Cryptotephra from Lipari Volcano in the eastern Gulf of Taranto (Italy) as a time marker for paleoclimatic studies

Menke, Valerie; Kutterolf, Steffen; Sievers, Carina; Schindlbeck, Julie; Schmiedl, Gerhard

doi:10.1017/qua.2018.2

Cited by 6 publications

(6 citation statements)

References 68 publications

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“…Within the Aeolian archipelago, distal ash layers associated with the more recent eruptive cycle (last 1500 yrs) of Lipari have been found subaerially: i) interbedded within the products of the Commenda eruption deposits of the La Fossa cone on Vulcano island (Keller, 1980;De Astis et al, 2013;Gurioli et al 2012;Di Traglia et al, 2013;Fusillo et al, 2015;Albert et al, 2017;Rosi et al, 2018), ii) at the base of the eruptive products of the present-day activity of Stromboli (Rosi et al, 2000(Rosi et al, , 2013. More distally, rhyolitic tephra and cryptotephra layers within the same timestratigraphic window have been found in the southern Tyrrhenian Sea (Paterne et al, 1988;Di Roberto et al, 2008;Albert et al, 2012Albert et al, , 2017, in the Gulf of Taranto (Di Donato et al, 2019), and in the Ionian Sea (Caron et al, 2012;Menke et al, 2018;Insinga et al 2020), in which they J o u r n a l P r e -p r o o f represent important regional marker horizons. Several of these studies provide independent dating ( 14 C, oxygen-isotope data, ecostratigraphy, sedimentation rates) for the rhyolitic tephra layers found within the respective cores that will be used here to cross-check distal correlations.…”

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confidence: 87%

“…Given the AD 1321-1349 date for the tephra , Caron et al (2012) attributed it to a generic MP eruption. Menke et al (2018) also identified a rhyolitic tephra layer which they attributed to MP based on 14 C age determinations and an age model based on the sedimentation rate in that area, while leaving open the possibility of a younger age (i.e. 13 th century).…”

Section: Proximal-medial-distal Correlations Of Lipari-sourced Rhyoli...mentioning

confidence: 99%

“…The new chrono-stratigraphic framework for the MP, FV, RR and LA eruptions, combined with lithological and textural characterization and geochemical analysis of the glass, have important implications for the use of the corresponding tephra layers as chronostratigraphic markers in the Aeolian Islands region and across the southern Mediterranean area. Lipari-sourced rhyolitic tephra and cryptotephra layers have been recognized subaerially on the Aeolian Islands (see Keller, 1980;Rosi et al, 2000;Lucchi et al, 2013d;Albert et al, 2017;Rosi et al, 2018) as well as in marine sediment sequences of the southern Tyrrhenian (Paterne et al, 1988;Di Roberto et al, 2008;Albert et al, 2012Albert et al, , 2017 and Northern Ionian (Caron et al, 2012;Menke et al, 2018;Di Donato et al, 2019;Insinga et al, 2020) seas. Based on their rhyolitic composition, aphyric texture and stratigraphic position above the widespread Vallone del Gabellotto marker bed, these distal tephra layers have been generally correlated to the MP eruption, which was considered that with the largest magnitude and dispersal.…”

Section: Proximal-medial-distal Correlations Of Lipari-sourced Rhyoli...mentioning

confidence: 99%

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Chrono-stratigraphy of the youngest (last 1500 years) rhyolitic eruptions of Lipari (Aeolian Islands, Southern Italy) and implications for distal tephra correlations

Pistolesi

Rosi

Malaguti

et al. 2021

Journal of Volcanology and Geothermal Research

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confidence: 87%

Section: Proximal-medial-distal Correlations Of Lipari-sourced Rhyoli...mentioning

confidence: 99%

Section: Proximal-medial-distal Correlations Of Lipari-sourced Rhyoli...mentioning

confidence: 99%

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Chrono-stratigraphy of the youngest (last 1500 years) rhyolitic eruptions of Lipari (Aeolian Islands, Southern Italy) and implications for distal tephra correlations

Pistolesi

Rosi

Malaguti

et al. 2021

Journal of Volcanology and Geothermal Research

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“…When only the 14 C dating points (second polynome age model) are taken into consideration, this cryptotephra has a deposition time between 81 and 113 years CE ± 120 years. The majority of the glass particles at 1596.5- and 1594-mm core depths have a clear Lipari composition ( 80 , 82 ) . The elemental compositions of the “Lipari” glass shards are equivalent to that of glass particles in cryptotephra “t6” of the core TEA-C6 from the western side of the Gulf of Taranto (fig.…”

Section: Methodsmentioning

confidence: 99%

Climate change, society, and pandemic disease in Roman Italy between 200 BCE and 600 CE

Zonneveld,

Harper,

Klügel

et al. 2024

Sci. Adv.

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Records of past societies confronted with natural climate change can illuminate social responses to environmental stress and environment-disease connections, especially when locally constrained high–temporal resolution paleoclimate reconstructions are available. We present a temperature and precipitation reconstruction for ~200 BCE to ~600 CE, from a southern Italian marine sedimentary archive—the first high-resolution (~3 years) climate record from the heartland of the Roman Empire, stretching from the so-called Roman Climate Optimum to the Late Antique Little Ice Age. We document phases of instability and cooling from ~100 CE onward but more notably after ~130 CE. Pronounced cold phases between ~160 to 180 CE, ~245 to 275 CE, and after ~530 CE associate with pandemic disease, suggesting that climate stress interacted with social and biological variables. The importance of environment-disease dynamics in past civilizations underscores the need to incorporate health in risk assessments of climate change.

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“…Barton et al, 2015;Bruins et al, 2019;Hirniak et al, 2020), as have stalagmites (Klaes et al, 2022). Here, we list further examples including benchmark methodological papers, regional reviews, and recent papers on long sedimentary sequences that collectively emphasize the growing importance of cryptotephrochronological research: Turney (1998), Hunt (1999b), Hall and Pilcher (2002), van den Bogaard and Schmincke (2002), Davies et al (2004), Gehrels et al (2008, Wastegård and Davies (2009), Swindles et al (2011, 2019, Lawson et al (2012), Matsu'ura et al (2012, Wastegård and Boygle (2012), , Riede andThastrup (2013), Smith et al (2013), Abbott et al (2018aAbbott et al ( , b, 2020a, Menke et al (2018), Wulf et al (2018), , Leicher et al (2019), Jones et al (2020), Freundt et al (2021, Jensen et al (2021), andKinder et al (2021).…”

Section: Development Of Cryptotephra Studies and The Advent Of The Mo...mentioning

confidence: 99%

Global tephra studies: role and importance of the international tephra research group “Commission on Tephrochronology” in its first 60 years

Lowe

Abbott

Suzuki

et al. 2022

Hist. Geo Space. Sci.

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Abstract. Tephrochronology is a correlational and age-equivalent dating method whereby practitioners characterize, map, and date tephra (or volcanic ash) layers and use them stratigraphically as connecting and dating tools in the geosciences (including volcanology) and in studies of past environments and archaeology. Modern tephra studies per se began around 100 years ago (in the 1920s), but the first collective of tephrochronologists with a common purpose and nascent global outlook was not formed until 7 September 1961 in Warsaw, Poland. On that date, the inaugural “Commission on Tephrochronology” (COT) was ratified under the aegis of the International Union for Quaternary Research (INQUA). The formation of COT is attributable largely to the leadership of Kunio Kobayashi of Japan, the commission's president for its first 12 years. We were motivated to record and evaluate the function and importance of COT because tephrochronology continues to grow globally and its heritage needs to be understood, appreciated, and preserved. In addition, studies on cryptotephras, which are fine-grained glass-shard and/or crystal concentrations preserved in sediments or soils but insufficiently numerous to be visible as a layer to the naked eye, have also expanded dramatically in recent times. Therefore, in this article, we review the role and impacts of COT under the umbrella of INQUA for 53 of the last 60 years or under IAVCEI (International Association of Volcanology and Chemistry of the Earth's Interior) for 7 of the last 60 years, including since 2019. The commission also functioned under other names (abbreviated as COTS, CEV, ICCT, COTAV, SCOTAV, and INTAV; see Table 2 for definitions). As well as identifying key persons of influence, we describe the development of the commission, its leaders, and its activities, which include organizing nine specialist tephra field meetings in seven different countries. Members of the commission have participated in numerous other conferences (including specialist tephra sessions) or workshops of regional to international scale, and they have played leading roles in international projects such as INTIMATE (INTegrating Ice-core, MArine and TErrestrial records) and SMART (Synchronising Marine And ice-core Records using Tephrochronology). As well as strongly supporting early-career researchers including graduate students, the commission has generated 10 tephra-themed journal volumes and two books. It has published numerous other articles including field guidebooks, reports, and specialist internet documents/sites. Although its fortunes have ebbed as well as flowed, the commission began to prosper after 1987 when key changes in leadership occurred. COT has blossomed further, especially in the past decade or so, as an entire new cohort of specialists, including many engaged in cryptotephra studies, has emerged alongside new geoanalytical and dating techniques or protocols to become a vibrant global group today. We name 29 elected officers who have been involved with COT since 1961 as well as 15 honorary life members. After reviewing the aims of the commission, we conclude by evaluating its legacies and by documenting current and future work.

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Cryptotephra from Lipari Volcano in the eastern Gulf of Taranto (Italy) as a time marker for paleoclimatic studies

Cited by 6 publications

References 68 publications

Chrono-stratigraphy of the youngest (last 1500 years) rhyolitic eruptions of Lipari (Aeolian Islands, Southern Italy) and implications for distal tephra correlations

Chrono-stratigraphy of the youngest (last 1500 years) rhyolitic eruptions of Lipari (Aeolian Islands, Southern Italy) and implications for distal tephra correlations

Climate change, society, and pandemic disease in Roman Italy between 200 BCE and 600 CE

Global tephra studies: role and importance of the international tephra research group “Commission on Tephrochronology” in its first 60 years

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