 and 7. Swath is 1.2 km (east–west), and the observation distance (north–south) is 4.0 km. (b, c) Effective snow-grain radius retrieved from the AMSS data with the channel combination of λ = 0.545 and 1.64 μm using the isotropic reflectance (ITR) model and the BRF model, respectively. (d, e) Same as (c), but retrieved from the channel combinations of λ =0.545 and 1.24 μmand λ =0.545 and 2.23 μm, respectively.

Figure 5

Fig. 6. (a) The theoretically calculated BRFs at λ = 1.64 μm for reff = 50, 75 and 100 μm with the soot concentration of 0.1ppmw, and the observed BRF with AMSS along line A in Figure 5a. The calculated BRFs are indicated by the characters, + and 6, and the observed BRFis indicated by a solid line. (*) indicates irrigation canal. (b) Retrieved effective snow-grain radii along line A in Figure 5a using the ITR model and the BRF model.

Figure 6

Fig. 7. Histograms of retrieved effective snow-grain radius from the AMSS data with the channel combinations of λ = 0.545 and 1.24 μm, λ =0.545 and 1.64 μm and λ = 0.545 and 2.23 μ m in the area of 2500 (50650) pixels around the cross indicated in Figure 5a.

Figure 7

Fig. 8. Imaginary parts of refractive index of ice, dust-like model and soot model. The stippled rectangles indicate the half-width of each AMSS channel.

Figure 8

Fig. 9. The concentration of snow impurities (a) using dust-like and (b) using soot particles with the BRF model. The AMSS channel was λ = 0.545 and 1.64 μm.