PART I. Introduction 1. Introduction 2. The Terminations of the
Glacial Cycles. 3. Previous synthesis of Last Deglaciation in
Europe
PART II. Climate changes during the Last Deglaciation in the
Eastern North Atlantic region 4. Introduction 5. The Heinrich-1
Stadial 6. The Bølling-Allerød Interstadial 7. The Younger Dryas
Stadial
PART III. The European glacial landforms during main deglaciation
(18.9-14.6 ka) 8. Concept and global context of the glacial
landforms from deglaciation SECTION 1. European regions that were
covered by the European Ice Sheet Complex (EISC) 9. European Ice
Sheet Complex evolution during main deglaciation (18.9-14.6 ka) 10.
Fennoscandia: glacial landforms during deglaciation (18.9-14.6 ka)
11. Northern Central Europe: glacial landforms during deglaciation
(18.9-14.6 ka) 12. European Russia: glacial landforms during
deglaciation (18.9-14.6 ka) 13. The Eurasian Arctic: Glacial
landforms during main deglaciation (18.9-14.6 ka) 14. The North Sea
and Mid Norwegian Continental Margin: glacial landforms during
deglaciation, the Bølling-Allerød Interstadial and the Younger
Dryas. 15. Britain and Ireland: glacial landforms during
deglaciation (18.9-14.6 ka). SECTION 2. European regions that were
not covered by the EISC 16. The Polar Ural Mountains: Deglaciation
history. 17. Iceland: glacial landforms during deglaciation
(18.9-14.6 ka) 18. The evolution of glacial landforms in the Tatra
Mountains during deglaciation (18.9-14.6 ka). 19. The Romanian
Carpathians: glacial landforms during deglaciation (18.9-14.6 ka).
20. The Alps: glacial landforms during deglaciation (18.9 to 14.6
ka). 21. The Pyrenees: environments and landforms in the aftermath
of the LGM (18.9–14.6 ka). 22. The evolution of glacial landforms
in Iberian Mountains during deglaciation (18.9–14.6 ka). 23. The
Italian Mountains: glacial landforms during deglaciation (18.9–14.6
ka). 24. The Balkans: glacial landforms during deglaciation
(18.9–14.6 ka). 25. The Anatolian Mountains: glacial landforms
during deglaciation (18.9–14.6 ka). SECTION 3. Synthesis of Part
III 26. The European glacial landscapes from the main
deglaciation
PART IV. The European glacial landforms from the Bølling-Allerød
Interstadial (14.6-12.9 ka) 27. Concept and global context of the
glacial landforms from the Bølling-Allerød Interstadial SECTION 1.
European regions that were covered by the European Ice Sheet
Complex (EISC) 28. European Ice Sheet Complex evolution during the
Bølling-Allerød Interstadial (14.6-12.9 ka) 29. Fennoscandia:
glacial landforms from the Bølling-Allerød Interstadial (14.6-12.9
ka). 30. Northern Central Europe: glacial landforms from the
Bølling-Allerød Interstadial 31. European Russia: glacial landforms
from the Bølling-Allerød Interstadial 32. The Eurasian Arctic:
Glacial landforms from the Bølling-Allerød Interstadial (14.6-12.9
ka BP). 33. Britain and Ireland: glacial landforms from the
Bølling-Allerød Interstadial. SECTION 2: European regions that were
not covered by the EISC 34. Iceland: Glacial landforms and raised
shorelines from the Bølling-Allerød interstadial. 35. The evolution
of glacial landforms in the Tatra Mountains during the
Bølling-Allerød Interstadial. 36. The Romanian Carpathians: glacial
landforms during Bølling –Allerød Interstadial. 37. The Alps:
glacial landforms from the Bølling-Allerød Interstadial 38. The
Pyrenees: glacial landforms from the Bølling-Allerød Interstadial
39. The evolution of glacial landforms in the Iberian Mountains
during Bølling-Allerød Interstadial. 40. The Italian Mountains:
glacial landforms from the Bølling-Allerød Interstadial 41. The
Balkans: glacial landforms from the Bølling-Allerød Interstadial
42. The Anatolian Mountains: glacial landforms from the
Bølling-Allerød Interstadial SECTION 3. Synthesis of the Part IV
43. European glacial landscapes from the Bølling-Allerød
Interstadial
PART V. The European glacial landforms from the Younger Dryas
Stadial (12.9-11.7 ka) 44. Concept and global context of the
glacial landforms from Younger Dryas SECTION 1. European regions
that were covered by the European Ice Sheet Complex (EISC) 45. The
EISC evolution during the Younger Dryas Stadial (12.9-11.7 ka). 46.
The Fennoscandian Ice Sheet during the Younger Dryas Stadial. 47.
Younger Dryas local moraines in western and northern Norway 48.
Northern Central Europe: glacial landforms from the Younger Dryas
Stadial. 49. European Russia: glacial landforms from the Younger
Dryas Stadial. 50. The Eurasian Arctic:?Glacial landforms from the
Younger Dryas Stadial. 51. Britain and Ireland: glacial landforms
from the Younger Dryas Stadial SECTION 2. European regions that not
were covered by the EISC 52. Iceland: glacial landforms from the
Younger Dryas Stadial 53. The evolution of glacial landforms in the
Tatra Mountains during the Younger Dryas Stadial. 54. The Romanian
Carpathians: glacial landforms from the Younger Dryas 55. The Alps:
glacial landforms from the Younger Dryas Stadial 56. The Pyrenees:
glacial landforms from the Younger Dryas Stadial 57. The evolution
of glacial landforms in Iberian Mountains during the Younger Dryas
Stadial. 58. The Italian Mountains: glacial landforms from the
Younger Dryas Stadial. 59. The Balkans: glacial landforms from the
Younger Dryas Stadial. 60. The Anatolian Mountains: glacial
landforms from the Younger Dryas Stadial. SECTION 3. Synthesis of
Part V 61. The European glacial landscapes from the Younger Dryas
Stadial
PART VI. The Synthesis of the European Landscapes from Last
Deglaciation 62. The importance of European glacial landscapes in a
context of great climatic variability
David Palacios is Full Professor of Physical Geography at the Complutense University of Madrid, Spain. He has been the coordinator for Spanish National Projects since 1998 to the present, and Spanish coordinator of two European Projects. He has served as founder and director of the High Mountain Physical Geography excellence research group for 12 years, and has authored over 200 international research papers, 100 chapters, and has edited five books. Philip Hughes is Professor of Physical Geography at the University of Manchester, United Kingdom. He obtained his first degree in geography at the University of Exeter graduating in 1999. This was followed by a Masters in Quaternary Science, then a PhD in Geography (2004), both at the University of Cambridge (Darwin College). His PhD was on the glacial history of the Pindus Mountains, Greece. This was then followed by a postdoctoral research project examining the glacial history of Montenegro at the University of Manchester (2004-2006). He has since worked on glaciation across the Mediterranean mountains in Greece, Albania, Montenegro, Croatia, Spain and with recent research activities focusing on the Atlas Mountains, Morocco. His research has utilised U-series dating and cosmogenic nuclides to date moraines in a variety of different lithologies, from limestones to basalts. In addition to studies of Mediterranean mountain glaciations he has also published on global glaciations and stratigraphy in Quaternary science. In addition to several edited scientific volumes on glaciation, in 2016 he published the textbook The Ice Age with co-authors Jürgen Ehlers and Philip Gibbard. In 2011 Philip also edited with these co-authors the highly successful Elsevier volume Quaternary Glaciation: Extent and Chronology – A Closer Look. Philip Hughes is Professor of Physical Geography at the University of Manchester, United Kingdom. José M. García-Ruiz is Ad Honorem Research Professor of the National Research Council of Spain (CSIC) at the Pyrenean Institute of Ecology. He was the Head of the University College of La Rioja (1982-1984), the head of the Pyrenean Institute of Ecology (1988-1990) and President of the Spanish Society of Geomorphology (1994-1996). His main focuses of interest have been related with the interactions between land use changes and their consequences on soil erosion, connectivity between hillslopes and fluvial channels, and fluvial dynamics. The evolution of mountain landscapes since mid-Holocene has been also a main focus of research, in relation with deforestation caused by paleolithic shepherds and Middle Ages transhumant herds, including the recent afforestation caused by land abandonment and the decline of transhumance systems. In parallel, he has published a high number of studies on glacial evolution in northern Iberian Peninsula, particularly in the Pyrenees. Nuria de Andrés is Professor of Physical Geography at the Complutense University of Madrid (Spain). Her PhD was on the application of GIS to the study of hazards in tropical high volcanoes (Mexico and Peru). She has participated in 22 research projects funded in public calls and she is currently leading a research project on the reconstruction of neoglacial oscillations in Iceland. She has published nearly a hundred research papers on the dynamics of deglaciation in mountains and its impact on geodiversity. Her research work focuses on the study of glacier and periglacial geomorphology in mountain areas through the application of different dating techniques and GIS. In addition to the Iberian mountains, she has conducted research in other mountain regions (northern Iceland, Western United States, Trans-Mexican Volcanic Belt, Peruvian Andes), which has given her a broad understanding of land surface processes in cold climate environments. She heads the High Mountain Physical Geography excellence research group.
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