Effects of Soil Surface Irregularities on the Diurnal Variation of Soil Broadband Blue-Sky Albedo

Cierniewski, Jerzy; Karnieli, Arnon; Kaźmierowski, Cezary; Królewicz, Sławomir; Piekarczyk, J.; Lewińska, Karolina; Goldberg, Alexander; Wesolowski, Roman; Orzechowski, M.

doi:10.1109/jstars.2014.2330691

Cited by 44 publications

(38 citation statements)

References 30 publications

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“…In our case, the gaps in the α b F data sets resulted from the need to reject those data measured when cirrus clouds obscured the sun. The soil blue-sky albedo measurements carried out in Poland and Israel [23], also confirmed by the data generated using a hemispherical-directional model [24], indicate that the blue-sky α b of extremely rough soil surfaces rises slightly from θ s at local noon to about 75 • -80 • of the θ s , while the α b of smooth soils clearly increases throughout the θ s range. Assuming that such behavior of the soil albedo with respect to the θ s is correct, the data representing a decrease in the α b F with increasing θ s were considered incorrect.…”

Section: Resultssupporting

confidence: 63%

Evaluation of the Effects of Surface Roughness on the Relationship Between Soil BRF Data and Broadband Albedo

Cierniewski

Kaźmierowski

Królewicz

2015

IEEE J. Sel. Top. Appl. Earth Observations Remote Sensing

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This paper reports a preliminary study on correctness of the broadband albedo (αb) of cultivated soils that could be calculated by their narrowband bidirectional reflectance factors (BRF) measured from many directions with a prototype goniometric device in a laboratory on their samples with similar roughness, as these soils revealed in the field. The correctness was tested on examples of Phaeozem, Luvisol, and Albeluvisol with roughness formed by a plow, disk harrow, pulverizing harrow, and smoothing harrow. The αb values of the soils calculated using the equation proposed here were not affected by the root mean square error higher than 0.01 as compared to the data measured in the field if the BRF data were obtained on the soil samples with a sufficiently low roughness. It was found that the roughness of those soil samples should be sufficiently low to ensure that the values of their height standard deviation along the length of the minor axis of a sensor field of view area are greater than 15.Index Terms-Bidirectional reflectance factor (BRF), field and laboratory measurements, hyperspectral directional reflectance, soil surface roughness.

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Section: Resultssupporting

confidence: 63%

Evaluation of the Effects of Surface Roughness on the Relationship Between Soil BRF Data and Broadband Albedo

Cierniewski

Kaźmierowski

Królewicz

2015

IEEE J. Sel. Top. Appl. Earth Observations Remote Sensing

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“…We distinguish between surface roughness that refers to microrelief of soil surfaces due to variations and arrangement of soil aggregates (Lehrsch et al 1987;Guzha 2004) from the general relief of a surface that represents topographical structures that are many times larger than soil aggregates. Studies of heat and mass transfer from terrestrial surfaces have shown that land relief and surface roughness may affect the surface reflectively (albedo) hence the amount of shortwave radiation absorbed at the surface (Bowers and Hanks 1965;Potter et al 1987;Raupach and Finnigan 1997;Matthias et al 2000;Cierniewski et al 2014). Surface roughness and relief have also been shown to act as momentum sinks for the atmospheric flows (Raupach 1992) affecting the aerodynamic boundary layer and turbulent interactions adjacent to the surface (Perry et al 1969;Taylor and Gent 1974;Finnigan 1988;Wieringa 1993;Raupach and Finnigan 1997).…”

Section: Introductionmentioning

confidence: 99%

Evaporation from Wavy Porous Surfaces into Turbulent Airflows

Haghighi

2015

Transp Porous Med

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The relief and roughness of natural surfaces interacting with airflows and with radiation affect rates and distributions of heat and vapor fluxes into the atmosphere. The study quantifies interactions of regular sinusoidal wavy porous surfaces (with different geometrical characteristics) affecting heat and vapor transport into prescribed turbulent airflows. A model for turbulent eddies interacting with an undulating evaporating surface with mean boundary layer that varies across sinusoidal wavy surfaces was developed and experimentally evaluated in a wind tunnel. The surface of a 1 m 2 shallow (0.3 m deep) sand-filled basin was imprinted with regular sinusoidal ridges and troughs; water content and temperature sensors were embedded in the sand, and the instrumented basin was placed on a balance in the wind tunnel. Detailed thermal signatures of the evaporating surface for different wind speeds and surface patterns were obtained using high-resolution infrared thermography. The evaporative mass loss measurements and observed thermal patterns were in good agreement with model predictions for turbulent exchange over various wavy sand surface geometries. Results suggest that evaporative fluxes can be either enhanced or suppressed (relative to a flat surface) due to complex interplay between local boundary layer thickness and internal limitations to water flow to the evaporating surface. For a practical range of air velocities (0.5-4.0 m/s), and for sinusoidal configurations studied (amplitudes of 50-100 mm), the evaporative mass loss (relative to the flat surface) was reduced by up to 60 % for low surface aspect ratio and high wind velocity, and enhanced by up to 80 % for high aspect ratio and low wind velocity. The study offers a framework for interpreting and upscaling evaporative fluxes from rough terrestrial surfaces. Ongoing work considers shortwave radiation and geometrical interactions for a more complete account of surface energy balance and fluxes from natural rough surfaces. A b Surface area of wavy building block (m 2 ) C a Vapor concentration in air (kg/m 3 ) C s Saturated vapor concentration (kg/m 3 ) c 1 Coefficient in Eq. (1) (-) c 2 Coefficient in Eq. (4) (-) c 3 Coefficient in Eq. (4) (-) c 4 Coefficient in Eq. (8) (-) c p Air-specific heat capacity (J/kg K) D Water vapor diffusion coefficient in air (m 2 /s) E Evaporation flux (kg/m 2 s) E o Potential evaporation flux (kg/m 2 s) e Total evaporation rate (kg/s) e b Evaporation rate from wavy building block (kg/s) g h Aerodynamic conductance (m/s) H Drying front depth (m) H C Evaporative characteristic length (m) H G Gravity characteristic length (m) H wt Water table depth measured from ridges (m) K a Air thermal conductivity (W/mK) K eff Effective hydraulic conductivity (m/s) K s Saturated hydraulic conductivity (m/s) Length of evaporating system (m) M w Molar mass of water (kg/mol) m Largest integer smaller than α (-) N b Number of wavy building blocks (-) n Pore size distribution index (-) P sat Saturated vapor pressure (Pa) R BL Boundary layer resi...

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“…The higher the diffuse light ratio, the smaller the impact of θ s on the albedo. Cierniewski et al [16] analysed the diurnal albedo variations of soils to find that soil roughness affected not only the overall level of those variations, but also that the intensity of its increase from θ s at the local noon, to about 75 • -80 • . Surfaces of rough and deep ploughed soils showed almost no rise in albedo values at θ s lower than 75 • , while the same soil, but smoothed, exhibited a gradual albedo increase at these angles.…”

Section: Introductionmentioning

confidence: 99%

Shortwave Radiation Affected by Agricultural Practices

et al. 2018

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Abstract:The albedo of bare soil depends on its organic matter, iron oxide, carbonate contents, and reflectance geometry, features considered stable over time, and also depends on salinity, moisture and roughness, which change dynamically due to agricultural practices. This paper deals with the quantitative estimation of the amount of shortwave radiation that could be reflected by air-dried bare soils in clear-sky conditions within arable lands in Israel throughout the year, assuming that they were shaped by a plough, a disk harrow, or a smoothing harrow. An area of bare soils was extracted from Landsat 8 images, within the contours of arable lands. The radiation reflected from the bare soils was calculated by equations predicting variations in their half-diurnal albedo as the solar zenith angle function. Accordingly, laboratory reflectance data of Israeli soil samples were used. The results clearly showed annual variation in the amount of short-wave radiation reflected from all bare soils within arable lands. The minimum radiation occurred in the winter, between the 1st and 70th day of the year (DOY), and the maximum was identified in the summer between 200th and 250th DOY. This could reach about 3-5 PJ/day and 16-23 PJ/day, respectively.

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Effects of Soil Surface Irregularities on the Diurnal Variation of Soil Broadband Blue-Sky Albedo

Cited by 44 publications

References 30 publications

Evaluation of the Effects of Surface Roughness on the Relationship Between Soil BRF Data and Broadband Albedo

Evaluation of the Effects of Surface Roughness on the Relationship Between Soil BRF Data and Broadband Albedo

Evaporation from Wavy Porous Surfaces into Turbulent Airflows

Shortwave Radiation Affected by Agricultural Practices

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