Evolution of northern wetlands since the Last Glacial Maximum Pirita Oksanen, University of Bristol, School of Geographical Sciences Contact

Slides:

Advertisements

Similar presentations

The Ice Age. The Ice Age Section Objectives Describe the climatic cycles that exist during an ice age. Identify and summarize the theory that best.

Advertisements

Pirita Oksanen and Sandy Harrison, University of Bristol, School of Geographical Sciences Evolution of wetlands since the Last Glacial Maximum Acknowledgements.

Evolution of wetlands since the Last Glacial Maximum Pirita Oksanen University of Bristol.

The Glacial History of Michigan

In the Beginning… Ice Age: period of time when freezing temperatures created ice sheets across continents. Glaciers covered most of.

Global warming and CO2―Are we headed for global catastrophe in the coming century? Don J. Easterbrook.

1 Climate Change Science Kathryn Parker U.S. Environmental Protection Agency Rocky Mountain National Park March 21, 2007 July 1932July 1988 Glacier National.

Clima en España: Pasado, presente y futuro Madrid, Spain, 11 – 13 February 1 IMEDEA (UIB - CSIC), Mallorca, SPAIN. 2 National Oceanography Centre, Southampton,

Global Air temperature from 1850 The time series shows the combined global land and marine surface temperature record from 1850 to The year 2007.

Climate Variability on Millennial Time Scales Introduction Dansgaard-Oeschger events Heinrich events Younger Dryas event Deglacial meltwater Meridional.

Drift of solar constants for the Earth (1), Venus (2) and Marc (3) due to increasing of Sun’s luminosity. Within an interval formed by carves 4 and 5 the.

The Last Glacial Maximum (LGM)

Equilibrium-Line Altitude Reconstruction in the Tropical and Subtropical Andes During the Last Glacial Maximum Lauren Vargo and Joseph Galewsky (Dept.

Pirita O. Oksanen, University of Bristol, School of Geographical Sciences Searching for wetlands since the Last Glacial Maximum Acknowledgements Most basal.

Climate models in (palaeo-) climatic research How can we use climate models as tools for hypothesis testing in (palaeo-) climatic research and how can.

SEAT Traverse The Satellite Era Accumulation Traverse (SEAT) collected near-surface firn cores and Ultra High Frequency (UHF) Frequency Modulated.

Lecture 7 Paleoclimate and the Ice Ages. Ruth Valley Glacier Alaska--The glacier occupying Yosemite Valley probably looked similar.

Seasonal Variations Why do we have seasons ? (continued…)

UNDERC INTRODUCTION #1: A REGION SHAPED BY GLACIERS

Global Climate Cycles, Global Warming and Anthropogenic Greenhouse Effect.

Outline Further Reading: Detailed Notes Posted on Class Web Sites Natural Environments: The Atmosphere GE 101 – Spring 2006 Boston University Myneni L28:

Chapter 4: Lesson 1 The Continental Drift Hypothesis

Lecture 10: Orbital Control of Ice Sheets

Composite of Sea Level – for last 600 k years. Note that SL was not always extremely low during glacial periods. From Rabineau et al, EPSL, 2006.

The Last Glacial Maximum (LGM) Lesson 1 Starter Slides on the nature and timing of the LGM.

Lecture 35: The Global Warming Debate Ch. 18 The Global Warming Debate Ch. 17, Ch Is global warming real? (Or is global warming happening?) 2.What.

Lecture 30: Historical Climate Part V, ; Ch. 17, p

Lecture 24: Survey of the Last Glacial Maximum Part IV, p ; Chapter 12 (p )

Chapter Menu Chapter Introduction Lesson 1Lesson 1The Continental Drift Hypothesis Lesson 2Lesson 2Development of a Theory Lesson 3Lesson 3The Theory.

Paleoclimatology Why is it important? Angela Colbert Climate Modeling Group October 24, 2011.

Investigation of Perennial Cave Ice in Lava Beds National Monument Nicole Rocco, Geology undergraduate & Dr. Ed Brook, Project Advisor, CEOAS Introduction.

A Multidecadal Midge-Based Temperature Reconstruction From the Great Basin, United States Provides Evidence of Warmer Conditions During The Medieval Climatic.

Unit 18: Natural Climate Change. OBJECTIVES: Explore the origin and nature of climate change Present Earth’s climatic history prior to the industrial.

What is Loess? What was the European climate like during the last glacial maximum? How did the 19 th century scientists know there were ice ages? How much.

Ice Ages Effects on Climate, Weather, & Geography.

Summary of Research on Climate Change Feedbacks in the Arctic Erica Betts April 01, 2008.

Lecture 8 The Holocene and Recent Climate Change.

Typical glacial landscapes T Parson – Allerton Grange School.

The FRAME Key Topic is about... So What? Main Idea Details _________________ Geography Introduction The study of the physical features of the earth and.

Characterizing and understanding the Quaternary Glacial/Interglacial cycles Earth’s Climate and Environment: Past, Present, and Future GEOL 3100.

Paper Review R 馮培寧 Kirsten Feng.

PLATE TECTONICS: PART 1 The Theory of Continental Drift Early in the 1900’s, Alfred Wagener proposed a theory, and suggested evidence for it. It was not.

Meeting of the CCl/OPACE2 Task Team on National Climate Monitoring Products How might NCMPs contribute in future IPCC reports ? Fatima Driouech TT on national.

Population. Key knowledge and skills Distribution and composition Future patterns.

Lecture 27: Climate Change in the Last Years Ch. 13.

CLIMATE CHANGE THE GREAT DEBATE Session 5.

World Geography Unit 1: Land and Water Forms Glaciers as Agents of Erosion.

An analysis of Russian Sea Ice Charts for A. Mahoney, R.G. Barry and F. Fetterer National Snow and Ice Data Center, University of Colorado Boulder,

CLIMATE CHANGE THE GREAT DEBATE Session 3. Advancing Franz Josef Glacier in 1996, New Zealand.

Synthesis and Integration of Studies of Secondary Forests 1. How fast does biomass accumulate and what factors are important as controllers of regrowth.

Timing of high latitude peatland initiation since the Last Glacial Maximum Pirita Oksanen, University of Bristol, School of Geographical Sciences Contact.

Questions Geographers Ask Location- Where is it? What is its absolute location? What is its relative location? Place- What is it like there? What are.

Glaciers.  Glaciers: Masses of ice built up over thousands of years.  Alpine Glaciers: Glaciers that occur in high altitudes, such as mountains.  Continental.

Wetland synthesis Pirita Oksanen and Sandy Harrison University of Bristol.

Impacts of Climate Change on Physical Systems Lesson Plan 4 – Day 2 PPT

The Surface of the Ice-Age Earth

©2010 Elsevier, Inc. 1 Chapter 13 Cuffey & Paterson.

Latitude and Longitude HEMISPHERES. Earth’s Hemispheres The Earth can be divided into four parts or hemispheres: 1)Northern 2)Southern 3)Eastern 4)Western.

Years before present This graph shows climate change over the more recent 20,000 years. It shows temperature increase and atmospheric carbon dioxide. Is.

Long-term climate change & Short-term climate variability.

Cultural Periods.

Glacio-isostatic Response in the Puget Lowland

VI Congreso Ibérico International Permafrost Association

MAIN ACTIVITY AREAS Global system of terrestrial observation networks: Gt-Net (ecology, glaciers, hydrology, permafrost) Regional activities: Central and.

Reconstructing Past Climates

Presentation transcript:

Evolution of northern wetlands since the Last Glacial Maximum Pirita Oksanen, University of Bristol, School of Geographical Sciences Contact Wetland data synthesis web site cal BP cal BP cal BP cal BP cal BP cal BP cal BP cal BP 9000 cal BP 8000 cal BP 7000 cal BP Introduction Information from ca late-Quaternary peat cores at above 39 N has been collected in a global wetland database within the QUEST-Deglaciation project. The data, including modern wetland type and area as well as peat stratigraphy and dating, are still incomplete, but most cores comprise at least the basal date indicating the time of wetland initiation. The synthesis is carried out in order to document the evolution of wetlands since the Last Glacial Maximum, to better understand the patterns of wetland initiation and the role of wetlands in the terrestrial carbon cycle during the last Ice Age and deglaciation, and to identify gaps in the existing wetland research. The data set will also be used to validate Earth System model simulations. Based on the collected data, a set of maps and time series is created, showing the change in peatland initiation and extent through time. All dates are calibrated to calendar years BP using OxCal calibration programme. The study area is divided into regions that show differences in the pattern of peatland evolution. Analyses on different characteristics are underway. Acknowledgements Earlier databases by Gorham et al. (2005) and McDonald et al. (2006) are incorporated into this database. The ice sheets reconstructions are based on ICE- 5G by Peltier (2004). Continental outlines are compiled by P. Bartlein. Results There was no significant peat accumulation in the high-latitudes of the northern hemisphere during the Last Glacial Maximum. Deglaciation started in America at ca. 16,000 cal BP, and first peatlands appeared at the same time. In Europe, deglaciation started earlier, at about 18,000 cal BP, but first peatlands are recorded at around 14,500 cal BP. Most of the early peatlands in America are now buried. In non-glaciated Alaska the formation started at ca. 17,500 cal BP, but in Siberia considerably later, at ca. 14,000 cal BP. At its most active peatland initiation was between 11,000 and 9000 cal BP: the highest peak in America occurred at ca. 10,500 and across Eurasia at ca cal BP. Half of the glaciers had melted from Europe by ca. 15,000 cal BP, and by ca. 10,000 cal BP from America. For peatlands, the half point was reached at 8000 and 9000 cal BP, respectively, and in Siberia, at 8500 cal BP. By around 7000 cal BP, when 60% of the modern peatlands existed, the distribution pattern was similar to today. The biggest relative troughs in the initiation curves occur at ca. 12,000 cal BP in Europe and eastern North America, 11,500 cal BP in Alaska, ca cal BP in western North America, 7500 cal BP in eastern Siberia and 7000 cal BP in western Siberia. None of these troughs extend below the standard deviation. Region together with mire type predicts best the age of a peatland or peat layer, but the variability is still large. Bogs show generally more constant accumulation rates than fens. Altitude makes little difference; most peatlands are located at lowlands, but peat of all ages is found at high altitudes too. All sites currently in the database, and division into regions. Extent of glaciers and distribution of peatlands through time Peatland initiation start and rates compared for the regions Peatland initiation dates and area covered by glaciers, for the world above 39 N and the regions Age-depth comparison of European bogs and fens