DOCSLIB.ORG

University of Southampton Research Repository Eprints Soton

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
University of Southampton Research Repository Eprints Soton University of Southampton Research Repository ePrints Soton Copyright © and Moral Rights for this thesis are retained by the author and/or other copyright owners. A copy can be downloaded for personal non-commercial research or study, without prior permission or charge. This thesis cannot be reproduced or quoted extensively from without first obtaining permission in writing from the copyright holder/s. The content must not be changed in any way or sold commercially in any format or medium without the formal permission of the copyright holders. When referring to this work, full bibliographic details including the author, title, awarding institution and date of the thesis must be given e.g. AUTHOR (year of submission) "Full thesis title", University of Southampton, name of the University School or Department, PhD Thesis, pagination http://eprints.soton.ac.uk UNIVERSITY OF SOUTHAMPTON FACULTY OF SCIENCE SCHOOL OF OCEAN AND EARTH SCIENCE Ecological Controls on Density, Diversity and Community Structure of Polar Megabenthos By Daniel Oliver Brée Jones Thesis for the degree of Doctor of Philosophy December 2005 UNIVERSITY OF SOUTHAMPTON FACULTY OF SCIENCE SCHOOL OF OCEAN AND EARTH SCIENCE Doctor of Philosophy Ecological Controls on Density, Diversity and Community Structure of Polar Megabenthos By Daniel Oliver Brée Jones ABSTRACT Polar deep water environments are poorly studied. This thesis investigates fundamental questions as to the nature of controlling factors on megabenthic communities as well as the diversity, densities and distributions of organisms present. The deep (1000-1660m) Faroe-Shetland Channel harbours an Arctic fauna owing to cold deep- water intrusions from the Norwegian Sea. Despite the relatively low species richness of the megabenthos, variation in faunal composition with depth is apparent. Two distinct communities were identified in the north and south of the channel. Epibenthic megafauna in the south are dominantly filter feeders and in the north deposit feeders. Megabenthic diversity and density decreased to the northeast of the channel. Lebensspuren number and area increase northwards in the Channel. The increase in bioturbation and deposit feeder abundance is concurrent with an increase in fine sediment quantity. The response of a deep, Arctic benthic community to physical disturbance was investigated in the Faroe-Shetland Channel. High levels of physical disturbance, characterised by smothering of the seabed resulted in significant but variable reductions in megafaunal abundance (up to 92.3%). Reductions in diversity, particularly in species richness, were apparent between disturbed (ES(500) = 12.9) and undisturbed areas (ES(500) = 20.6). The implications of selective removal of taxa on ecosystem function and recovery are discussed. Low level disturbance had comparatively little effect on the communities. The effects varied in nature depending on motility and functional group (e.g. motile scavenger abundances were maximal at intermediate distances from disturbance). Effects of physical factors on the megabenthos of Kangerdlugssuaq Fjord mouth in Arctic Greenland were investigated. Large reductions in faunal density (1881 to 60,132 individuals ha-1) and increases in diversity (H´ = 0.93-2.54), through increases in richness (ES(220) = 7.6-18.8) and reductions in dominance (Berger-Parker Index = 0.77-0.38), were found from 270 to 720m depth. Distinct shallow, intermediate and deep communities were identified. Shallower stations had high levels of iceberg disturbance, directly reducing diversity and creating a complex, patchy environment. Responses to disturbance were taxa specific (e.g. mobile suspension feeders aggregate on disturbed areas), but the shallow area has higher densities of suspension feeding epifauna. Deeper areas experience small scale disturbance from deposition of drop stones but its relatively low frequency and magnitude allows increased diversity. Deposit feeding epifaunal and infaunal taxa increase with depth indicated by increased Lebensspuren. Density decreases result from decreased food supply with depth. Benthic megafauna were investigated from the NE Weddell Sea (250 to 500m depth), close to the Fimbul Ice Shelf. Faunal density decreased with depth; diversity was variable but not related to depth. Two distinct communities were found, a shallow community with dense patches of suspension feeders in undisturbed areas and a deep community where these were not present. Disturbance from icebergs was very important in controlling faunal distribution. In shallow waters direct effects of disturbance were observed. In deeper waters habitat changes, caused by past disturbance, controlled faunal distributions. Ice ploughing created a mosaic landscape of fine and coarse sediments. Megafaunal density was highest in coarse sediment and diversity highest in intermediate areas. Quantitative data on benthic megafaunal abundance and diversity obtained using the same method allowed valid comparisons to be made between these polar areas. Megafaunal abundance was comparable between the Arctic and Antarctic stations, although in both areas abundance decreased with increased depth. Diversity was higher in the Antarctic stations, but species richness and evenness in both areas changed with depth. Iceberg disturbance was found to be very important in structuring megabenthic communities, particularly in the Antarctic. The results of this study are used to assess the utility of towed camera sleds, remotely operated vehicles and autonomous underwater vehicles as a method for obtaining ecological information in remote environments. Contents CONTENTS Chapter 1 – General Introduction History of deep-sea polar exploration 1 The deep ocean environment 2 Topography 2 Circulation and temperature 3 The deep benthic environment 5 Deep-sea community measures 6 Faunal density in the deep sea 6 Species diversity in the deep sea 7 Physical controls on deep-water communities 11 Depth 12 Habitat 13 Food supply 14 Currents 15 Disturbance 16 Measuring Diversity 19 Species diversity 19 Species Richness 19 Evenness 20 Measuring species richness 20 Disentangling metrics of species diversity in gradients of abundance 24 Measuring evenness 25 Combined diversity measures 25 Measurement of diversity between habitats 27 Megafauna 29 Deep-sea sampling 32 Traditional methods 32 Photography 33 History of use 33 Photographic techniques 34 Work in the Polar Regions using deep-sea photography 39 Sites of Interest 40 The polar environment 40 Arctic 40 Arctic bathymetry 40 Arctic benthic environment 41 Arctic primary production 43 Arctic seawater characteristics 43 Arctic ice 43 Antarctic 44 Antarctic bathymetry 44 Antarctic benthic environment 47 Antarctic primary production 49 Antarctic ice 49 Faroe-Shetland Channel 51 FSC bathymetry 51 FSC hydrographic regime 52 FSC benthic environment 54 Polar megabenthos 55 Arctic megabenthos 55 Species richness and biodiversity 55 Distribution and zonation 56 Contents Faunal densities and biomass 57 Antarctic megabenthos 58 Species richness and biodiversity 59 Distributions and zonation patterns 61 Faunal densities, biomass and productivity 61 The fauna under ice 63 Aims 64 Chapter 2 – Materials and Methods Data collection 65 WASP 65 Remotely Operated Vehicle 66 Autosub vehicle 68 Collection Devices 71 ROV Suction Sampler 71 Agassiz Trawl 72 Rock Dredge 73 Image analysis 75 Chapter 3 – Ecology of the Deep Faroe-Shetland Channel Introduction 76 Materials and Methods 79 Field Sampling 79 Photo Analysis 80 Data Analysis 80 Results 83 Environment and physical setting 83 Megafaunal density 85 Size and biomass 86 Diversity 88 Community analysis 89 Lebensspuren 95 Discussion 99 Abundance and biomass 99 Diversity 100 Species distribution patterns 103 Lebensspuren 105 Chapter 4 – Effects of disturbance on cold-water Faroe-Shetland Channel Communities Introduction 107 Materials and Methods 109 Study area 109 Data collection 113 Data analysis 114 Results 116 Discussion 127 Contents Chapter 5 – Ecology of the Kangerdlugssuaq Fjord Mouth, East Greenland Introduction 135 Materials and Methods 137 Study area 137 Field sampling 139 Photo analysis 141 Data analysis 142 Results 144 Environment and physical setting 144 Density 146 Diversity 148 Community composition 148 Small-scale patchiness 151 Traces 153 Discussion 156 Density 156 Diversity 158 Community patterns 160 Traces 163 Chapter 6 – Ecology of benthic megafaunal communities in the Fimbul Ice Shelf region, Weddell Sea, Antarctica Introduction 165 Materials and Methods 167 Study area 167 Field sampling 170 Photo analysis 171 Classification of disturbance 172 Data analysis 173 Results 175 Seabed environment 175 Density 176 Diversity 181 Community patterns 184 Discussion 186 Characterisation of the seabed environment 186 Density 188 Diversity 189 Community composition 191 Chapter 7 – Conclusions Biological conclusions Introduction 195 Methods 198 Data analysis 199 Analysis 199 Common fauna 199 Changes in densities 201 Contents Changes in diversity 202 Changes in the physical environment between regions and the effects on the 207 communities Discussion 210 Common fauna between regions 210 Faunal density between regions 211 Diversity between regions 211 Changes between the poles in relation to physical factors 212 Sufficiency of sampling 219 Methodological conclusions Introduction 221 Methods 225 Photographic technique 225 Comparison of vehicles 228 Analysis 229 Photographic technique 229 Comparison of vehicles 232 Discussion 233 Photographic technique 233 Comparison
Load more

Recommended publications
  • Antarctic Primer
    Antarctic Primer By Nigel Sitwell, Tom Ritchie & Gary Miller By Nigel Sitwell, Tom Ritchie & Gary Miller Designed by: Olivia Young, Aurora Expeditions October 2018 Cover image © I.Tortosa Morgan Suite 12, Level 2 35 Buckingham Street Surry Hills, Sydney NSW 2010, Australia To anyone who goes to the Antarctic, there is a tremendous appeal, an unparalleled combination of grandeur, beauty, vastness, loneliness, and malevolence —all of which sound terribly melodramatic — but which truly convey the actual feeling of Antarctica. Where else in the world are all of these descriptions really true? —Captain T.L.M. Sunter, ‘The Antarctic Century Newsletter ANTARCTIC PRIMER 2018 | 3 CONTENTS I. CONSERVING ANTARCTICA Guidance for Visitors to the Antarctic Antarctica’s Historic Heritage South Georgia Biosecurity II. THE PHYSICAL ENVIRONMENT Antarctica The Southern Ocean The Continent Climate Atmospheric Phenomena The Ozone Hole Climate Change Sea Ice The Antarctic Ice Cap Icebergs A Short Glossary of Ice Terms III. THE BIOLOGICAL ENVIRONMENT Life in Antarctica Adapting to the Cold The Kingdom of Krill IV. THE WILDLIFE Antarctic Squids Antarctic Fishes Antarctic Birds Antarctic Seals Antarctic Whales 4 AURORA EXPEDITIONS | Pioneering expedition travel to the heart of nature. CONTENTS V. EXPLORERS AND SCIENTISTS The Exploration of Antarctica The Antarctic Treaty VI. PLACES YOU MAY VISIT South Shetland Islands Antarctic Peninsula Weddell Sea South Orkney Islands South Georgia The Falkland Islands South Sandwich Islands The Historic Ross Sea Sector Commonwealth Bay VII. FURTHER READING VIII. WILDLIFE CHECKLISTS ANTARCTIC PRIMER 2018 | 5 Adélie penguins in the Antarctic Peninsula I. CONSERVING ANTARCTICA Antarctica is the largest wilderness area on earth, a place that must be preserved in its present, virtually pristine state.
    [Show full text]
  • Talks on Antarctica: United Nations of the World (English)
    Talks on Antarctica: United Nations of the World (English) Talks on Antarctica, the United Nations of the World Topic: the great continent of ice, wind and snow located at the southernmost end of our planet, surrounded by the Southern Ocean, where the Roaring Forties and Furious Fifties rage. It is an extraordinary nature reserve, one and a half times as big as the United States, devoted to peace and science, and a continent that does not belong to a country. You do not need a passport to land on Antarctica. The great American explorer Richard E. Byrd wrote: “ I am hopeful that Antarctica in its symbolic robe of white will shine forth as a continent of peace as nations working together there in the cause of science set an example of international cooperation”. Therefore: the true United Nations of Earth are down there, on the white continent where the South Pole is found. On 28 October 2016, the creation of the Ross Sea Marine Reserve in Antarctica was announced. It is the largest in the world (one and a half times the size of Europe): the international community has finally become aware of the need to protect the valuable Antarctic marine ecosystems. The Agreement will enter into force on December 1st 2017. WHY ANTARCTICA? 1) The continent is entirely devoted “to peace and science” (Madrid Protocol). It is a nature reserve which does not belong to any country, and is a world heritage site. Researchers and logistics technicians from several different countries work together in peace in Antarctica: 5,000 during the austral summer, and 1,000 in the winter.
    [Show full text]
  • ITALY in ANTARCTICA Definiti
    ITALY in ANTARCTICA Coring through sea-ice: a preliminary survey. ITALY IN ANTARCTICA 6 WHY ANTARCTICA? 8 ITALY AND ANTARCTICA BEFORE PNRA 10 THE ITALIAN NATIONAL PROGRAMME 12 THE INTERNATIONAL FRAMEWORK 14 ANTARCTICA AND THE WORLD 16 THIRTY YEARS OF COMMITMENT 28 MARIO ZUCCHELLI SCIENTIFIC STATION 30 CONCORDIA SCIENTIFIC STATION 34 VESSELS AND AIRCRAFTS 38 THE YEARS TO COME A small iceberg is visiting Mario Zucchelli Station. Foreword Italy has been present in Antarctica with a governmental scientific programme since 1985. Until 1985 Italian scientists, alpine guides and other adventurous spirits went to the continent mostly as members of other national expeditions. After 1985 however, and during the following thirty years, the Italian national programme PNRA (Programma Nazionale di Ricerche in Antartide) has promoted a large scientific commitment, by organizing yearly expeditions and built two stations, the first on the coast of the Ross Sea, the second – jointly with France – on the East Antarctic ice plateau. The purpose of the present publication is to stress, firstly, the global values of Antarctica, and secondly to document the activities of the Italian expeditions. Focussing on the close relationship established between Italy and Antarctica in these exciting years, whilst not forgetting our past and glimpsing into the future. It is our hope that these pages may stimulate the readers to acquire more knowledge on the continent and may help them to perceive the spirit of collaboration that enlivens the parties of all Countries working in Antarctica or on Antarctic matters. This spirit makes this continent a unique land not only from the geographical but also human point of view.
    [Show full text]
  • Antarctica the Last Continent
    Antarctica The Last Continent Copyright: Material on these pages is copyright Paul Ward / CoolAntarctica.com or reproduced with permission from other copyright owners. It may be downloaded and printed for personal reference or public performance in an educational establishment as long as it is not for direct or indirect commercial use. It may be altered or modified, but not made publically available or transmitted to others in original or modified form without the written permission of Paul Ward / CoolAntarctica.com. Pictures by Alan Light, Drummond Small, Mike Usher, Paul Ward, Text by Paul Ward / CoolAntarctica.com This copyright notice must appear wherever this material is used. Any queries please email Antarctica covers the South Pole Africa South America South Pole X X Australia and NZ st Midnight at the pole 21st December Midday at the pole 21 June The Living Earth, Inc. copyright 2006 A common way to get to Antarctica is still by ship. This means crossing the “Drake’s Passage”, the narrow band of sea between Cape Horn and the Antarctic Peninsula. It is the roughest sea on Earth. As your ship approaches Antarctica, you will be followed by albatrosses. This is a young Wandering Albatross – “The bird that made the wind to blow”. Wandering Albatross have the greatest wingspan of any birds at up to 3.5m. The first iceberg is like a doorway to the South. You don’t know where you will encounter it and it will probably be a distant shape made out through mist under a grey sky. Once seen, it signifies your passage into Antarctic waters and entry into a world quite different to any you have seen before.
    [Show full text]
  • Antarctica: Teaching and Learning About
    DOCUMENT RESUME ED 355 167 SO 023 066 AUTHOR Kiernan, Jan; Brewer, Warren TITLE Antarctica: Teaching and Learning about. A Teacher's Guide. INSTITUTION Curriculum Development Centre, Canberra (Australia). REPORT NO ISBN-0-642-53196-X PUB DATE 87 NOTE 51p.; Photographs may not reproduce clearly. AVAILABLE FROMMarketing Officer, Curriculum Services, Department of Education and the Arts, 71 Letitia Street, North Hobart, Tasmania, Australia 7000. PUB TYPE Guides Classroom Use Teaching Guides (For Teacher) (052) EDRS PRICE MF01/PC03 Plus Postage. DESCRIPTORS Area Studies; Curriculum Development; Elementary Secondary Education; Foreign Countries; *Instructional Materials; *International Educational Exchange; International Programs; Learning Activities; Resource Materials; Social Studies; Teaching Guides; *Teaching Methods IDENTIFIERS *Antarctica; Global Education ABSTRACT In 1980 the members of the Pacific Circle Consortium (Australia, New Zealand, the United States, Japan, and Canada) considered a proposal from the Tasmanian Education Department for a project to develop a curriculum framework and teaching materials about the Antarctic. The outcome was the Antarctic Project conducted jointly by Australia and New Zealand with participation from Tasmania and the Curriculum Development Center of Canberra, Australia. This document provides background on the Antarctic Project and development of the materials, explaining the Project's "resource-led" approach and its conceptual base. A resource-led approach implies that the materials are not a course
    [Show full text]
  • Condensed Matter Researches in Cryospheric Science
    Condensed Matter Researches in Cryospheric Science Edited by Augusto Marcelli, Valter Maggi and Cunde Xiao Printed Edition of the Special Issue Published in Condensed Matter www.mdpi.com/journal/condensedmatter Condensed Matter Researches in Cryospheric Science Condensed Matter Researches in Cryospheric Science Special Issue Editors Augusto Marcelli Valter Maggi Cunde Xiao MDPI • Basel • Beijing • Wuhan • Barcelona • Belgrade Special Issue Editors Augusto Marcelli Valter Maggi Istituto Nazionale di Fisica Nucleare University of Milano Bicocca Italy Italy Cunde Xiao Beijing Normal University China Editorial Office MDPI St. Alban-Anlage 66 4052 Basel, Switzerland This is a reprint of articles from the Special Issue published online in the open access journal Condensed Matter (ISSN 2410-3896) from 2018 to 2019 (available at: https://www.mdpi.com/journal/ condensedmatter/special issues/cryospheric science). For citation purposes, cite each article independently as indicated on the article page online and as indicated below: LastName, A.A.; LastName, B.B.; LastName, C.C. Article Title. Journal Name Year, Article Number, Page Range. ISBN 978-3-03921-323-8 (Pbk) ISBN 978-3-03921-324-5 (PDF) Cover image: Dosegu’ glacier from Passo Gavia, Valtellina (Italy). Courtesy by Stefano Pignotti. c 2019 by the authors. Articles in this book are Open Access and distributed under the Creative Commons Attribution (CC BY) license, which allows users to download, copy and build upon published articles, as long as the author and publisher are properly credited, which ensures maximum dissemination and a wider impact of our publications. The book as a whole is distributed by MDPI under the terms and conditions of the Creative Commons license CC BY-NC-ND.
    [Show full text]
  • Mechanical Equipment in Antarctica and the Relation of Laboratory Research to Field Performance Thesis Submitted for the Degree
    Mechanical Equipment in Antarctica and The Relation of Laboratory Research to Field Performance by D.L. Pratt M.A., A.M.I.Mech. E. Thesis submitted for the degree of Doctor of Philosophy in the Faculty of Engineering the University of London Department of Engineering, Imperial College of Science and Technology, London, S.W.7. June, 1960. ABSTRACT In the summer of 1957-1953 a vehicle journey was made for the first time across the Antarctic Continent, from the 'ieddell Sea to the Ross Sea, a distance of 2,158 miles. The mechanical engineering aspect of that project forms a large part of the field work of this thesis. The performance of polar vehicle journeys in the past is reviered and requirements for mechanical equipment are assessed. In view of the unknown conditions to be encountered an operational specification temperature of -60°F with storage to -90°F was chosen. An investigation into the main factors affecting performance led to preparatory laboratory research into the fields of : Engines and Lubrication (Startability; economy and altitude performance) Materials (Ferrous; nort4errous; elastomers) Snow Traction and Friction. A theoretical analysis indicated that cranking torque was proportional to the product of cranking speed and oil viscosity. However, the proving of startability appeared essential and the cold clamber was extensively used. Compromise field trials in Norway, together with laboratory research formed a basis for engineering planning and development. The Antarctic field results are analysed under the headings : Terrain Snow Traction and. Friction Engines and Lubrication Materials (Field. Fractures) Human. Snow friction experiments were performed for man-hauling and vehicle sledges and also aircraft on ski.
    [Show full text]
  • Persistent Organic Pollutants (Pops) in the Antarctic Environment
    Persistent Organic Pollutants (POPs) in the Antarctic environment A Review of Findings by The SCAR Action Group on Environmental Contamination in Antarctica Roger Fuocoa, Gabriele Capodagliob, Beatrice Muscatelloa and Marta Radaellib a Department of Chemistry and Industrial Chemistry, University of Pisa (Italy) b Department of Environmental Sciences, University of Venice (Italy) February 2009 A SCAR Publication Published by the Scientific Committeee on Antarctic Research (SCAR) Scott Polar Research Institute Lensfield Road Cambridge, CB2 1ER, UK First Published September 2009 ISBN 978-0-948277-23-8 2 CONTENTS Page Introduction 4 Research Findings 6 Atmosphere 6 Marine Environment 7 Terrestrial Environment 9 Food Web 11 Pelagic Plankton 11 Krill (Euphausia Superba) 12 Pelagic Marine Mammals 12 Coastal Benthic Organisms 13 Penguins 14 Skua and other birds breeding in Antarctica 16 Seals 17 World Regional Comparison 17 Conclusive Remarks on Food Web 18 In Progress Research Activities 19 2009 ECA Report vs 2002 UNEP Report 20 2002 UNEP Report 20 2009 ECA Report 20 Recommendations from ECA Report 2009 22 Appendix: Review of recent research into the presence of Persistent Organic Pollutants (POPs) in the Antarctic Environment 23 3 Persistent Organic Pollutants (POPs) in the Antarctic environment A Review of Findings INTRODUCTION 1. The main objective of programs on environmental contamination is to determine the processes influencing global environment quality. Data and feedback from this can then be employed to improve models to predict the environmental evolution. Understanding the way the earth system answers to stimuli is a formidable scientific challenge, and it is also an urgent priority owing to the growing effects of human activities on the quality both of life and environment.
    [Show full text]
  • JCS Journal No. 8
    THE JAMES CAIRD SOCIETY THE JAMES CAIRD SOCIETY JOURNAL Number Eight Antarctic Exploration Sir Ernest Shackleton May 2016 1 Sir Ernest Henry Shackleton 2 The James Caird Society Journal – Number Eight Welcome to the latest Journal (‘Number Eight’). As ever, it is a privilege to edit this work as I to seek to inspire and educate JCS members in all things ‘Shackleton’. We remain, of course, in the midst of much jubilation and the Society has advanced the Centennial celebrations in no mean fashion. Thanks must go to your hardworking Committee and, in particular, our Chairman, Sir James, who has spearheaded the major calendar of events splendidly. These will, in effect, culminate in a wonderful Commemoration Service at Westminster Abbey on Friday 20th May 2016. The launch, in January 2014, of the Society’s ‘The Shackleton Centenary Book (2014)’ [Sutherland House Publishing; ISBN 978-0-9576293-0-1] was a great success with all copies sold – thanks to the advance subscription of many members. TSCB (2014) focused, almost exclusively, on the Imperial Trans-Antarctic Expedition (ITAE) (1914/16) and was intended to be the principal written contribution by the JCS to celebrate the Centenary of the Boss’s extraordinary achievements down south. ‘Number Eight’ attempts, therefore, to complement the record by sprinkling a number of extra polar ‘goodies’ into the mix. Tim Jarvis’s Shackleton Epic Expedition set the scene for our celebrations. His successful ‘double’ crossing of the Southern Ocean and South Georgia in early 2013 was followed by three gripping one-hour documentary programmes on ‘Discovery Channel’ broadcast far and wide.
    [Show full text]
  • Journey Through the Polar Lands
    Journey Through the Polar Lands Margate Primary School, / McNeil Canyon School ICE E-MYSTERY Journey Through the Polar Lands A story written and illustrated by pupils at Margate Primary School, Tasmania, Australia and McNeil Canyon School, Alaska, USA Margate Primary School, Tasmania, Australia Margate is a small town 20km south of Hobart, the capital city of Tasmania. Surrounded by native bushland and the beautiful marine environment of North West Bay, the school has a population of 450 students from Kindergarten to Grade 6. In the summer months we all have to wear sun hats when ever we are outside, and if children don’t they have to play in the shade. Margate Primary School Class 5 Teacher: Anne Briggs Students: Erica Haskin Sabrynah Smth Josh Bones River Kitchell Lizzy Thurn Brayden Crane Zeke Lagerewskij Lucy Tomlinson Smith Megan DeMartino Molly Lucas Jacob Verdouw Jenna Field Danika Lukic Nathan Gaze Jacob Mackay Molly Gilmore James O’Donnell Brady Gordon Nichola Overeem Kurt Haba Brydie Pearce 4 McNeil Canyon School, Alaska, USA McNeil Canyon Elementary School, located 12 miles east of Homer, Alaska, was constructed in 1983. Homer is located on the north shore of Kachemak Bay on the southwestern Kenai Peninsula, at the southern most point of the Sterling Highway. The facility was originally built to house 225 students and currently serves 108 students in grades K-6. The relatively high altitude, 1350 feet, of the school site provides lots of snow and ice so students are able to skate and ski for almost half of the school year. McNeil Canyon School Class 5/6 Teacher: Sheryl Sotelo Keagan Jiron Jonas Noomah Anthony Jones Irene Pellegrini Students: Jessica Jones Sunny Puterbaugh Isabelle Baillargeon-Radliff Morgan Kelly Patrick Rainwater Daniel Basargin Andrean Kusnetxov Filip Reutov Feodora Basargin Ulian Kuzmin Beverly Schindler Brandon Beachy Patrick Latimer Abby Vaz Brittany Craig Misael Martushev Zach Williams Axel Gillam Demetria Marwedel Ilarion Ivanov 5 Chapter One Dad was talking to Mom.
    [Show full text]
  • Issue 15 · July 2009
    The James Caird Society Newsletter Issue 15 · July 2009 Antarctic scientists map penguins from space Penguin guano stains, visible from space, have helped British scientists locate emperor penguin breeding colonies in Antarctica. Knowing their location provides a baseline for monitoring their response to environmental change. In a new study, published in the journal Global Ecology and Biogeography , scientists from British Antarctic Survey (BAS) describe how they used satellite images to survey the sea-ice around 90 per cent of Antarctica’s coast to search for emperor penguin colonies. The survey identified a total of 38. Ten of those were new. Of the previously known colonies six had re- located and six were not found. Because emperor penguins breed on sea-ice during the Antarctic winter little is known about their colonies. Reddish brown patches of guano on the ice, visible in satellite images, provide a reliable indication of their location. BAS mapping expert Peter Fretwell said: ‘We can’t see actual penguins on the satellite maps because the resolution isn’t good enough. But during the breeding season the birds stay at a colony for eight months. The ice gets pretty dirty and it’s the guano stains that we can see.’ Emperor penguins spend a large part of their lives at sea. During the Antarctic winter when temperatures drop to -50°C they return to their colonies to breed on sea-ice, but this is a time when it is most difficult for scientists to monitor them. BAS penguin ecologist Dr Phil Trathan said: ‘This is a very exciting development.
    [Show full text]
  • Climate Center Proposal, April 30, 2005 FIELD MEASUREMENTS OF
    Climate Center Proposal, April 30, 2005 FIELD MEASUREMENTS OF INHOMOGENEITY IN WIND TRANSPORT OF SNOW OVER ANTARCTIC SEA ICE: WHAT ARE APPROPRIATE AVERAGING LENGTHS AND TIMESCALES FOR MODELS? Katherine C. Leonard Email: [email protected] Advisors: Stan Jacobs (LDEO), Doug MacAyeal (University of Chicago), and Bruno Tremblay (McGill University and LDEO) An upcoming sea ice cruise on the RVIB Nathaniel B. Palmer provides a unique opportunity for winter-season measurements of spatial variability in drifting snow over Antarctic sea ice. Modeling studies of blowing snow are typically validated against profile measurements, but distributed measurements of drift heterogeneity have been hindered by the cost and scarcity of appropriate measurement devices. My recent identification and validation of an inexpensive commercially available device that can be used to measure wind-blown snow transport means this financial and technological roadblock can now be overcome. I propose to use a combination of existing and new equipment to set up a simple weather station and three masts with anemometers and snow drift sensors several meters apart on an ice floe during the drifting phases of the “Sea Ice Mass Balance of Antarctica” (SIMBA) cruise to the Amundsen Sea in September and October of 2007. RESULTS OF PRIOR SUPPORT Prior support from the LDEO Climate Center (“Blowing Snow Instrumentation Development for future Antarctic Field Deployment” to Leonard and Tremblay, $5000, awarded 12/2005) enabled the development and testing of photoelectric particle counters to measure windblown snow transport in unmanned weather station deployments in Antarctica. A combination of borrowed and purchased sensors were tested against one another and led to the identification of a low-cost commercially available device (officially an assembly line parts counter) which operates in a manner similar to the custom-built instruments typically used for this task (e.g.
    [Show full text]