Among various palaeoclimatic analyses of the Late-Holocene, assessing the cave ice growth rate offers valuable insights into past environmental conditions. Dobšiná Ice Cave (DIC; Carpathians, Slovakia) is an impressive ice cave, which hosts one of the most extensive subterranean perennial ice block. Thirteen organic macroremains were collected from a clearly layered ice section ca. 12 m thick. 14C dating of the samples enabled the construction of the precise age-depth model which revealed the ice growth rate. The obtained data proved that it was high during the Dark Ages (1.29 cm/year), significantly lower during the Medieval Climate Anomaly (0.58 cm/year), again high during the Little Ice Age (1.2 cm/year), and then decreased again (0.95 cm/year) during the Anthropogenic Recent Warmth. Among the collected organic macroremains, 10 were bats remains belonging to the species Myotis mystacinus, M. brandtii and Eptesicus nilssonii, which recently hibernate in the cold conditions of the cave. They group into two age clusters, which indicates higher bats mortality during colder periods, that is, the Dark Ages and Little Ice Age. This is consistent with episodes of faster ice growth in DIC. The continuous ice growth distinguishes DIC from several Alpine caves, where episodes of ice melting have been documented during the Medieval Climate Anomaly. This may result from local site-specific processes or geographically differentiated climatic conditions over Central Europe during the period under consideration.
BartošKPukanskáKKseňak, et al. (2023) Cross-polarized SfM photogrammetry for the spatial reconstruction of challenging surfaces, the case study of Dobšiná Ice Cave (Slovakia). Remote Sensing15: 4481.
2.
BellaP (2007) Morphology of ice surface in The Dobsina Ice Cave. In: 2nd International workshop on ice caves. Proceedings (ed ZelinkaJ), Slovak Caves Administration, Liptovský Mikuláš, pp.15–23.
BellaPBraucherRHolecJ, et al. (2014) Datovanie pochowania alochtónnych fluviálnych sedimentov v hornej časti Dobšinskej ľadovej jaskyne (IV. Vývojová úroveň systému Stratenej jaskyne) pomocou kozmogénnych nuklidov [in English: Cosmogenic nuclide dating of the burial of allochthonous fluvial sediments in the upper part of the Dobšinská Ice Cave (IVth evolution level of the Stratenská cave system), Slovakia]. Acta Carsologica Slovaca52(2): 101–110.
5.
BellaPTulisJZelinkaJ, et al. (2020) Dobšiná Ice Cave (Slovakia, central Europe) and its unique underground glacier originated in the mid-mountain position of the moderate climate zone. Aragonit25(1): 4–16.
BlantMMorettiMTinnerW (2010) Effect of climatic and palaeoenvironmental changes on the occurrence of Holocene bats in the Swiss alps. Holocene20: 711–721.
8.
Bronk RamseyCAdolphiFAustinW, et al. (2024) Development of the IntCal database. Radiocarbon66(6): 1852–1868.
9.
BüntgenUKynclTGinzlerC, et al. (2013) Filling the Eastern European gap in millennium-long temperature reconstructions. Proceedings of the National Academy of Sciences of the United States of America110(5): 1773–1778.
10.
BüntgenUTegelWNicolussiK, et al. (2011) 2500 years of European climate variability and human susceptibility. Science331: 578–582.
11.
BüntgenUUrbanOKrusicPJ, et al. (2021) Recent European drought extremes beyond common era background variability. Nature Geoscience14: 190–196.
12.
CitterioMTurriSPerșoiuA, et al. (2005) Radiocarbon ages from two ice caves in the Italian Alps and the Romanian Carpathians and their significance. In: Mavlyudov BR (ed.) Glacier Caves and Glacial Karst in High Mountains and Polar Regions. Moscow: Institute of Geography of the Russian Academy of Sciences, pp.87–92.
13.
ClausenHBVranaKHansenSB, et al. (2007) Continental ice body in Dobšiná Ice Cave (Slovakia) – part. II. – Results of chemical and isotopic study. In: 2nd International Workshop on Ice Caves. Proceedings (ed JZelinka), Liptovský Mikuláš, Slovakia, 8–12 May 2006, pp.29–37.
14.
ColucciRRGuglielminM (2019) Climate change and rapid ice melt: Suggestions from abrupt permafrost degradation and ice melting in an alpine ice cave. Progress in Physical Geography Earth and Environment43: 561–573.
15.
CzernikJGoslarT (2001) Preparation of graphite targets in the Gliwice radiocarbon laboratory for AMS 14C dating. Radiocarbon43: 283–291.
16.
DickfossPVBetancourtJIThompsonLG, et al. (1997) History of ice at Candelaria Ice Cave, New Mexico. New Mexico Bureau of Mines & Mineral Resources, Bulletin156: 91–112.
17.
DodelinB (2002) Identification des Chiroptères de France à partir de restes osseux. Fédération Française de Spéléologie, La Ravoire: Gap ed, p.48.
FairchildIJBakerA (2012) Speleothem Science: From Process to Past Environments. Oxford: John Wiley and Sons.
20.
FeurdeanAGalkaMKuskeE, et al. (2015) Last Millennium hydro-climate variability in Central–Eastern Europe (Northern Carpathians, Romania). Holocene25(7): 1179–1192.
21.
FeurdeanAPerșoiuAPazdurA, et al. (2011) Evaluating the palaeoecological potential of pollen recovered from ice in caves: A case study from Scărișoara Ice Cave, Romania. Review of Palaeobotany and Palynology165: 1–10.
22.
FleischerTGampeJScheuerleinA, et al. (2017) Rare catastrophic events drive population dynamics in a bat species with negligible senescence. Scientific Reports7: 7370.
23.
FordDWilliamsP (2007) Cave interior deposits. In: FordDWilliamsP (eds) Karst Hydrogeology and Geomorphology. Chichester: John Wiley & Sons Ltd, pp.271–320.
24.
FórizsIKernZSzántóZ, et al. (2004) Environmental isotope study on perennial ice in the Focul Viu Ice Cave, Bihor Mountains, Romania. Theoretical and Applied Karstology17: 61–69.
25.
GašinecJPukanskáKBartošK (2020) Geodetical measurements of ice surface changes in the Dobšiná Ice Cave. Abstracts of the 9th International Workshop on Ice Caves (IWIC-IX). Aragonit25(1): 40–41.
26.
GeantăATanţăuITămaşT, et al. (2012) Palaeoenvironmental information from the palynology of an 800 year old bat guano deposit from Măgurici Cave, NW Transylvania (Romania). Review of Palaeobotany and Palynology174: 57–66.
27.
GoslarTCzernikJGoslarE (2004) Low-energy 14C AMS in Poznań Radiocarbon Laboratory, Poland. Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms223–224: 5–11.
28.
GradzińskiMHercmanHPereswiet-SoltanA, et al. (2016) Radiocarbon dating of fossil bats from Dobšina Ice Cave (Slovakia) and potential palaeoclimatic implications. Annales Societatis Geologorum Poloniae86: 341–350.
29.
HalašJ (1986) Tepelná bilancia Dobšinskej ľadovej jaskyne. Kandidátska dizertačná práca, Vysoká škola technická, Banícka fakulta, Košice, Slovak Caves Administration Archive, Liptovský Mikuláš, p.119.
30.
HanákVAnděraMUhrinM, et al. (2010) Bats of the Czech Republic and Slovakia: Distributional status of individual species. In: HoráčekIUhrinM (eds) A Tribute To Bats. Kostelec nad Černými lesy: Lesnická práce, pp.143–254.
31.
HercmanHGąsiorowskiMGradzińskiM, et al. (2010) The first dating of cave ice from the Tatra Mountains, Poland and its implication to palaeoclimate reconstructions. Geochronometria36: 31–38.
32.
HercmanHPawlakJ (2012) MOD-AGE: An age-depth model construction algorithm. Quaternary Geochronology12: 1–10.
33.
HolmlundPOnacBPHanssonM, et al. (2005) Assessing the palaeoclimate potential of cave glaciers: The example of the Sčarișoara Ice Cave (Romania). Geografiska Annaler: Series A, Physical Geography87(1): 193–201.
34.
HoráčekI (1976) Review of Quaternary bats in Czechoslovakia. Lynx18: 35–58.
35.
HristovNIAllenLCChadwellBA (2013) New advances in the study of group behavior in bats. In: AdamsRAPedersenSC (eds) Bat Evolution, Ecology, and Conservation. New York: Springer, pp.271–291.
36.
HughesMKDiazHF (1994) Was there a ‘medieval warm period’, and if so, where and when?.Climatic Change26: 109–142.
JaworowskiZ (1966) Temporal and geographical distribution of radium D (lead-210). Nature212: 886–889.
39.
JelonekM (2024) Rekonstrukcja paleośrodowiska na podstawie analizy pyłkowej lodu jaskiniowego – studium na przykładzie Dobszyńskiej Jaskini Lodowej (Słowacja). PhD Thesis, Jagiellonian University, Poland.
40.
KaňuchPDankoŠCeluchM, et al. (2006) Relating bat species presence to habitat features in natural forests of Slovakia (Central Europe). Mammalian Biology73: 147–155.
KernZFórizsIHorvatinčićN, et al. (2010) Glaciochemical investigations on the subterranean ice deposit of Vukušić Ice Cave, Velebit Mountain, Croatia. Cryosphere Discussions4(3): 1561–1591.
43.
KernZFórizsINagyB, et al. (2004) Late-Holocene environmental changes recorded at Gheţarul de la Focul Viu, Bihor Mountains, Romania. Theoretical and Applied Karstology17: 51–60.
44.
KernZFórizsIPavuzaR, et al. (2011a) Isotope hydrological studies of the perennial ice deposit of Saarhalle, Mammuthöhle, Dachstein Mts, Austria. Cryosphere5: 291–298.
45.
KernZMolnárMSvingorÉ, et al. (2009) High-resolution, well-preserved tritium record in the ice of Bortig Ice Cave, Bihor Mountains, Romania. Holocene19(5): 729–736.
46.
KernZPerșoiuA (2013) Cave ice – The imminent loss of untapped mid-latitude cryospheric palaeoenvironmental archives. Quaternary Science Reviews67: 1–7.
47.
KernZSzélesEHorvatinčićN, et al. (2011b) Glaciochemical investigations of the ice deposit of Vukušić Ice Cave, Velebit Mountain, Croatia. Cryosphere5(2): 485–494.
48.
KołaczekPKarpińska-KołaczekMMarciszK, et al. (2016) Palaeohydrology and the human impact on one of the largest raised bogs complex in the Western Carpathians (Central Europe) during the last two millennia. Holocene28: 595–608.
49.
KorzystkaMPiaseckiJSawińskiT, et al. (2011) Climatic system of the Dobsinska Ice cave. In: 6th Congress International Show Caves Association Proceedings (eds PBellaPGazik), Slovak Caves Administration, Liptovsky Mikulas, pp.89–97.
50.
KressAHangartnerSBugmannH, et al. (2014) Swiss tree rings reveal warm and wet summers during medieval times. Geophysical Research Letters41: 1732–1737.
51.
KryštufekB (2004) Chiroptera (bats). In: GunnJ (ed.) Encyclopedia of Caves and Karst Science. New York: Fitzroy Dearborn, pp.225–227.
52.
KudlaM (2020) The history overview of the Dobšiná Ice Cave. Aragonit25(1): 17–22.
53.
LauriolBClarkID (1993) An approach to determine the origin and age of massive ice blockages in two Arctic caves. Permafrost and Periglacial Processes4: 77–85.
54.
LazaridisGStamoulisKDoraD, et al. (2023) Brief communication: tritium concentration and age of firn accumulation in an ice cave of Mount Olympus (Greece). Cryosphere17: 883–887.
55.
LeundaMGonzález-SampérizPGil-RomeraG, et al. (2019) Ice cave reveals environmental forcing of long-term Pyrenean tree line dynamics. Journal of Ecology107: 814–828.
56.
LožekVGaál Ľ, HolecP, et al. (1989) Stratigraphy and Quaternary fauna of cave Peskõ in the Rimava Basin. Slovenský Kras27: 29–56.
57.
LuetscherM (2005) Processes in Ice Caves and their Significance for Paleoenvironmental Reconstructions. La Chaux-de-Fonds: Swiss Institute for Speleology and Karst Studies.
58.
LuetscherM (2013) Glacial processes in caves. In: SchroederJFrumkinA (eds) Treatise on Geomorphology, Vol. 6. Karst Geomorphology. San Diego, Ca: Academic Press, pp.258–266.
59.
LuetscherMBoliusDSchwikowskiM, et al. (2007) Comparison of techniques for dating of subsurface ice from Monlesi Ice Cave, Switzerland. Journal of Glaciology53: 374–384.
60.
MaggiVTurriSBiniA, et al. (2008) 2500 year of history in Focul Viu Ice Cave. In: Proceedings of the 3rd International Workshop on Ice Caves (eds OKadebskayaBRMavlyudovMPyatunin), Kungur, pp.11–15.
61.
MannMEZhangZRutherfordS, et al. (2009) Global signatures and dynamical origins of the Little Ice Age and medieval climate anomaly. Science326: 1256–1260.
62.
MasingMLutsarL (2007) Hibernation temperatures in seven species of sedentary bats (Chiroptera) in Northeastern Europe. Acta Zoologica Lituanica17(1): 47–55.
63.
MenuHPopelardJB (1987) Utilisation des caracteres dentaires pour la determination des Vespertilionines de l’ Ouest Européen. Le Rhinopophe4: 1–88.
64.
MilovskýRLiHCOrvošováM, et al. (2019) 2600-ročný záznam atmosférickej cirkulácie a klímy z Dobšinskej Ľadovej Jaskyne. In: Konferencie, sympóziá, semináre – Geochémia 2019. Zborník vedeckých príspevkov z konferencie (eds ĽJurkovičISlaninkaJKordík), Bratislava, pp.137–138.
65.
MilovskýRŠurkaJOrvošováM, et al. (2020) 2300 years of ice. Abstracts of 9th International Workshop on Ice Caves (IWIC-IX). Aragonit25(1): 49.
66.
MunroeJSO’KeefeSSGorinAL (2018) Chronology, stable isotopes, and glaciochemistry of perennial ice in Strickler Cavern, Idaho, USA. Geological Society of America Bulletin130: 175–192.
67.
NeukomRSteigerNGómez-NavarroJJ, et al. (2019) No evidence for globally coherent warm and cold periods over the preindustrial Common Era. Nature571: 550–554.
68.
ObuchJ (1994) Types of the bat assemblages (Chiroptera) recorded in Slovakia. Folia Zoologica43: 393–410.
69.
ObuchJ (2012) Assemblages of bats in deposits of the Dobšinská Ice Cave, Slovenský raj National Park, Slovakia. Vespertilio16: 205–210.
70.
O’SheaTJCryanPMHaymanDT, et al. (2016) Multiple mortality events in bats: A global review. Mammal Review46(3): 175–190.
71.
PanaitADiaconuAGalkaM, et al. (2017) Hydrological conditions and carbon accumulation rates reconstructed from a mountain raised bog in the Carpathians: A multi-proxy approach. CATENA152: 57–68.
72.
PaštekaRZahorecPŠulekI, et al. (2024) Preliminary estimate of current ice thickness in the Dobšiná ice cave by means of geophysical and geodetic methods. Contributions to Geophysics and Geodesy54(4): 389–406.
73.
PazdurAGoslarTPawlytaM, et al. (1999) Variations of isotopic composition of carbon in the karst environment from Southern Poland, present and past. Radiocarbon41: 81–97.
PerșoiuABellaPRollM, et al. (2022) New radiocarbon data completing the spatial distribution of ice ages in the Dobšiná Ice Cave: Implications for the ice movement. Abstracts of 9th International Workshop on Ice Caves (IWIC-IX). Aragonit27(1): 35.
PerșoiuAOnacBPWynnJG, et al. (2017) Holocene winter climate variability in Central and Eastern Europe. Scientific Reports7: 1196.
79.
PerșoiuAPazdurA (2011) Ice genesis and its long-term mass balance and dynamics in Scărișoara Ice Cave, Romania. Cryosphere5: 45–53.
80.
PfeifferJRutzingerMSpötlC (2023) Terrestrial laser scanning for 3D mapping of an alpine ice cave. Photogrammetric Record38(181): 6–21.
81.
PflitschAPiaseckiJSawińskiT, et al. (2007) Development and degradation of ice crystals sediment in Dobsinska Ice Cave (Slovakia). In: 2nd International Workshop on Ice Caves. Proceedings (ed J Zelinka), Slovak Caves Administration, Liptovský Mikuláš, pp.38–49.
82.
PopovVIvanovaTI (2002) Comparative craniometrical analysis and distributional patterns of medium-sized horseshoe bats (Chiroptera: Rhinolophidae) in Bulgaria. Foolia Zoologica51(3): 187–200.
83.
PukanskáKBartošKGašinecJ, et al. (2024) Methodological approaches to survey complex ice cave environments - the case of Dobšiná (Slovakia). Frontiers in Environmental Science12: 1484169.
84.
RachlewiczGSzczucińskiW (2004) Seasonal and decadal ice mass balance changes in the ice cave Jaskinia Lodowa w Ciemniaku, the Tatra Mountains, Poland. Theoretical and Applied Karstology17: 11–18.
85.
RacineTMFReimerPJSpötlC (2022a) Multi-centennial mass balance of perennial ice deposits in alpine caves mirrors the evolution of glaciers during the late Holocene. Scientific Reports12: 11374.
86.
RacineTMFSpötlCReimerPJ, et al. (2022b) Radiocarbon constraints on periods of positive cave ice mass balance during the last millennium, Julian alps (NW Slovenia). Radiocarbon64(2): 333–356.
87.
ReimerPJAustinWENBardE, et al. (2020) The IntCal20 Northern Hemisphere radiocarbon age calibration curve (0–55 cal kBP). Radiocarbon62(4): 725–757.
88.
RuediM (2020) Lesser mouse-eared bat Myotis blythii (Tomes, 1857). In: HackländerKZachosFE (eds) Handbook of the Mammals of Europe. Cham: Springer Nature Switzerland, pp.1–24.
89.
RygielskiWSiarzewskiWWieliczkoP (1995) Variability of the ice deposits in ice cave on Mount Ciemniak in the West Tatra mountains. Questiones Geographicae17: 55–64.
90.
SanchoCBelmonteALópez-MartínezJ, et al. (2012) Potencial paleoclimático de la cueva helada A294 (Macizo de Cotiella, Pirineos, Huesca). Geogaceta52: 101–104.
91.
SanchoCBelmonteÁBartoloméM, et al. (2018) Middle-to-Late-Holocene palaeoenvironmental reconstruction from the A294 ice-cave record (Central Pyrenees, northern Spain). Earth and Planetary Science Letters484: 135–144.
92.
SawińskiT (2012) Dynamika ruchu powietrza w jaskiniach o różnych cechach środowiska. PhD Thesis, Wroclaw University, Poland.
93.
SchmeidlHKralF (1969) Zur pollenanalytischen Altersbestimmung der Eisbildungen In der Schellenberger Eishöhle und in der Dachstein-Rieseneishöhle. In: Jahrbuch des Vereins zum Schutze der Alpenpflanzen und Tiere. München: Band 34, pp. 67–84.
94.
ŞerbanMBlagaLBlagaL, et al. (1967) Contribuţii la stratigrafia depozitelor de gheaţă din Gheţarul de la Scărișoara. Lucr. Inst. Speol. “E. Racoviţă”VI: 107–140.
95.
SpötlCFohlmeisterJReimerP, et al. (2024) First insights into the age of the giant ice deposits in the Eisriesenwelt cave (Austria). Scientific Reports14: 11001.
96.
SpötlCReimerPJLuetscherM (2014) Long-term mass balance of perennial firn and ice in an Alpine cave (Austria): Constraints from radiocarbon-dated wood fragments. Holocene24(2): 165–175.
97.
StoffelMLuetscherMBollschweilerM, et al. (2009) Evidence of NAO control on subsurface ice accumulation in a 1200 yr. old cave-ice sequence, St. Livres ice cave, Switzerland. Quaternary Research72: 16–26.
98.
StrugK (2011) Klimatyczne uwarunkowania rozwoju zjawisk lodowych w jaskiniach o odmiennych cechach środowiska. Wrocław: Instytut Geografii i Rozwoju Regionalnego.
99.
SutcliffeAJ (1976) Cave palaeontology. In: FordDCullingfordCHD (eds) The Science of Spelelogy. London: Academic Press, pp.495–520.
100.
TulisJNovotnýL (1989) Jaskynný systém Stratenskej jaskyne [The cave system of Stratenská jaskyňa Cave]. Osveta, p.464 (in Slovak).
101.
TulisJNovotnýL (1995) Čiastková správa o morfometrických parametroch v zaľadnených častiach Dobšinskej ľadovej jaskyne. Ochrana ľadových jaskýň, Zborník referátov, Liptovský Mikuláš, pp.25–28.
102.
TulisJNovotnýL (2003) Zmeny zaľadnenia v Dobšinskej ľadovej jaskyni [Glaciation changes in the Dobšiná Ice Cave]. Aragonit8: 7–9.
103.
TulisJNovotnýL (2007) Dobšinská ľadová jaskyňa Ice Cave – 136 years from its discovery. In: 2nd International Workshop on Ice Caves. Proceedings (ed JZelinka), Liptovský Mikuláš, Slovakia, 8–12 May 2006, pp.8–14.
104.
van der KnaapWOLamentowiczMvan LeeuwenJFN, et al. (2011) A multi-proxy, high-resolution record of peatland development and its drivers during the last millennium from the subalpine Swiss Alps. Quaternary Science Reviews30: 3467–3480.
105.
VišňovskáZCibula HájkováA, et al. (2017) Pozoruhodný chiropterologický nález po objavení nových priestorov v jaskyni Duča (Slovenský raj) [Noteworthy chiropterological finding after the discovery of new spaces in the Duča Cave (Slovak Paradise)]. Aragonit22(2): 81.
106.
VišňovskáZUhrinMHájkováA (2020) The structure and long-term dynamics of bat assemblage hibernating in the Dobšiná Ice Cave. Slovenský Kras, Acta Carsologica Slovaca58(1): 39–67.
107.
WołoszynBW (1970) The Holocene bat fauna (Chiroptera) from the caves of the Tatra Mountains. Folia Quaternaria35: 1–52.
108.
ZelinkaJ (2012) Program záchrany národnej prírodnej pamiatky Dobšiná ľadová jaskyňa. Správa slovenských jaskýň.
