The Antarctic Plateau is a promising site to monitor microwave radiometers' drift, and to inter-calibrate microwave radiometers, especially 1.4 GHz (L-band) radiometers on board the Soil Moisture and Ocean Salinity (SMOS), and AquariusSAC-D missions. The Plateau is a thick ice cover, thermally stable in depth, with large dimensions, and relatively low heterogeneities. In addition, its high latitude location in the Southern Hemisphere enables frequent observations by polar-orbiting satellites, and no contaminations by radio frequency interference. At Dome C (75S, 123E), on the Antarctic Plateau, the substantial amount of in-situ snow measurements available allows us to interpret variations in space-borne microwave brightness temperature (TB) (e.g. Macelloni et al., 2007, 2013, Brucker et al., 2011, Champollion et al., 2013). However, to analyze the observations from the Aquarius radiometers, whose sensitivity is 0.15 K, the stability of the snow layers near the surface that are most susceptible to rapidly change needs to be precisely assessed. This study focuses on the spatial and temporal variations of the Aquarius TB over the Antarctic Plateau, and at Dome C in particular, to highlight the impact of snow surface metamorphism on the TB observations at L-band

Brucker, Ludovic

Champollion, Nicolas

Dinnat, Emmanuel Phillippe

Picard, Ghislain

NASA Technical Reports Server

Motivations TB(x,y) TB(t) Surface state Conclusion
Aquarius brightness temperature variations at
Dome C and snow metamorphism at the surface
Ludovic Brucker1,2, Emmanuel Dinnat1,3,
Ghislain Picard4, and Nicolas Champollion4
1 NASA GSFC Cryospheric Sciences Lab., code 615, Greenbelt, MD, USA
2 Universities Space Research Association – GESTAR
3 Chapman University, Orange, CA, USA
4 Uni. Grenoble Alpes/CNRS, LGGE, Grenoble, France
p. 1 ludovic.brucker@nasa.gov L-band TB variations at Dome C and snow metamorphism
https://ntrs.nasa.gov/search.jsp?R=20150000372 2019-08-31T14:35:57+00:00Z
Motivations TB(x,y) TB(t) Surface state Conclusion
Motivations
The Antarctic ice sheet is both an actor in the climate system
and an indicator of its evolution
Ice sheet area ∼ 14.106 km2
Antarctica contains ∼ 90% of total ice on Earth
Number of Automatic Weather Station ∼ 100
p. 2 ludovic.brucker@nasa.gov L-band TB variations at Dome C and snow metamorphism
Motivations TB(x,y) TB(t) Surface state Conclusion
Motivations
The Antarctic ice sheet is both an actor in the climate system
and an indicator of its evolution
Ice sheet area ∼ 14.106 km2
Antarctica contains ∼ 90% of total ice on Earth
Number of Automatic Weather Station ∼ 100
How to monitor ice temperature?
⇒ climate models (global, or regional)
⇒ reanalysis (ERA-interim, MERRA...)
⇒ remote sensing
p. 3 ludovic.brucker@nasa.gov L-band TB variations at Dome C and snow metamorphism
Motivations TB(x,y) TB(t) Surface state Conclusion
Motivations
Motivated by L-band deep-penetration observations over Antarctica to:
- Analyze their spatial distribution
- Assess the observations’ stability
- Contribute to deﬁne cal/val and intercalibration experiments
Important initial tasks toward retrieving snow & ice properties
p. 4 ludovic.brucker@nasa.gov L-band TB variations at Dome C and snow metamorphism
Motivations TB(x,y) TB(t) Surface state Conclusion
The current 1.4 GHz (L-band) space-borne radiometers
Aquarius SMOS
p. 5 ludovic.brucker@nasa.gov L-band TB variations at Dome C and snow metamorphism
Motivations TB(x,y) TB(t) Surface state Conclusion
The current 1.4 GHz (L-band) space-borne radiometers
Aquarius
Designed for sea surface salinity retrievals
Operates 3 non-scanning radiometers
Radiometer 1 2 3
Incidence angle (o) 29.2 38.4 46.3
Footprint size (km×km) 76×94 84×120 97×156
Northernmost latitude (o) 84.99 86.07 87.40
Southernmost latitude (o) 79.01 77.90 76.54
Large footprint sizes, but
Excellent sensitivity of 0.2 K
p. 6 ludovic.brucker@nasa.gov L-band TB variations at Dome C and snow metamorphism
Motivations TB(x,y) TB(t) Surface state Conclusion
The current 1.4 GHz (L-band) space-borne radiometers
Aquarius
Designed for sea surface salinity retrievals
Operates 3 non-scanning radiometers
Radiometer 1 2 3
Incidence angle (o) 29.2 38.4 46.3
Footprint size (km×km) 76×94 84×120 97×156
Northernmost latitude (o) 84.99 86.07 87.40
Southernmost latitude (o) 79.01 77.90 76.54
Large footprint sizes, but
Excellent sensitivity of 0.2 K
SMOS
Designed for moisture & salinity
Radiometer with aperture synthesis
Multiple incidence angles (0–65o)
Finer spatial resolution (30–90 km)
Coarser sensitivity (2–2.5 K)
p. 7 ludovic.brucker@nasa.gov L-band TB variations at Dome C and snow metamorphism
Motivations TB(x,y) TB(t) Surface state Conclusion
Outline
1. Spatial distribution of Aquarius TB in Antarctica
2. Temporal Aquarius TB variations at Dome C
3. Impact of snow surface state
3.1 Comparison with AMSU-B grain index
3.2 Comparison with surface-based IR surface pictures
4. Conclusion
p. 8 ludovic.brucker@nasa.gov L-band TB variations at Dome C and snow metamorphism
Motivations TB(x,y) TB(t) Surface state Conclusion
Antarctica
Weekly mean brightness temperature (vertical polarization, radiometer 3 θinc ∼ 46.3o)
Winter Summer
Coastal open water/sea ice modiﬁes Aquarius TB
(Brucker et al., 2014 TC)
p. 9 ludovic.brucker@nasa.gov L-band TB variations at Dome C and snow metamorphism
Motivations TB(x,y) TB(t) Surface state Conclusion
East Antarctica
Annual mean and standard deviation TB (radiometer 1, θinc ∼ 29.2o)
TB V
Stdev TB V
TB H
Stdev TB H
Areas where melt events occurred since August 1, 2000 were masked.
There are grid cells (36 km) without observations.
p. 10 ludovic.brucker@nasa.gov L-band TB variations at Dome C and snow metamorphism
Motivations TB(x,y) TB(t) Surface state Conclusion
Dome C, Antarctic Plateau (3240 m)
Snow temperature below 15 m:
218.42±0.07 K (Brucker et al., 2011)
Snow accumulation:
8–10 cm of snow (Urbini et al., 2008)
Ideal site to study the relationship: microwave observations – ice properties
p. 11 ludovic.brucker@nasa.gov L-band TB variations at Dome C and snow metamorphism
Motivations TB(x,y) TB(t) Surface state Conclusion
Dome C – TB timeseries
Beam TB V (K)
3 209.50±0.26
2 206.79±0.25
1 202.54±0.28
Beam TB H (K)
1 189.97±0.44
2 186.22±0.53
3 181.39±0.72
Sensitivity ∼0.2K
p. 12 ludovic.brucker@nasa.gov L-band TB variations at Dome C and snow metamorphism
Motivations TB(x,y) TB(t) Surface state Conclusion
Dome C – TB angular diagram
Beam TB V (K)
3 209.50±0.26
2 206.79±0.25
1 202.54±0.28
Beam TB H (K)
1 189.97±0.44
2 186.22±0.53
3 181.39±0.72
Sensitivity ∼0.2K
p. 13 ludovic.brucker@nasa.gov L-band TB variations at Dome C and snow metamorphism
Motivations TB(x,y) TB(t) Surface state Conclusion
Dome C – TB timeseries
Beam TB V (K)
3 209.50±0.26
2 206.79±0.25
1 202.54±0.28
Beam TB H (K)
1 189.97±0.44
2 186.22±0.53
3 181.39±0.72
Sensitivity ∼0.2K
Fast variations  surface changes?
p. 14 ludovic.brucker@nasa.gov L-band TB variations at Dome C and snow metamorphism
Motivations TB(x,y) TB(t) Surface state Conclusion
Dome C – TB H/V timeseries
Focus on TBHTBV . removes the dependency on the physical temperature
. highlights emissivity variations
p. 15 ludovic.brucker@nasa.gov L-band TB variations at Dome C and snow metamorphism
Motivations TB(x,y) TB(t) Surface state Conclusion
Dome C – TB H/V timeseries
Focus on TBHTBV . removes the dependency on the physical temperature
. highlights emissivity variations
Radiometer 1
(θinc ∼ 29.2o)
Radiometer 2
(θinc ∼ 38.4o)
Radiometer 3
(θinc ∼ 46.3o)
Variation > 0.001 is above the radiometric noise
The largest variations are observed by radiometer 3
p. 16 ludovic.brucker@nasa.gov L-band TB variations at Dome C and snow metamorphism
Motivations TB(x,y) TB(t) Surface state Conclusion
Satellite monitoring of the snow surface at Dome C
AMSU-B grain index derived from AMSU-B (Picard et al., 2012),
GI = 1− TB150TB89 with shallow penetration (few cm) channels
p. 17 ludovic.brucker@nasa.gov L-band TB variations at Dome C and snow metamorphism
Motivations TB(x,y) TB(t) Surface state Conclusion
Satellite monitoring of the snow surface at Dome C
AMSU-B grain index derived from AMSU-B (Picard et al., 2012),
GI = 1− TB150TB89 with shallow penetration (few cm) channels
Typical penetration depths in ice
89 GHz  <0.2 m
37 GHz  <1 m
19 GHz  3-5 m
10 GHz  10-15 m
6.9 GHz  >20 m
(Surdyk, 2002)
L-band observations have a large penetration in ice
p. 18 ludovic.brucker@nasa.gov L-band TB variations at Dome C and snow metamorphism
Motivations TB(x,y) TB(t) Surface state Conclusion
Satellite monitoring of the snow surface at Dome C
AMSU-B grain index derived from AMSU-B (Picard et al., 2012),
GI = 1− TB150TB89 with shallow penetration (few cm) channels

 

	


Good synchronization of the variations in summer
p. 19 ludovic.brucker@nasa.gov L-band TB variations at Dome C and snow metamorphism
Motivations TB(x,y) TB(t) Surface state Conclusion
Surface-based monitoring of the snow surface at Dome C
(Champollion et al., 2013)
Near IR camera
2 m high
imaged area ∼ 4 m2
p. 20 ludovic.brucker@nasa.gov L-band TB variations at Dome C and snow metamorphism
Motivations TB(x,y) TB(t) Surface state Conclusion
Surface-based monitoring of the snow surface at Dome C
(Champollion et al., 2013)
Near IR camera
2 m high
imaged area ∼ 4 m2
p. 21 ludovic.brucker@nasa.gov L-band TB variations at Dome C and snow metamorphism
Motivations TB(x,y) TB(t) Surface state Conclusion
Surface-based monitoring of the snow surface at Dome C
(Champollion et al., 2013)
Near IR camera
2 m high
imaged area ∼ 4 m2
Hoar
p. 22 ludovic.brucker@nasa.gov L-band TB variations at Dome C and snow metamorphism
Motivations TB(x,y) TB(t) Surface state Conclusion
Surface-based monitoring of the snow surface at Dome C
(Champollion et al., 2013)
Near IR camera
2 m high
imaged area ∼ 4 m2
No hoar
p. 23 ludovic.brucker@nasa.gov L-band TB variations at Dome C and snow metamorphism
Motivations TB(x,y) TB(t) Surface state Conclusion
Surface-based monitoring of the snow surface at Dome C
(Champollion et al., 2013)
Near IR camera
2 m high
imaged area ∼ 4 m2
Hoar
p. 24 ludovic.brucker@nasa.gov L-band TB variations at Dome C and snow metamorphism
Motivations TB(x,y) TB(t) Surface state Conclusion
Aquarius and hoar crystal on the surface
No hoar Hoar
p. 25 ludovic.brucker@nasa.gov L-band TB variations at Dome C and snow metamorphism
Motivations TB(x,y) TB(t) Surface state Conclusion
Aquarius and hoar crystal on the surface
No hoar Hoar
L-band observations are sensitive to surface snow properties
p. 26 ludovic.brucker@nasa.gov L-band TB variations at Dome C and snow metamorphism
Motivations TB(x,y) TB(t) Surface state Conclusion
A simple calculation with Fresnel’s reﬂection coeﬃcients
at the air/snow interface
Radiometer 1 (θinc ∼ 29.2o)
Radiometer 2 (θinc ∼ 38.4o)
Radiometer 3 (θinc ∼ 46.3o)
A density variation of 75 kg m−3
could explain the largest change in TB H/V (in Dec. 2011)
p. 27 ludovic.brucker@nasa.gov L-band TB variations at Dome C and snow metamorphism
Motivations TB(x,y) TB(t) Surface state Conclusion
Conclusion
Aquarius radiometers . have an excellent sensitivity (0.2 K)
. are thus appealing to study the ice sheets
TB variability at H polarization . is larger than at V polarization
. increases as θinc increases
. is larger than the sensors’ sensitivity
L-band radiation . has a deep penetration
. but is sensitive to surface snow properties
Hoar crystals on the surface may inﬂuence cal/val experiments
Brucker et al., 2014: Eﬀect of Snow Surface Metamorphism on Aquarius L-Band
Radiometer Observations at Dome C, Antarctica. IEEE TGRS 52(11): 7408-7417,
doi:10.1109/TGRS.2014.2312102.
p. 28 ludovic.brucker@nasa.gov L-band TB variations at Dome C and snow metamorphism
Motivations TB(x,y) TB(t) Surface state Conclusion
Dome C
Wind direction
Hoar crystals present Hoar crystals disappear
(Champollion et al., 2013)
See also: Gallet et al. (2014), The growth of sublimation crystals and surface hoar on
the Antarctic plateau, The Cryosphere.
p. 29 ludovic.brucker@nasa.gov L-band TB variations at Dome C and snow metamorphism


Aquarius Brightness Temperature Variations at Dome C and Snow Metamorphism at the Surface

The Antarctic Plateau is a promising site to monitor microwave radiometers' drift, and to inter-calibrate microwave radiometers, especially 1.4 GigaHertz (L-band) radiometers on board the Soil Moisture and Ocean Salinity (SMOS), and AquariusSAC-D missions. The Plateau is a thick ice cover, thermally stable in depth, with large dimensions, and relatively low heterogeneities. In addition, its high latitude location in the Southern Hemisphere enables frequent observations by polar-orbiting satellites, and no contaminations by radio frequency interference. At Dome C (75S, 123E), on the Antarctic Plateau, the substantial amount of in-situ snow measurements available allows us to interpret variations in space-borne microwave brightness temperature (TB) (e.g. Macelloni et al., 2007, 2013, Brucker et al., 2011, Champollion et al., 2013). However, to analyze the observations from the Aquarius radiometers, whose sensitivity is 0.15 K, the stability of the snow layers near the surface that are most susceptible to rapidly change needs to be precisely assessed. This study focuses on the spatial and temporal variations of the Aquarius TB over the Antarctic Plateau, and at Dome C in particular, to highlight the impact of snow surface metamorphism on the TB observations at L-band

Dinnat, Emmanuel

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Aquarius Brightness Temperature Variations at Dome C and Snow Metamorphism at the Surface

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