FIRST ALPINE EVIDENCE OF IN SITU COARSE CRYOGENIC CAVE CARBONATES (CCCCOARSE)

被引:15
作者
Colucci, Renato R. [1 ,2 ]
Luetscher, Marc [3 ,4 ]
Forte, Emanuele [5 ]
Guglielmin, Mauro [6 ]
Lenaz, Davide [5 ]
Princivalle, Francesco [5 ]
Vita, Francesca [7 ]
机构
[1] ISMAR CNR, Dept Earth Syst Sci & Environm Technol, Area Sci Pk Basovizza Q2 Bldg,SS 14 Km 163-5, I-34149 Trieste, Italy
[2] Soc Alpina Giulie CAI, Commiss Grotte E Boegan, Trieste, Italy
[3] Austrian Acad Sci, Interdisciplinary Mt Res, Vienna, Austria
[4] Univ Innsbruck, Inst Geol, Innrain 52, A-6020 Innsbruck, Austria
[5] Univ Trieste, Dept Math & Geosci, Via Weiss 1, I-34128 Trieste, Italy
[6] Insubria Univ, Dept Theoret & Appl Sci, Via JH Dunant, I-21100 Varese, Italy
[7] Univ Trieste, Dept Life Sci, Via Weiss 2, I-34128 Trieste, Italy
来源
GEOGRAFIA FISICA E DINAMICA QUATERNARIA | 2017年 / 40卷 / 01期
关键词
cryogenic cave carbonates; paleoclimate; climate change; ice caves; Alps; O ISOTOPE COMPOSITION; ICE CAVE; JULIAN ALPS; GLACIERS; PERMAFROST; MOUNTAINS; EVOLUTION; INSIGHTS; DEPOSITS; CALCITE;
D O I
10.4461/GFDQ2017.40.5
中图分类号
P9 [自然地理学];
学科分类号
0705 ; 070501 ;
摘要
A layer of coarse cryogenic cave carbonate (CCCcoarse) is documented within a subsurface ice outcrop (in-situ) in a cave of the Julian Alps (southeastern Alps). This original finding, representing the first alpine evidence of in-situ CCCcoarse and the first occurrence from the southern side of the Alps, provides a unique opportunity to better understand the processes associated with the formation of CCCcoarse with respect to the cave ice mass balance. Here, we discuss first considerations on the shape and characteristics of CCCcoarse samples and their potential for palaeoclimate reconstructions in the southern Alps. In the light of accelerated climate change, we emphasize the need for scientific actions to exploit the available physical, chemical, isotopic and biological records from still untapped and fragile cryospheric archives such as ice caves.
引用
收藏
页码:53 / 59
页数:7
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