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The Archaeoclimatology Atlas of Oregon: The Modeled Distribution in Space and Time of Past Climates PDF

345 Pages·2009·23.23 MB·English
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Archaeoclimatology Atlas of Oregon The Modeled Distribution in Space and Time of Past Climates Reid A. Bryson, Katherine McEnaney DeWall, and Alison Stenger The Archaeoclimatology Atlas of Oregon Archaeoclimatology Atlas of Oregon The Modeled Distribution in Space and Time of the Past Climates of Oregon Reid A. Bryson, Katherine McEnaney DeWall, and Alison Stenger The University of Utah Press Salt Lake City Copyright © 2009 by The University of Utah Press. All rights reserved. All rights reserved. Except as permitted under the U.S. Copyright Act of 1976, no part of this publication may be reproduced, distributed, or transmitted in any form or by any means, or stored in a database or retrieval system, without the prior written permission of the publisher. The Defiance House Man colophon is a registered trademark of the University of Utah Press. It is based upon a four-foot-tall, Ancient Puebloan pictograph (late PIII) near Glen Canyon, Utah. 12 11 10 09 08 1 2 3 4 5 ISBN: 978-0-87480-926-8 (paper) ISBN: 978-1-60781-953-0 (ebook) Library of Congress Cataloging-in-Publication Data Bryson, Reid A. The archaeoclimatology atlas of Oregon : the modeled distribution in space and time of the past climates of Oregon / Reid A. Bryson, Katherine McEnaney DeWall, and Alison Stenger. p. cm. Includes bibliographical references and index. ISBN 978-0-87480-926-8 (paper) ISBN 978-1-60781-953-0 (ebook) 1. Paleoclimatology—Oregon. 2. Oregon—Climate. 3. Human beings—Effect of climate on—Oregon. 4. Human ecology—Oregon—History. I. DeWall, Katherine McEnaney. II. Stenger, Alison. III. Title. QC884.5.O7B79 2009 551.69795—dc22 2009003743 Contents Publisher’s Note vi The Ochoco–Blue Mountains Ridge: Austin, Ironside, Section A n climatology for the Field Scientist John Day, Mitchell, Paulina, Prineville, and Chapter 1. Archaeoclimatology: An Introduction 3 Seneca 175 Chapter 2. Statewide Climate Mapping 11 The Northeast: Baker, Elgin, La Grande, Ukiah, and Wallowa 201 The High Desert: Bend and Brothers 221 Section B n Western oregon Chapter 3. Case Study: Salem 17 Section D n the interior Basin Chapter 4. Case Study: The Portland Basin and Lake River Region 21 Chapter 8. Case Study: Diamond Pond, Voltage 231 Chapter 5. Models for Western Oregon 27 Anthony H. Ruter and Reid A. Bryson The Northwest Coast: Clatskanie, Nehalem, Chapter 9: Models for the Interior Basin 235 Newport, Seaside, St. Helens, Summit, The Western Great Basin: Adel, Chemult, Fremont, and Tillamook 29 Klamath Falls, Malin, Paisley, Sprague River, The Southwest: Ashland, Brookings, Coquille City, and Valley Falls 236 Fern Ridge Dam, Gold Beach, Grants Pass, The Eastern Great Basin: Alkali Lake, Beulah, Burns Honeyman, and Roseburg—48 Junction, Burns WSO, Hart Mountain Refuge, The Portland Basin: Portland 75 McDermitt, Owyhee Dam, P Ranch Refuge, The Willamette Valley: Corvallis, Eugene, McMinnville, Riverside, Sheaville, Vale, and Wagontire 264 North Willamette Experiment Station, and Stayton 79 Section e n Storms and Rivers The Cascades: Bonneville Dam, Cascadia, Cottage Grove Dam, Crater Lake, Detroit Dam, Idleyld Chapter 10. Typhoons and the Middle Park, Lost Creek Dam, McKenzie Bridge, Holocene 311 Odell Lake East, and Three Lynx 98 Chapter 11. Case Study: River Modeling near Woodburn 317 Chapter 12. Modeled River Discharge 323 Section c n the columbia Plateau and Valleys Deschutes at Mecca, John Day at McDonald Ferry, Chapter 6. Case Study: Wildcat Canyon, Molalla at Wilhoit, Owyhee at Rome, Rogue Arlington 139 at Agness, Umpqua at Elkton, Willamette Chapter 7. Models for the Columbia Plateau and at Portland, and Willamina Creek at Valleys 145 Willamina 324 The Plateau: Antelope, Dufur, Heppner, Kent, Metolius, Mikkalo, Monument, and Epilogue 333 Pendleton 146 References 335 Publisher’s Note Seventy-two full-color, supplemental spatial maps not included in the printed volume may be accessed free of charge at the University of Utah Press Web site, www.Uof Upress.com. Please look for the link to the maps on the book’s main page. Available supplemental spatial maps in- clude precipitation, annual temperature, evaporation, pre- cipitation minus evaporation, and snowfall in increments every 1,000 rcybp, from 13,000 rcybp to the present. Section A Climatology for the Field Scientist This book is not a definitive treatment of the past cli- mates of the state of Oregon, nor is it so intended. We present here a set of robust hypotheses of what the climate might have been at various places at various times, especially in the Holocene climatic time. The method by which this climatic past was calculated was developed specifically for the use of field scientists such as archaeologists, ecologists, and geomorphologists. The first section of the Atlas (A) provides the cli- matic and scientific foundations of the climatic model used and an overview of the general climatic peri- ods in Oregon. The next three sections (B–D) divide the state of Oregon into three major climatological and topographic areas. Each section begins with one or two case study applications of the model to spe- cific sites and questions in Oregon. The final section (E) presents case studies and models for storms and riv- ers. Each section also contains a chapter of model out- put graphs for each individually modeled site within the state so that researchers can apply the model out- put to their specific area(s) of interest. The Atlas seeks to demonstrate the range of potential utility of Macro- physical Climate Modeling (MCM) for archaeological, environmental, and climatological questions about Or- egon’s past. Users may calculate similar models for any place in the world for which modern calibration data are available—on their own personal computer (Bry- son and DeWall, ed. 2007). We hope they will. 1 Archaeoclimatology: An introduction Archaeoclimatology, also called Macrophysical Climate theory is approached. Such definitions suggest that cli- Mo del ing (MCM), was developed in the mid-1990s by mate does not have a body of theory distinct from that of Reid A. Bryson and Robert U. Bryson as an alternative to weather, but atmospheric scientists disagree. iterative general circulation models (GCMs) to produce Climate cannot be viewed as simply a statistical sum- results at a spatial and temporal scale useful for a variety of mary of the daily weather; this definition is not functional social, natural, and earth sciences. Unlike the wide assort- even within meteorology. Any experienced meteorolo- ment of GCMs in the literature, MCM takes a top-down, gist can identify the atmospheric circulation pattern on a rather than bottom-up, approach to model building. This weather map immediately as a summer pattern or a win- chapter provides the basic meteorological knowledge nec- ter pattern. This is possible because the array of character- essary to understand and successfully interpret the model istic weather patterns differs from one season to another, and its results. Additional technical details about the con- as a result of the climate differing from season to season. struction of the model are available in the published lit- To understand this statement, we must understand that erature. For a comprehensive overview, please refer to climate is a boundary condition problem: the dynamic Bryson (2005) and Bryson and DeWall (ed. 2007). For status of the earth-atmosphere system determines the more detailed descriptions of various components, refer array of possible weather patterns. The “climate as average to Bryson (1988, 1989, 1992), R. A. Bryson and R. U. Bry- weather” view assumes the opposite: that climate is deter- son (1997b, 2000), Bryson et al. (2006), and Bryson and mined by whatever weather there happened to be. “These Goodman (1986). ‘boundary conditions’ force the state of the climate sys- tem, which in turn produces and requires sets of weather complexes, which differ as the climate differs from one the Definition of climate: time to another” (R. U. Bryson and R. A. Bryson 1997:3). Basic Meteorological concepts This changing status (and the resulting weather patterns) The Oxford English Dictionary (second edition, 1989) de- is what constitutes the climate. Such a top-down approach fines climate as “the condition (of a region or country) (from the climate and boundary conditions to the possi- in relation to prevailing atmospheric phenomena, as tem- ble weather patterns) is the foundation of what is called perature, dryness or humidity, wind, clearness or dullness synoptic (or large-scale) climatology. of sky, etc., esp. as these affect human, animal, or vegetable life.” For meteorologists, a commonly cited definition is centers of Action, now and in the Past that of the Glossary of Meteorology: climate as “the synthe- sis of the weather” (Huschke 1959). For geographers, the The term “centers of action” was created by Teisserenc de classical definition is similar: “Climate … refers to a more Bort (1883) to define the mean centers of high and low enduring regime of the atmosphere; it is an abstract con- sea-level pressure that “represent the principal circulation cept. It represents a composite of the day-to-day weather features that help determine mid-latitude weather and conditions, and of the atmospheric elements, within a wind systems” (Barry and Carleton 2001:209–210). These specified area over a long period of time” (Trewartha and centers of action are the boundary conditions referred to Horn 1980), or “climate is the sum total of the weather ex- above that define the climate and determine the potential perienced at a place in the course of the year and over the weather patterns. These centers are also referred to as sub- years” (Lamb 1972). These views see climate as essentially tropical highs. The jet stream and Intertropical Conver- a summation of the weather (or average weather), and gence (ITC, sometimes erroneously called the Intertropi- this viewpoint has profound implications for how climate cal Convergence Zone, or ITCZ) also determine weather 3

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