Surface energy budget over the central Arctic Ocean during late summer and early freeze-up

AbstractUrban facets—the walls, roofs, and ground in built-up terrain—are often conceptualized as homogeneous surfaces, despite the obvious variability in the composition and material properties of the urban fabric at the subfacet scale. This study focuses on understanding the influence of this subfacet heterogeneity, and the associated influence of different material properties, on the urban surface energy budget. The Princeton Urban Canopy Model, which was developed with the ability to capture subfacet variability, is evaluated at sites of various building densities and then applied to simulate the energy exchanges of each subfacet with the atmosphere over a densely built site. The analyses show that, although all impervious built surfaces convert most of the incoming energy into sensible heat rather than latent heat, sensible heat fluxes from asphalt pavements and dark rooftops are 2 times as high as those from concrete surfaces and light-colored roofs. Another important characteristic of urban areas—the shift in the peak time of sensible heat flux in comparison with rural areas—is here shown to be mainly linked to concrete’s high heat storage capacity as well as to radiative trapping in the urban canyon. The results also illustrate that the vegetated pervious soil surfaces that dot the urban landscape play a dual role: during wet periods they redistribute much of the available energy into evaporative fluxes but when moisture stressed they behave more like an impervious surface. This role reversal, along with the direct evaporation of water stored over impervious surfaces, significantly reduces the overall Bowen ratio of the urban site after rain events.

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Measuring the impact of a new snow model using surface energy budget process relationships

10.1002/essoar.10502951.1 ◽

2020 ◽

Author(s):

Jonathan Day ◽

Gabriele Arduini ◽

Irina Sandu ◽

Linus Magnusson ◽

Anton Beljaars ◽

...

Keyword(s):

Surface Energy ◽

Energy Budget ◽

Surface Energy Budget ◽

Budget Process ◽

Snow Model ◽

The Impact

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Projected Changes in Soil Temperature and Surface Energy Budget Components over the Alps and Northern Italy

Water ◽

10.3390/w10070954 ◽

2018 ◽

Vol 10 (7) ◽

pp. 954 ◽

Cited By ~ 2

Author(s):

Claudio Cassardo ◽

Seon Park ◽

Sungmin O ◽

Marco Galli

Keyword(s):

Heat Flux ◽

Surface Energy ◽

Soil Temperature ◽

Energy Budget ◽

Regional Climate ◽

Northern Italy ◽

Surface Energy Budget ◽

Future Climate ◽

Radiative Properties ◽

The Alps

This study investigates the potential changes in surface energy budget components under certain future climate conditions over the Alps and Northern Italy. The regional climate scenarios are obtained though the Regional Climate Model version 3 (RegCM3) runs, based on a reference climate (1961–1990) and the future climate (2071–2100) via the A2 and B2 scenarios. The energy budget components are calculated by employing the University of Torino model of land Processes Interaction with Atmosphere (UTOPIA), and using the RegCM3 outputs as input data. Our results depict a significant change in the energy budget components during springtime over high-mountain areas, whereas the most relevant difference over the plain areas is the increase in latent heat flux and hence, evapotranspiration during summertime. The precedence of snow-melting season over the Alps is evidenced by the earlier increase in sensible heat flux. The annual mean number of warm and cold days is evaluated by analyzing the top-layer soil temperature and shows a large increment (slight reduction) of warm (cold) days. These changes at the end of this century could influence the regional radiative properties and energy cycles and thus, exert significant impacts on human life and general infrastructures.

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Examination of the Surface Energy Budget: A Comparison of Eddy Correlation and Bowen Ratio Measurement Systems

Journal of Hydrometeorology ◽

10.1175/1525-7541(2003)4<160:eotseb>2.0.co;2 ◽

2003 ◽

Vol 4 (2) ◽

pp. 160-178 ◽

Cited By ~ 72

Author(s):

Jerald A. Brotzge ◽

Kenneth C. Crawford

Keyword(s):

Surface Energy ◽

Energy Budget ◽

Bowen Ratio ◽

Surface Energy Budget ◽

Eddy Correlation ◽

Ratio Measurement ◽

Measurement Systems

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The Surface Energy Budget at Gale Crater during the first 2500 sols of the Mars Science Laboratory mission

Journal of Geophysical Research Planets ◽

10.1029/2020je006804 ◽

2021 ◽

Author(s):

G. M. Martínez ◽

A. Vicente‐Retortillo ◽

A. R. Vasavada ◽

C. E. Newman ◽

E. Fischer ◽

...

Keyword(s):

Surface Energy ◽

Energy Budget ◽

Surface Energy Budget ◽

Science Laboratory ◽

Mars Science Laboratory ◽

Gale Crater

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Downslope föhn winds over the Antarctic Peninsula and their effect on the Larsen ice shelves

Atmospheric Chemistry and Physics ◽

10.5194/acp-14-9481-2014 ◽

2014 ◽

Vol 14 (18) ◽

pp. 9481-9509 ◽

Cited By ~ 19

Author(s):

D. P. Grosvenor ◽

J. C. King ◽

T. W. Choularton ◽

T. Lachlan-Cope

Keyword(s):

Heat Flux ◽

Wind Speed ◽

Surface Energy ◽

Antarctic Peninsula ◽

Energy Budget ◽

Surface Flux ◽

Surface Energy Budget ◽

Ice Shelf ◽

Aircraft Observations ◽

The Antarctic

Abstract. Mesoscale model simulations are presented of a westerly föhn event over the Antarctic Peninsula mountain ridge and onto the Larsen C ice shelf, just south of the recently collapsed Larsen B ice shelf. Aircraft observations showed the presence of föhn jets descending near the ice shelf surface with maximum wind speeds at 250–350 m in height. Surface flux measurements suggested that melting was occurring. Simulated profiles of wind speed, temperature and wind direction were very similar to the observations. However, the good match only occurred at a model time corresponding to ~9 h before the aircraft observations were made since the model föhn jets died down after this. This was despite the fact that the model was nudged towards analysis for heights greater than ~1.15 km above the surface. Timing issues aside, the otherwise good comparison between the model and observations gave confidence that the model flow structure was similar to that in reality. Details of the model jet structure are explored and discussed and are found to have ramifications for the placement of automatic weather station (AWS) stations on the ice shelf in order to detect föhn flow. Cross sections of the flow are also examined and were found to compare well to the aircraft measurements. Gravity wave breaking above the mountain crest likely created a~situation similar to hydraulic flow and allowed föhn flow and ice shelf surface warming to occur despite strong upwind blocking, which in previous studies of this region has generally not been considered. Our results therefore suggest that reduced upwind blocking, due to wind speed increases or stability decreases, might not result in an increased likelihood of föhn events over the Antarctic Peninsula, as previously suggested. The surface energy budget of the model during the melting periods showed that the net downwelling short-wave surface flux was the largest contributor to the melting energy, indicating that the cloud clearing effect of föhn events is likely to be the most important factor for increased melting relative to non-föhn days. The results also indicate that the warmth of the föhn jets through sensible heat flux ("SH") may not be critical in causing melting beyond boundary layer stabilisation effects (which may help to prevent cloud cover and suppress loss of heat by convection) and are actually cancelled by latent heat flux ("LH") effects (snow ablation). It was found that ground heat flux ("GRD") was likely to be an important factor when considering the changing surface energy budget for the southern regions of the ice shelf as the climate warms.

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Case analyses and numerical simulation of soil thermal impacts on land surface energy budget based on an off-line land surface model

Advances in Atmospheric Sciences ◽

10.1007/s00376-002-0082-0 ◽

2002 ◽

Vol 19 (3) ◽

pp. 500-512 ◽

Cited By ~ 5

Author(s):

Guo Weidong ◽

Sun Shufen ◽

Qian Yongfu

Keyword(s):

Numerical Simulation ◽

Surface Energy ◽

Energy Budget ◽

Land Surface ◽

Land Surface Model ◽

Surface Energy Budget ◽

Surface Model

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Arctic Cloud Fraction and Radiative Fluxes in Atmospheric Reanalyses

Journal of Climate ◽

10.1175/2008jcli2213.1 ◽

2009 ◽

Vol 22 (9) ◽

pp. 2316-2334 ◽

Cited By ~ 95

Author(s):

John E. Walsh ◽

William L. Chapman ◽

Diane H. Portis

Keyword(s):

Surface Energy ◽

Energy Budget ◽

Radiative Forcing ◽

Cloud Fraction ◽

Surface Energy Budget ◽

Japan Meteorological Agency ◽

Central Research ◽

Radiative Fluxes ◽

Arctic Clouds ◽

Cloud Radiative Forcing

Abstract Arctic radiative fluxes, cloud fraction, and cloud radiative forcing are evaluated from four currently available reanalysis models using data from the North Slope of Alaska (NSA) Barrow site of the Atmospheric Radiation Measurement Program (ARM). A primary objective of the ARM–NSA program is to provide a high-resolution dataset of direct measurements of Arctic clouds and radiation so that global climate models can better parameterize high-latitude cloud radiative processes. The four reanalysis models used in this study are the 1) NCEP–NCAR global reanalysis, 2) 40-yr ECMWF Re-Analysis (ERA-40), 3) NCEP–NCAR North American Regional Reanalysis (NARR), and 4) Japan Meteorological Agency and Central Research Institute of Electric Power Industry 25-yr Reanalysis (JRA25). The reanalysis models simulate the radiative fluxes well if/when the cloud fraction is simulated correctly. However, the systematic errors of climatological reanalysis cloud fractions are substantial. Cloud fraction and radiation biases show considerable scatter, both in the annual mean and over a seasonal cycle, when compared to those observed at the ARM–NSA. Large seasonal cloud fraction biases have significant impacts on the surface energy budget. Detailed comparisons of ARM and reanalysis products reveal that the persistent low-level cloud fraction in summer is particularly difficult for the reanalysis models to capture creating biases in the shortwave radiation flux that can exceed 160 W m−2. ERA-40 is the best performer in both shortwave and longwave flux seasonal representations at Barrow, largely because its simulation of the cloud coverage is the most realistic of the four reanalyses. Only two reanalyses (ERA-40 and NARR) capture the observed transition from positive to negative surface net cloud radiative forcing during a 2–3-month period in summer, while the remaining reanalyses indicate a net warming impact of Arctic clouds on the surface energy budget throughout the entire year. The authors present a variable cloud radiative forcing metric to diagnose the erroneous impact of reanalysis cloud fraction on the surface energy balance. The misrepresentations of cloud radiative forcing in some of the reanalyses are attributable to errors in both simulated cloud amounts and the models’ radiative response to partly cloudy conditions.

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