Climate changes during the Late Glacial in southern Europe: new insights based on pollen and brGDGTs of Lake Matese in Italy
暂无分享,去创建一个
L. Charlet | S. Guédron | B. Paura | O. Peyron | B. Vannière | S. Wulf | S. Joannin | J. de Beaulieu | G. Ménot | Oona Appelt | E. Brugiapaglia | L. Dugerdil | S. Ansanay-Alex | M. Robles | Marion Blache | A. Cromartie | Salomé Ansanay-Alex
[1] A. Develle,et al. Lipid biomarker (brGDGT)- and pollen-based reconstruction of temperature change during the Middle to Late Holocene transition in the Carpathians , 2022, Global and Planetary Change.
[2] L. Millet,et al. High-frequency vegetation and climatic changes during the Lateglacial inferred from the Lapsou pollen record (Cantal, southern Massif Central, France) , 2022, Quaternary International.
[3] J. S. Sinninghe Damsté,et al. Paleoclimate reconstruction of the last 36 kyr based on branched glycerol dialkyl glycerol tetraethers in the Padul palaeolake record (Sierra Nevada, southern Iberian Peninsula) , 2022, Quaternary Science Reviews.
[4] F. Guiter,et al. Late-Glacial palaeotemperatures and palaeoprecipitations in the Aubrac Mountains (French Massif Central) reconstructed from multiproxy analyses (Coleoptera, chironomids and pollen) , 2022, Quaternary International.
[5] A. Develle,et al. Impact of climate changes on vegetation and human societies during the Holocene in the South Caucasus (Vanevan, Armenia): A multiproxy approach including pollen, NPPs and brGDGTs , 2022, Quaternary Science Reviews.
[6] A. Develle,et al. Late Holocene Mongolian climate and environment reconstructions from brGDGTs, NPPs and pollen transfer functions for Lake Ayrag: Paleoclimate implications for Arid Central Asia , 2021, Quaternary Science Reviews.
[7] C. Schubert,et al. Temperature, precipitation, and vegetation changes in the Eastern Mediterranean over the last deglaciation and Dansgaard-Oeschger events , 2021 .
[8] H. Behling,et al. Climate reconstructions based on GDGT and pollen surface datasets from Mongolia and Baikal area: calibrations and applicability to extremely cold–dry environments over the Late Holocene , 2021, Climate of the Past.
[9] G. Miller,et al. Revised fractional abundances and warm-season temperatures substantially improve brGDGT calibrations in lake sediments , 2021, Biogeosciences.
[10] J. Tierney,et al. A global Bayesian temperature calibration for lacustrine brGDGTs , 2020, Geochimica et Cosmochimica Acta.
[11] L. Holmström,et al. Pollen-based climate reconstruction techniques for late Quaternary studies , 2020, Earth-Science Reviews.
[12] C. Spötl,et al. A high‐resolution speleothem proxy record of the Late Glacial in the European Alps: extending the NALPS19 record until the beginning of the Holocene , 2020, Journal of Quaternary Science.
[13] A. Ribolini,et al. Atmospheric circulation over Europe during the Younger Dryas , 2020, Science Advances.
[14] Xuefa Shi,et al. Evaluation of reconstructed sea surface temperatures based on U37k′ from sediment surface samples of the North Pacific , 2020 .
[15] D. Horne,et al. Rapid Late Pleistocene climate change reconstructed from a lacustrine ostracod record in central Italy (Lake Trasimeno, Umbria) , 2020, Boreas.
[16] E. Bard,et al. Early Holocene Thermal Maximum recorded by branched tetraethers and pollen in Western Europe (Massif Central, France) , 2020, Quaternary Science Reviews.
[17] R. Pancost,et al. Insights into the evolution of the young Lake Ohrid ecosystem and vegetation succession from a southern European refugium during the Early Pleistocene , 2020, Quaternary Science Reviews.
[18] J. S. Sinninghe Damsté,et al. BayMBT: A Bayesian calibration model for branched glycerol dialkyl glycerol tetraethers in soils and peats , 2020, Geochimica et Cosmochimica Acta.
[19] John W. Williams,et al. Machine-learning based reconstructions of primary and secondary climate variables from North American and European fossil pollen data , 2019, Scientific Reports.
[20] P. Petrosino,et al. Constraining mountain front tectonic activity in extensional setting from geomorphology and Quaternary stratigraphy: A case study from the Matese ridge, southern Apennines , 2019, Quaternary Science Reviews.
[21] E. Bard,et al. Impact of human activities and vegetation changes on the tetraether sources in Lake St Front (Massif Central, France) , 2019, Organic Geochemistry.
[22] B. Glaser,et al. How dry was the Younger Dryas? Evidence from a coupled δ2H–δ18O biomarker paleohygrometer applied to the Gemündener Maar sediments, Western Eifel, Germany , 2019, Climate of the Past.
[23] J. Russell,et al. Vegetation effects on temperature calibrations of branched glycerol dialkyl glycerol tetraether (brGDGTs) in soils , 2019, Organic Geochemistry.
[24] L. Sadori. The Lateglacial and Holocene vegetation and climate history of Lago di Mezzano (central Italy) , 2018, Quaternary Science Reviews.
[25] J. Damsté,et al. An overview of the occurrence of ether- and ester-linked iso-diabolic acid membrane lipids in microbial cultures of the Acidobacteria: Implications for brGDGT paleoproxies for temperature and pH , 2018, Organic Geochemistry.
[26] E. Bard,et al. The importance of mass accuracy in selected ion monitoring analysis of branched and isoprenoid tetraethers , 2018 .
[27] C. M. Barton,et al. Risk and resilience in the late glacial: A case study from the western Mediterranean , 2018 .
[28] J. Russell,et al. Distributions of 5- and 6-methyl branched glycerol dialkyl glycerol tetraethers (brGDGTs) in East African lake sediment : Effects of temperature, pH, and new lacustrine paleotemperature calibrations , 2018 .
[29] J. Russell,et al. Temperature variations in the southern Great Lakes during the last deglaciation: Comparison between pollen and GDGT proxies , 2018 .
[30] K. Rehfeld,et al. Global patterns of declining temperature variability from the Last Glacial Maximum to the Holocene , 2018, Nature.
[31] D. M. Gray,et al. Introducing global peat-specific temperature and pH calibrations based on brGDGT bacterial lipids , 2017 .
[32] R. Pancost,et al. Refining the global branched glycerol dialkyl glycerol tetraether (brGDGT) soil temperature calibration , 2017 .
[33] N. Combourieu-Nebout,et al. Precipitation changes in the Mediterranean basin during the Holocene from terrestrial and marine pollen records: a model–data comparison , 2017 .
[34] T. A. Stabile,et al. Middle to Late Pleistocene activity of the northern Matese fault system (southern Apennines, Italy) , 2017 .
[35] F. Joos,et al. Warm Mediterranean mid-Holocene summers inferred from fossil midge assemblages , 2017 .
[36] D. Rius,et al. Lateglacial-Holocene abrupt vegetation changes at Lago Trifoglietti in Calabria, Southern Italy: The setting of ecosystems in a refugial zone , 2017 .
[37] G. Lavecchia,et al. Segmentation pattern and structural complexities in seismogenic extensional settings: The North Matese Fault System (Central Italy) , 2017 .
[38] M. Lange,et al. Identification of novel 7-methyl and cyclopentanyl branched glycerol dialkyl glycerol tetraethers in lake sediments , 2016 .
[39] P. Podwojewski,et al. Consideration of soil types for the calibration of molecular proxies for soil pH and temperature using global soil datasets and Vietnamese soil profiles , 2016 .
[40] H. Birks,et al. Environmental and climate reconstruction of the late-glacial-Holocene transition from a lake sediment sequence in Aubrac, French Massif Central: Chironomid and diatom evidence , 2016 .
[41] Stefan Schouten,et al. The effect of improved chromatography on GDGT-based palaeoproxies , 2016 .
[42] H. Goosse,et al. Multiple causes of the Younger Dryas cold period , 2015 .
[43] F. Fiorillo,et al. Recharge processes of Matese karst massif (southern Italy) , 2015, Environmental Earth Sciences.
[44] C. Ramsey,et al. Improved age estimates for key Late Quaternary European tephra horizons in the RESET lattice , 2015 .
[45] P. Burrato,et al. The seismogenic structure of the 2013–2014 Matese seismic sequence, Southern Italy: implication for the geometry of the Apennines active extensional belt , 2015 .
[46] A. Lotter,et al. Stacking of discontinuous regional palaeoclimate records: Chironomid-based summer temperatures from the Alpine region , 2015 .
[47] S. Brooks,et al. A compilation of Western European terrestrial records 60–8 ka BP: towards an understanding of latitudinal climatic gradients , 2014 .
[48] H. Fischer,et al. A stratigraphic framework for abrupt climatic changes during the Last Glacial period based on three synchronized Greenland ice-core records: refining and extending the INTIMATE event stratigraphy , 2014 .
[49] J. Russell,et al. Seasonal variability of branched glycerol dialkyl glycerol tetraethers (brGDGTs) in a temperate lake system , 2014 .
[50] R. Cheddadi,et al. Spatial climate dynamics in the Iberian Peninsula since 15 000 Yr BP , 2014 .
[51] Stefan Schouten,et al. Occurrence and abundance of 6-methyl branched glycerol dialkyl glycerol tetraethers in soils : Implications for palaeoclimate reconstruction , 2014 .
[52] H. Birks,et al. Validation of climate model-inferred regional temperature change for late-glacial Europe , 2014, Nature Communications.
[53] J. Damsté,et al. Sources of core and intact branched tetraether membrane lipids in the lacustrine environment: Anatomy of Lake Challa and its catchment, equatorial East Africa , 2014 .
[54] I. Isola,et al. Lateglacial to Holocene trace element record (Ba, Mg, Sr) from Corchia Cave (Apuan Alps, central Italy): paleoenvironmental implications , 2014 .
[55] R. Evershed,et al. Correlations between microbial tetraether lipids and environmental variables in Chinese soils: Optimizing the paleo-reconstructions in semi-arid and arid regions , 2014 .
[56] E. Bard,et al. Insights into continental temperatures in the northwestern Black Sea area during the Last Glacial period using branched tetraether lipids , 2014 .
[57] P. Aucelli,et al. Geomorphological map of the central sector of the Matese Mountains (Southern Italy): an example of complex landscape evolution in a Mediterranean mountain environment , 2013 .
[58] N. Combourieu-Nebout,et al. Holocene vegetation and climate changes in the central Mediterranean inferred from a high-resolution marine pollen record (Adriatic Sea) , 2013 .
[59] N. Combourieu-Nebout,et al. North-south palaeohydrological contrasts in the central Mediterranean during the Holocene: tentative synthesis and working hypotheses , 2013 .
[60] D. Genty,et al. Seemingly divergent sea surface temperature proxy records in the central Mediterranean during the last deglaciation , 2013 .
[61] N. Combourieu-Nebout,et al. Contrasting patterns of climatic changes during the Holocene across the Italian Peninsula reconstructed from pollen data , 2013 .
[62] G. Jia,et al. Alkenone and tetraether lipids reflect different seasonal seawater temperatures in the coastal northern South China Sea , 2013 .
[63] N. Combourieu-Nebout,et al. Deglacial and Holocene vegetation and climatic changes in the southern Central Mediterranean from a direct land–sea correlation , 2013 .
[64] A. Lotter,et al. A TEX86 lake record suggests simultaneous shifts in temperature in Central Europe and Greenland during the last deglaciation , 2013 .
[65] S. Goring,et al. Pollen-based reconstruction of Holocene vegetation and climate in Southern Italy: the case of Lago di Trifoglietti , 2012 .
[66] L. Frate,et al. Structure, ecology and plant richness patterns in fragmented beech forests , 2012 .
[67] M. Menzies,et al. Geochemistry of the Phlegraean Fields (Italy) proximal sources for major Mediterranean tephras: implications for the dispersal of Plinian and co-ignimbritic components of explosive eruptions , 2012 .
[68] M. Cutini,et al. The Quercus cerris woods of the alliance Carpinion orientalis Horvat 1958 in Italy , 2012 .
[69] C. Bryant,et al. Lateglacial and early Holocene palaeoenvironmental ‘events’ in Sluggan Bog, Northern Ireland: comparisons with the Greenland NGRIP GICC05 event stratigraphy , 2012 .
[70] Stephen J. Brooks,et al. Rapid summer temperature changes during Termination 1a: high-resolution multi-proxy climate reconstructions from Gerzensee (Switzerland) , 2012 .
[71] L. Millet,et al. Chironomid-based reconstruction of Lateglacial summer temperatures from the Ech palaeolake record (French western Pyrenees) , 2012 .
[72] D. Froese,et al. The INTAV intercomparison of electron-beam microanalysis of glass by tephrochronology laboratories: Results and recommendations , 2011 .
[73] N. Pearce,et al. Tephrostratigraphy and glass compositions of post-15 kyr Campi Flegrei eruptions: implications for eruption history and chronostratigraphic markers , 2011 .
[74] Stefan Schouten,et al. A review of molecular organic proxies for examining modern and ancient lacustrine environments , 2011 .
[75] J. Russell,et al. Distributions of branched GDGTs in soils and lake sediments from western Uganda: Implications for a lacustrine paleothermometer , 2011 .
[76] S. Goring,et al. Holocene seasonality changes in the central Mediterranean region reconstructed from the pollen sequences of Lake Accesa (Italy) and Tenaghi Philippon (Greece) , 2011 .
[77] F. Fiorillo,et al. The relation between karst spring discharge and rainfall by cross-correlation analysis (Campania, southern Italy) , 2010 .
[78] M. Blaauw. Methods and code for 'classical' age-modelling of radiocarbon sequences. , 2010 .
[79] W. Tinner,et al. Late-Glacial and Holocene vegetation history of Pavullo nel Frignano (Northern Apennines, Italy) , 2010 .
[80] A. Stams,et al. Constraints on the Biological Source(s) of the Orphan Branched Tetraether Membrane Lipids , 2009 .
[81] S. Wulf,et al. Towards a detailed distal tephrostratigraphy in the Central Mediterranean : The last 20,000 yrs record of Lago Grande di Monticchio , 2008 .
[82] J Elith,et al. A working guide to boosted regression trees. , 2008, The Journal of animal ecology.
[83] W. Finsinger,et al. Late-glacial chironomid-based temperature reconstructions for Lago Piccolo di Avigliana in the southwestern Alps (Italy) , 2008 .
[84] Walter Finsinger,et al. Modern pollen assemblages as climate indicators in southern Europe , 2007 .
[85] Stefan Schouten,et al. Environmental controls on bacterial tetraether membrane lipid distribution in soils , 2007 .
[86] L. Millet,et al. Vegetation history, climate and human impact over the last 15,000 years at Lago dell’Accesa (Tuscany, Central Italy) , 2007 .
[87] O. Spaargaren,et al. Occurrence and distribution of tetraether membrane lipids in soils : Implications for the use of the TEX86 proxy and the BIT index , 2006 .
[88] D. Thompson,et al. An improved method to determine the absolute abundance of glycerol dibiphytanyl glycerol tetraether lipids , 2006 .
[89] A. Prasad,et al. Newer Classification and Regression Tree Techniques: Bagging and Random Forests for Ecological Prediction , 2006, Ecosystems.
[90] L. Millet,et al. Late-Glacial climatic changes in Eastern France (Lake Lautrey) from pollen, lake-levels, and chironomids , 2005, Quaternary Research.
[91] A. Brauer,et al. Tephrochronology of the 100 ka lacustrine sediment record of Lago Grande di Monticchio (southern Italy) , 2004 .
[92] A. Mercuri,et al. The long history of Cannabis and its cultivation by the Romans in central Italy, shown by pollen records from Lago Albano and Lago di Nemi , 2002 .
[93] Odile Peyron,et al. Climatic Reconstruction in Europe for 18,000 YR B.P. from Pollen Data , 1998, Quaternary Research.
[94] J. Hunt,et al. An inter-laboratory comparison of the electron probe microanalysis of glass geochemistry , 1996 .
[95] G. Coope,et al. Regional differences in the Lateglacial climate of northern Europe based on coleopteran analysis , 1995 .
[96] J. Guiot,et al. Methodology of the last climatic cycle reconstruction in France from pollen data , 1990 .
[97] R. Bradshaw,et al. The Selection of Sites for Paleovegetational Studies , 1981, Quaternary Research.