Response of Sandy Lake in Schirmacher Oasis, East Antarctica to the glacial-interglacial climate shift

Freshwater lakes in Antarctica fluctuate from ice-free state (during austral summer) to ice-cover state (during austral winter). Hence the lakes respond instantly to the seasonal climate of the region. The Antarctic seasons respond sharply to the glacial and interglacial climates and these signature...

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Bibliographic Details
Published in:Journal of paleolimnology 2017-10, Vol.58 (3), p.275-289
Main Authors: Mahesh, Badanal Siddaiah, Warrier, Anish Kumar, Mohan, Rahul, Tiwari, Manish, Roy, Rajdeep, Asthana, Rajesh, Ravindra, Rasik
Format: Article
Language:English
Subjects:
Algae
Allochthonous deposits
Aquatic plants
Biomass
Carbon-nitrogen ratio
Climate
Climate Change
Deglaciation
Denitrification
Earth and Environmental Science
Earth Sciences
Foundry sands
Freshwater & Marine Ecology
Freshwater lakes
Geology
Holocene
Ice
Ice cover
Inland water environment
Interglacial periods
Lake deposits
Lake ice
Lake sediments
Lakes
Meltwater
Oases
Organic matter
Original Paper
Oxygen enrichment
Paleontology
Physical Geography
Sand
Seasons
Sediment
Sedimentology
Sediments
Temperature effects
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Summary:Freshwater lakes in Antarctica fluctuate from ice-free state (during austral summer) to ice-cover state (during austral winter). Hence the lakes respond instantly to the seasonal climate of the region. The Antarctic seasons respond sharply to the glacial and interglacial climates and these signatures are archived in the lake sediments. A sediment core from Sandy Lake, a periglacial lake located in Schirmacher Oasis of East Antarctica records distinct changes in grain-size, C, N, C/N ratios (atomic), δ 13 C OM and δ 15 N OM contents during the last 36 ky. The contents of the sedimentary organic matter (OM) proxies (C org  ~ 0.3 ± 0.2%, C/N ratios ~9 ± 5 and δ 13 C OM  ~−18 ± 6‰) indicate that the OM in this lake sediment is a product of mixing of terrestrial and lacustrine biomass. Distinctly lower contents of C org (~0.2%) and sand (~50%), low C/N ratios (~8) and depleted δ 13 C OM (~−20‰) during the Last Glacial Maximum (LGM: 32–17 ky BP based on Vostok Temperatures) suggest greater internal (autochthonous) provenance of organic matter and limited terrestrial (allochthonous) inputs probably due to long and intense winters in the Antarctic. Such intense winters might have resulted the lake surface to be ice-covered for most part of the year when the temperatures remained consistently colder than the Holocene temperatures. The denitrification within the lake evident by enriched δ 15 N OM (>10‰) during Antarctic LGM might have resulted from oxygen-limitation within the lake environment caused by insulated lake surface. The gradual increases in δ 13 C OM , C/N and sand content starting at ~11 ky BP and attaining high values (~−11‰, ~10 and ~80% respectively) at ~6 ky BP together suggest a subtle change in the balance of sources of organic matter between algal and macrophyte/bryophyte nearly 8–9 ky later to the beginning of the deglaciation. Thus the seasonal opening-up of the Sandy Lake similar to the modern pattern started with the establishment of the optimum temperature conditions (i.e., 0 °C anomaly) in the Antarctic, prior to which the lake environment might have remained mostly insulated or closed.
ISSN:0921-2728
1573-0417
DOI:10.1007/s10933-017-9977-8