Search engine for discovering works of Art, research articles, and books related to Art and Culture
Javascript must be enabled to continue!
A global 0.05° maximum albedo dataset of snow‐covered land based on MODIS observations
View through CrossRef
A new global 0.05° maximum albedo for snow‐covered land is developed from BRDF/Albedo, reflectance and land cover measured from the MODIS sensor on board the Terra and Aqua satellites. The dataset is similar to previous maximum snow albedo datasets, but is available at higher resolution. The dataset displays: (1) high albedo at very high latitudes with tundra and open shrub land cover; (2) a local minimum (0.35) in zonally‐averaged albedo at 56–60°N due to boreal forest cover; and (3) a local maximum (0.70) in zonally‐averaged albedo at 42–45°N due to crop and grassland. The dataset is tested in the Noah land model at 0.125° resolution as used in the North American Land Data Assimilation System. Compared with the original data, the new dataset increases the spatial heterogeneity in the Noah model during winter and produces surface energy component differences of 10 W/m2 during the snowmelt period.
American Geophysical Union (AGU)
Title: A global 0.05° maximum albedo dataset of snow‐covered land based on MODIS observations
Description:
A new global 0.
05° maximum albedo for snow‐covered land is developed from BRDF/Albedo, reflectance and land cover measured from the MODIS sensor on board the Terra and Aqua satellites.
The dataset is similar to previous maximum snow albedo datasets, but is available at higher resolution.
The dataset displays: (1) high albedo at very high latitudes with tundra and open shrub land cover; (2) a local minimum (0.
35) in zonally‐averaged albedo at 56–60°N due to boreal forest cover; and (3) a local maximum (0.
70) in zonally‐averaged albedo at 42–45°N due to crop and grassland.
The dataset is tested in the Noah land model at 0.
125° resolution as used in the North American Land Data Assimilation System.
Compared with the original data, the new dataset increases the spatial heterogeneity in the Noah model during winter and produces surface energy component differences of 10 W/m2 during the snowmelt period.
Related Results
Characteristics of Taiga and Tundra Snowpack in Development and Validation of Remote Sensing of Snow
Characteristics of Taiga and Tundra Snowpack in Development and Validation of Remote Sensing of Snow
Remote sensing of snow is a method to measure snow cover characteristics without direct physical contact with the target from airborne or space-borne platforms. Reliable estimates ...
Snow representation in seasonal forecasts and climate simulations: sensitivities of seasonal snow simulation and impact on frozen soils
Snow representation in seasonal forecasts and climate simulations: sensitivities of seasonal snow simulation and impact on frozen soils
Snow cover is a critical component of the Earth's climate system, covering up to 44 % of the Northern Hemisphere's land during winter and influencing energy exchange, water storage...
Influence of cohesion on drifting snow investigated in cold wind-tunnel 
Influence of cohesion on drifting snow investigated in cold wind-tunnel 
<p>Aeolian transport of particles occurs in many geophysical contexts such as wind-blown sand or snow drift and is governed by a myriad of physical mechanisms. Most o...
Spatiotemporal Evolution of the Land Cover over Deception Island, Antarctica, Its Driving Mechanisms and Its Impact on the Shortwave Albedo
Spatiotemporal Evolution of the Land Cover over Deception Island, Antarctica, Its Driving Mechanisms and Its Impact on the Shortwave Albedo
The aim of this work is to provide a full description of how air temperature and solar radiation induce changes in the land cover over an Antarctic site. We use shortwave broadband...
Assimilation of Satellite Albedo to Improve Simulations of Glacier Hydrology
Assimilation of Satellite Albedo to Improve Simulations of Glacier Hydrology
Wildfires and heatwaves have recently affected the hydrological system
in unprecedented ways due to climate change. In cold regions, these
extremes cause rapid reductions in snow a...
Effective UV surface albedo of seasonally snow-covered lands
Effective UV surface albedo of seasonally snow-covered lands
Abstract. At ultraviolet wavelengths the albedo of most natural surfaces is small with the striking exception of snow and ice. Therefore, snow cover is a major challenge for variou...
A snow reanalysis for Italy: IT-SNOW
A snow reanalysis for Italy: IT-SNOW
Quantifying the amount of snow deposited across the landscape at any given time is the main goal of snow hydrology. Yet, answering this apparently simple question is still elusive ...
Dynamic Snow Distribution Modeling using the Fokker-Planck Equation Approach
Dynamic Snow Distribution Modeling using the Fokker-Planck Equation Approach
<p>The Fokker-Planck equation (FPE) describes the time evolution of the distribution function of fluctuating macroscopic variables.&#160; Although the FPE was...