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1. Comparison of Ventilated and Unventilated Air Temperature Measurements in Inland Dronning Maud Land on the East Antarctic Plateau

   https://doi.org/10.1175/JTECH-D-21-0107.1  

   Morino, Shohei ; Kurita, Noayuki ; Hirasawa, Noahiko ; Motoyama, Hideaki ; Sugiura, Konosuke ; Lazzara, Matthew ; Mikolajczyk, David ; Welhouse, Lee ; Keller, Linda ; Weidner, George ( December 2021 , Journal of Atmospheric and Oceanic Technology)

   Surface temperature measurements with naturally ventilated (NV) sensors over the Antarctic Plateau are largely subject to systematic errors caused by solar radiative heating. Here we examined the radiative heating error in Dronning Maud Land on the East Antarctic Plateau using both the newly installed automatic weather stations (AWSs) at NDF and Relay Station and the existing AWSs at Relay Station and Dome Fuji. Two types of NV shields were used in these AWSs: a multiplate radiation shield and a simple cylinder-shaped shield. In austral summer, the temperature bias between the force-ventilated (FV) sensor and the NV sensor never reached zero because of continuous sunlight. The hourly mean temperature errors reached up to 8°C at noon on a sunny day with weak wind conditions. The errors increased linearly with increasing reflected shortwave radiation and decreased nonlinearly with increasing wind speed. These features were observed in both the multiplate and the cylinder-shaped shields. The magnitude of the errors of the multiplate shield was much larger than that of the cylinder-shaped shield. To quantify the radiative errors, we applied an existing correction model based on the regression approach and successfully reduced the errors by more than 70% after the correction. This indicates that we can use the corrected temperature data instead of quality controlled data, which removed warm bias during weak winds in inland Dronning Maud Land. 

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2. Antarctic temperature and CO 2 : near-synchrony yet variable phasing during the last deglaciation

   https://doi.org/10.5194/cp-15-913-2019  

   Chowdhry Beeman, Jai ; Gest, Léa ; Parrenin, Frédéric ; Raynaud, Dominique ; Fudge, Tyler J. ; Buizert, Christo ; Brook, Edward J. ( January 2019 , Climate of the Past)

   Abstract. The last deglaciation, which occurred from 18 000 to 11 000 years ago,is the most recent large natural climatic variation of global extent. Withaccurately dated paleoclimate records, we can investigate the timings ofrelated variables in the climate system during this major transition. Here,we use an accurate relative chronology to compare temperature proxy data andglobal atmospheric CO2 as recorded in Antarctic ice cores. In addition tofive regional records, we compare a δ18O stack, representingAntarctic climate variations with the high-resolution robustly dated WAISDivide CO2 record (West Antarctic Ice Sheet). We assess the CO2 and Antarctic temperature phaserelationship using a stochastic method to accurately identify the probabletimings of changes in their trends. Four coherent changes are identified forthe two series, and synchrony between CO2 and temperature is within the95 % uncertainty range for all of the changes except the end of glacial termination 1 (T1). During the onset of the last deglaciation at 18 ka and the deglaciationend at 11.5 ka, Antarctic temperature most likely led CO2 by several centuries (by 570 years, within a range of 127 to 751 years, 68 %probability, at the T1 onset; and by 532 years, within a range of 337 to 629years, 68 % probability, at the deglaciation end). At 14.4 ka, the onsetof the Antarctic Cold Reversal (ACR) period, our results do not show a clearlead or lag (Antarctic temperature leads by 50 years, within a range of−137 to 376 years, 68 % probability). The same is true at the end of the ACR(CO2 leads by 65 years, within a range of 211 to 117 years, 68 %probability). However, the timings of changes in trends for the individualproxy records show variations from the stack, indicating regional differencesin the pattern of temperature change, particularly in the WAIS Divide recordat the onset of the deglaciation; the Dome Fuji record at the deglaciationend; and the EDML record after 16 ka (EPICA Dronning Maud Land, where EPICA is the European Project for Ice Coring in Antarctica). In addition, two changes – one at 16 ka in the CO2 record and one after the ACR onset in three of theisotopic temperature records – do not have high-probability counterparts in the other record. The likely-variable phasing we identify testify to thecomplex nature of the mechanisms driving the carbon cycle and Antarctictemperature during the deglaciation. 

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3. The AntAWS dataset: a compilation of Antarctic automatic weather station observations

   https://doi.org/10.5194/essd-15-411-2023  

   Wang, Yetang ; Zhang, Xueying ; Ning, Wentao ; Lazzara, Matthew A. ; Ding, Minghu ; Reijmer, Carleen H. ; Smeets, Paul C. ; Grigioni, Paolo ; Heil, Petra ; Thomas, Elizabeth R. ; et al ( January 2023 , Earth System Science Data)

   Abstract. A new meteorological dataset derived from records of Antarctic automatic weather stations (here called the AntAWS dataset) at 3 h, daily and monthly resolutions including quality control information is presented here. This dataset integrates the measurements ofair temperature, air pressure, relative humidity, and wind speed anddirection from 267 Antarctic AWSs obtained from 1980 to 2021. The AWS spatial distribution remains heterogeneous, with the majority of instrumentslocated in near-coastal areas and only a few inland on the East Antarctic Plateau. Among these 267 AWSs, 63 have been operating for more than 20 years and 27 of them in excess of more than 30 years. Of the fivemeteorological parameters, the measurements of air temperature have the bestcontinuity and the highest data integrity. The overarching aim of thiscomprehensive compilation of AWS observations is to make these data easilyand widely accessible for efficient use in local, regional and continentalstudies; it may be accessed at https://doi.org/10.48567/key7-ch19 (Wang et al., 2022). This dataset isinvaluable for improved characterization of the surface climatology acrossthe Antarctic continent, to improve our understanding of Antarctic surfacesnow–atmosphere interactions including precipitation events associated with atmospheric rivers and to evaluate regional climate models ormeteorological reanalysis products. 

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4. Age stratigraphy in the East Antarctic Ice Sheet inferred from radio-echo sounding horizons

   https://doi.org/https://doi.org/10.5194/essd-11-1069-2019  

   Winter, A. and ( July 2019 , Earth system science data)

   The East Antarctic Ice Sheet contains a wealth of information that can be extracted from its internal architecture such as distribution of age, past flow features, and surface and basal properties. Airborne radar surveys can sample this stratigraphic archive across broad areas. Here, we identify and trace key horizons across several radar surveys to obtain the stratigraphic information. We transfer the age–depth scales from ice cores to intersecting radar data. We then propagate these age scales across the ice sheet using the high fidelity continuity of the radar horizons. In Dronning Maud Land, including Dome Fuji, we mapped isochrones with ages of 38 and 74 ka. In the central region of East Antarctica around Dome Concordia, Vostok and Dome Argus, we use isochrone ages of 38, 48, 90 and 161 ka. Taking together both regions, we provide isochrone depths traced along a combined profile length of more than 40 000 km and discuss uncertainties of the obtained stratigraphy, as well as factors important to consider for further expansion. This data set is the most extensive distribution of internal horizons in East Antarctica to date. The isochrone depths presented in this study are available on PANGAEA (https://doi.org/10.1594/PANGAEA.895528; Winter et al., 2018). 

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5. The Seismic Structure of the Antarctic Upper Mantle

   https://doi.org/10.1144/M56-2020-18  

   Wiens, Douglas A. ; Shen, Weisen ; Lloyd, Andrew ( July 2021 , Geological Society, London, Memoirs)

   null (Ed.)

   Abstract The deployment of seismic stations and the development of ambient noise tomography and new analysis methods provide an opportunity for higher resolution imaging of Antarctica. Here we review recent seismic structure models and describe their implications for the dynamics and history of the Antarctic upper mantle. Results show that most of East Antarctica is underlain by continental lithosphere to depths of ∼ 200 km. The thickest lithosphere is found in a band 500-1000 km west of the Transantarctic Mountains, representing the continuation of cratonic lithosphere with Australian affinity beneath the ice. Dronning Maud Land and the Lambert Graben show much thinner lithosphere, consistent with Phanerozoic lithospheric disruption. The Transantarctic Mountains mark a sharp boundary between cratonic lithosphere and the warmer upper mantle of West Antarctica. In the Southern Transantarctic Mountains, cratonic lithosphere has been replaced by warm asthenosphere, giving rise to Cenozoic volcanism and an elevated mountainous region. The Marie Byrd Land volcanic dome is underlain by slow seismic velocities extending through the transition zone, consistent with a mantle plume. Slow velocity anomalies beneath the coast from the Amundsen Sea Embayment to the Antarctic Peninsula likely result from upwelling of warm asthenosphere during subduction of the Antarctic-Phoenix spreading center. 

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