Climatological Observations and Predicted Sublimation Rates at Lake Hoare, Antarctica

Clow, Gary D.; McKay, Christopher P.; Simmons, George M.; Wharton, Robert A.

doi:10.1175/1520-0442(1988)001<0715:coapsr>2.0.co;2

Cited by 337 publications

(163 citation statements)

References 0 publications

Supporting

Mentioning

152

Contrasting

Order By: Relevance

“…At the same time, air temperatures must allow for a balance between the accretion of new (bottom) ice and the ablation of old (surface) ice. The ablation rate of the Lake Fryxell ice cover varies considerably because of summertime melt and the dry katabatic winds which are most frequent during non-summer months (Henderson et al, 1966;Doran et al, 2002b (Clow et al, 1988). Much higher ablation rates, up to ,1.5 m yr…”

Section: Study Areamentioning

confidence: 99%

“…Downwelling PAR was measured on the ice surface, next to the sediment, with a Licor 190-SA quantum detector and LI-1000 datalogger. These values were converted to shortwave irradiance using a conversion factor of 0.5 W m 22 per mmol photon m 22 s 21 (Clow et al, 1988). Albedos of beach sand and ice table ( Fig.…”

Section: Field Experimentsmentioning

confidence: 99%

“…Based on MCM LTER records for [2001][2002][2003][2004], the surface ablation rates at Lake Fryxell during the months of December and January were an order of magnitude greater than during other months. Intraseasonal variation in surface ablation was also noted at Lake Hoare by Clow et al (1988) and is likely associated with summertime melting at the ice surface. The ice cover thickness of Lake Fryxell ranged from 3.8 to 4.5 m between 1961 and 1963 (Henderson et al, 1966), and from 3.5 to 6.0 m between 1995 and 2006 (Priscu, unpublished data; MCM LTER).…”

mentioning

confidence: 99%

See 2 more Smart Citations

Sediment Melt-Migration Dynamics in Perennial Antarctic Lake Ice

Jepsen¹,

Adams

Priscu

2010

Arctic, Antarctic, and Alpine Research

View full text Add to dashboard Cite

Section: Study Areamentioning

confidence: 99%

Section: Field Experimentsmentioning

confidence: 99%

mentioning

confidence: 99%

See 1 more Smart Citation

Sediment Melt-Migration Dynamics in Perennial Antarctic Lake Ice

Jepsen¹,

Adams

Priscu

2010

Arctic, Antarctic, and Alpine Research

View full text Add to dashboard Cite

“…Similar results have been reported on the basis of data from automatic weather stations (AWS, Kikuchi et al, 1988;Allison, 1985;Clow et al, 1988;Stearns and Weidner, 1993;Reijmer and Oerlemans, 2002;Renfrew and Anderson, 2002), as well as theoretical and numerical modelling studies (Gallée and Schayes, 1992;Parish et al, 1993;Sorbjan et al, 1986;.…”

Section: Introductionmentioning

confidence: 99%

Daily cycle of the surface energy balance in Antarctica and the influence of clouds

Broeke

Reijmer

et al. 2006

Intl Journal of Climatology

View full text Add to dashboard Cite

We present the summertime daily cycle of the Antarctic surface energy balance (SEB) and its sensitivity to cloud cover. We use data of automatic weather stations (AWS) located in four major Antarctic climate zones: the coastal ice shelf, the coastal and interior katabatic wind zone and the interior plateau. Absorbed short wave radiation drives the daily cycle of the SEB, in spite of the high surface albedo (0.84-0.88). The dominant heat sink is the cooling by long wave radiation, but this flux is distributed more evenly throughout the day so that a pronounced daily cycle in net all-wave radiation remains with all-sky night-time heat losses of 20-30 W m −2 and noontime heat gains of 30-40 W m −2 . During the night, heat is re-supplied to the snow surface by the sensible heat flux, especially in the katabatic wind zone, and the sub-surface heat flux. Daytime radiative energy excess is removed from the surface by sublimation (except at the high plateau) and sub-surface heat transport. Daytime convection occurs at all sites around solar noon but is generally weak. Spatial differences in the SEB are largely controlled by differences in cloud cover. Clouds are associated with higher surface temperatures and near-surface wind speeds. This especially limits nocturnal cooling, so that the strongest daytime convection is found during overcast conditions on the interior plateau.

show abstract

“…When AWSs are equipped with sonic height rangers, precipitation events can be monitored (Reijmer and van den Broeke, 2003) to support the interpretation of climate records in firn/ice cores (Helsen et al, in press). If humidity measurements are available, then similarity theory may be used to calculate sublimation from AWS data (Clow et al, 1988;Stearns and Weidner, 1993; in press a). Reliable radiation sensors deployed on AWSs have improved our knowledge of the surface radiation balance in Antarctica (van den Broeke et al, 2004a,b).…”

Section: Introductionmentioning

confidence: 99%

Sensible heat exchange at the Antarctic snow surface: a study with automatic weather stations

Broeke

Reijmer

et al. 2005

Intl Journal of Climatology

View full text Add to dashboard Cite

Data of four automatic weather stations (AWSs) are used to calculate the turbulent exchange of sensible heat at the Antarctic snow surface for a 4 year period (1998)(1999)(2000)(2001). The AWSs are situated on the ice shelf, in the coastal/inland katabatic wind zone and on the interior plateau in Dronning Maud Land, East Antarctica. Sensible heat flux (SHF) is calculated using the aerodynamic 'bulk' method between a single AWS sensor level and the surface, in combination with surface temperature derived from upwelling longwave radiation and surface roughness derived from eddy correlation measurements. Good agreement is found between calculated and directly measured SHF. All AWS sites show a downwarddirected average sensible heat transport, but otherwise the differences between the various zones are large. The surface roughness for momentum differs by an order of magnitude between the interior plateau (0.02 mm) and the katabatic wind zone (0.16 mm). On the ice shelf, frequent clouds limit surface cooling, and annual mean SHF is small (8 W m −2 ). In contrast, clear skies prevail on the interior plateau, but weak winds, an aerodynamically smooth surface and stability effects limit annual mean SHF to an equally low value (8 W m −2 ). The most favourable conditions for sensible heat exchange are found in the katabatic wind zone, where a combination of strong winds, relatively little cloud cover and a rougher surface results in annual mean SHF values of 22 to 24 W m −2 .

show abstract

Climatological Observations and Predicted Sublimation Rates at Lake Hoare, Antarctica

Cited by 337 publications

References 0 publications

Sediment Melt-Migration Dynamics in Perennial Antarctic Lake Ice

Sediment Melt-Migration Dynamics in Perennial Antarctic Lake Ice

Daily cycle of the surface energy balance in Antarctica and the influence of clouds

Sensible heat exchange at the Antarctic snow surface: a study with automatic weather stations

Contact Info

Product

Resources

About