DOCSLIB.ORG

Paul Whelan Map 1

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Paul Whelan Map 1 CANADA PHOTOGRAPHS of the HOH RAINFOREST WASHINGTON THREE SEASONS OF SELECTED IMAGES THROUGH THE EYES OF A PARK RANGER CARTOGRAPHY BY AND IMAGES FROM PAUL WHELAN One of the few remaining primeval forests, the Hoh Rain Forest offers a perspective on the cycle of life and death through the A FEW WORDS ABOUT THE PARK movement of nutrients from monolithic stands of old growth to wellsprings of nurse logs. Only with the falling of one of these The expanse of Olympic National Park encompasses a host of different landscape types and HOH RIVER TRAIL ELEVATION PROFILE enormous trees is enough sunlight available for new tree growth to occur, as this river valley has rarely seen a fire event. The majestic climatic regimes. Although the mountains are comparatively short when scaled against the Cascade Range, their position affords the peninsula a unique array of 4,300 ft Hoh River offers solace to its visitors and a glimpse at the pre-settlement condition of the unique and spectacular Olympic Peninsula. H O microclimates. On the west side of the park, temperate rainforests abound as the prevailing westerly winds (usually with a southerly 2,450 H L A K E T RA component) sweep moist air off the Pacific Ocean. These I L 600 precipitation rich clouds meet the west face of the 0 4.5 9 13.5 17.4 miles !\C Olympic Range and, via orographic lifting, dump !@ Olympus Guard Station !\B torrential rains on the Hoh, Queets and Quinault 50 Basins. Conversely, the east side of the park Miles O H R I L !@ H V A I exhibits starkly different characteristics. Hoh Ranger Station E R T R HOH LAKE TRAIL ELEVATION PROFILE Heavily glaciated during the Pleistocene OREGON Ice Age, these river valleys are riddled 4,210 ft with jagged peaks &steep side slopes. Due to the rain shadow cast by the 2,360 !\D Olympics, vegetative communities !\ E also vary distinctly from their west 610 side relatives. This rare composition 0 1.5 3 4.5 6.4 miles !\F of various climatic communities, with !\A gradually sloping river valleys in the N a t i o n a l P a r k B o u n d a r y Glaciar Meadows west and perilously steep gradients in £101 P !\G ¤ U P A D !@ Guard Station the east, make Olympic National Park E R O H R O H !\ a treasured heritage to all who visit. H CHARACTERISTICS of the HOH BASIN # River Length: 50 miles, Glacially Fed Mt. Olympus 7,980 ft Topographic Formation: Glacial & Fluvial Climatic Classification: Temperate Rain Forest Forest Type: Mixed Coniferous and Deciduous Forest Microflora: Wide Assortment of Ferns, Lichens & Mosses Megafauna: Roosevelt Elk, Black Bear, Cougar, Black-tailed Deer Average Annual Precipitation (Recorded at Hoh Ranger Station): 141- 165 inches Salmonid Stocks: Chinook, Coho, Chum, Steelhead, Bull Trout/Dolly Varden, Cutthroat Dominant Tree Species: Sitka Spruce, Western Red Cedar, Western Hemlock, Bigleaf Maple, Red Alder among others 0 2.5 5 Miles BRAIDED CHANNELS OF THE HOH DATA SOURCES - A majority of the data used in this project are courtesy of Western Washington University's Huxley Spatial Analysis WATERFALLS OFF PANIC PEAK (C) Taken near Olympus Guard Station, this shot (F) Taken from the Hoh River Trail, this shot MT. TOM WATERFALL ENTER WILDERNESS MISTY, GREEN HOH Institute, however other organizations and agencies contributed data sets. They include: Olympic National Park, Olympic National illustrates the typical behavior of this immense 0 2.5 5 Kilometers (B) Seen from the Hoh River Trail, (A) With the Entrance Station in the (D) On the Hoh River Trail, this shot of the highlights the rugged and steep topography water body in its lower reaches; slight a 3-mile trek from the parking foreground, the landscape seen as author depicts a typical day in the foggy, Forest, Washington Department of Transportation, Okanogan-Wenatchee National Forest, Mount Baker-Snoqualmie National Forest, that characterizes the upper extent of this meanders riddled with gravel bars lot affords a view of this cascade. you enter this unique sub-district plant rich temperate rain forest ecosystem. National Agriculture Imaging Program (NAIP), Washington State Department of Natural Resources and ESRI 2008. May 25, 2011 glacially carved valley. County Boundaries Indian Reservations ELEVATION PROFILE 8,000 feet Mt. Olympus 7,980 ft Major Highways National Forests 6,000 U Cape Flattery: 4,000 T N : Major Rivers National Parks Most Northwest Point I 2,000 in the Contiguous U.S. H T E 0 20 40 60 80 miles E D Trails Water Bodies S S MACAW T City Limits 2 - 15 16 - 30 31 - 45 46 - 60 61 - 90 91 - 120 121 - 180 181 - 240 241 - 300 301 - 360 0 2,000 4,000 6,000 8,000 INDIAN T A T RESERVATION R E S A o BATHEMETRY in FEET ELEVATION in FEET I f 112 T A 0 5 10 20 UV M C Miles E A O R N Kilometers I C A A O F D 0 5 10 20 A A C L J U OLYMPIC U F Y WILDERNESS A OZETTE N d e T M P I INDIAN S P S RESERVATION E S P N E G N I I Z H O O K Port Townsend UV113 UV112 E D U D ABOVE: THE ALPINE ZONE OF GLACIER MEADOWS C A D (G) Perched at the terminus of the Hoh River Trail, this image was taken in Glacier Meadows, a small treeless area at the foot of Mt. Olympus. Ozette KLALLAM U In the background is an anonomous and jagged range that flanks Mt. Olympus, often refered to by locals as the Range of the Gods. Lake INDIAN N C RESERVATION G e k Port Angeles E 20 N VU O a L D i s 101 E c ¤£ t o v C n S AS C e D R r e s c e r L U V E S Sequim y C R I O LEFT: GLACIER CREEK HEADWATERS B S R QUILEUTE a I (E) Exemplifying the origins of the glacially fed Hoh River, this image of the White Glacier on Mt. Olympus was taken from y V T INDIAN OLYMPIC NATIONAL the Hoh River Trail. Depicting the evolution of notable tributaries to the Hoh main stem, Glacier creek cascades down E RESERVATION R FOREST into this glacially carved valley, eventually forming into the characteristic braided morphology. I N A T BELOW: THE CEILING OF THE PENINSULA - MT. OLYMPUS F Forks (H) The highest point in the park, Mt. Olympus stands tall at 7,980 feet above sea level. In this image, taken from the lateral moraine, a host of different geographic features are visible. I OLYMPIC NATIONAL PARK From left to right: Glacier Pass; the expansive surface of Blue Glacier: West, East & Middle Peak; the bulging crown of Snow Dome. O ¤£104 N CLALLAM COUNTY E L I R W A JEFFERSON COUNTY A C H R I V E B O G I E L H L R R E A I V H OLYMPIC M O R NATIONAL C H I L A V FOREST E A R R Y I A N N B ELEVATION TRANSECT PATH FOR PROFILE A E ¤£101 Poulsbo B C R E O S OLYMPIC WILDERNESS O H O H I N D I A N V B 101 I A ¤£ RESERVATION R A R D R E N R I V W A T E T S VU3 A R E D C OLYMPIC E E O L O C C U T WILDERNESS H Q U E A H E MASON COUNTY R OLYMPIC T NATIONAL Y Bremerton FOREST A GRAYS HARBOR COUNTY lt S u . a Cushman n e u i k F N Q a o L r k 16 S VU k o Lake R k QUINAULT INDIAN o E m RESERVATION V i I s R OLYMPIC NATIONAL h L T U R A FOREST i N ¤£101 v I e U r Q.
Load more

Recommended publications
  • Geomorphic Character, Age and Distribution of Rock Glaciers in the Olympic Mountains, Washington
    Portland State University PDXScholar Dissertations and Theses Dissertations and Theses 1987 Geomorphic character, age and distribution of rock glaciers in the Olympic Mountains, Washington Steven Paul Welter Portland State University Follow this and additional works at: https://pdxscholar.library.pdx.edu/open_access_etds Part of the Geology Commons, and the Geomorphology Commons Let us know how access to this document benefits ou.y Recommended Citation Welter, Steven Paul, "Geomorphic character, age and distribution of rock glaciers in the Olympic Mountains, Washington" (1987). Dissertations and Theses. Paper 3558. https://doi.org/10.15760/etd.5440 This Thesis is brought to you for free and open access. It has been accepted for inclusion in Dissertations and Theses by an authorized administrator of PDXScholar. For more information, please contact [email protected]. AN ABSTRACT OF THE THESIS OF Steven Paul Welter for the Master of Science in Geography presented August 7, 1987. Title: The Geomorphic Character, Age, and Distribution of Rock Glaciers in the Olympic Mountains, Washington APPROVED BY MEMBERS OF THE THESIS COMMITTEE: Rock glaciers are tongue-shaped or lobate masses of rock debris which occur below cliffs and talus in many alpine regions. They are best developed in continental alpine climates where it is cold enough to preserve a core or matrix of ice within the rock mass but insufficiently snowy to produce true glaciers. Previous reports have identified and briefly described several rock glaciers in the Olympic Mountains, Washington {Long 1975a, pp. 39-41; Nebert 1984), but no detailed integrative study has been made regarding the geomorphic character, age, 2 and distribution of these features.
    [Show full text]
  • GLACIERS Glacial Ice Is One of the Foremost Scenic and Scientific Values of Olympic National Park
    OLYMPIC NATIONAL PARK Glaciers MOUNT OLYMPUS GLACIERS Glacial ice is one of the foremost scenic and scientific values of Olympic National Park. There are about sixty glaciers crowning the Olympics peaks; most of them are quite small in contrast to the great rivers of ice in Alaska. The prominent glaciers are those on Mount Olympus covering approximately ten square miles. Beyond the Olympic complex are the glaciers of Mount Carrie, the Bailey Range, Mount Christie, and Mount Anderson. In the company of these glaciers are perpetual snowbanks that have the superficial appearance of glacial ice. Because they are lacking in the criteria below, they are (aerial view) not true glaciers. True glaciers are structurally three layered bodies of frozen water. The top layer is snow; the middle neve, or mixed snow and ice; and the bottom layer is of pure ice, which is quite plastic in nature. Crevasses or deep cracks in the glaciers form as the ice is subjected to uneven flow over alpine terrain. Another structural feature is the bergschrund, which is a prominent crevasse-like opening at the head of the glacier where the ice has been pulled away from the mountain wall. The rate of glacial flow is quite variable, and Olympic glaciers are "slow-moving" in contrast to some in Alaska which occasionally move at the rate of several hundred feet per day for short periods of time. There is no great advance of Olympic glaciers today, but there is not a rapid melting back of the ice either. Forward surges in glacial flow often occur after a number of very heavy winters and cool summers, but such activity has been relatively infrequent with Olympic glaciers in recorded time.
    [Show full text]
  • Flow of Blue Glacier, Olympic Mountains, Washington, U.S.A.*
    Journa/ DiG/a ciD/OK)', Vol. 13, No. 68,1974 FLOW OF BLUE GLACIER, OLYMPIC MOUNTAINS, WASHINGTON, U.S.A.* By MARK F. MEIER, (U.S. Geological Survey, Tacoma, Washington g8408, U .S.A.) W. BARCLAY KAMB, CLARENCE R . ALLEN and ROBERT P. SHARP (California Institute of Technology, Pasaciena, California gl 109, U.S.A.) ABSTRACT. Velocity and stra in-rate patterns in a small temperate valley glacier display flow effects of channel geometry, ice thickness, surface slope, a nd ablation. Surface velocities of 20- 55 m /year show year­ to-year fluctuations of I .5- 3 m /year. Tra nsverse profiles of velocity have the form of a higher-order para bola modified by the effects of flow around a broad bend in the cha nnel, which makes the velocity profile asym­ metric, with maximum velocity displaced toward the outside of the bend. M arginal sliding rates are 5- 22 m/ year against bedrock a nd nil against debris. Velocity vectors diverge from the glacier center-line near the terminus, in response to surface ice loss, but converge toward it near the firn line because of channel narrowing. Plunge of the vectors gives an em ergence fl ow component that falls short of bala ncing ice loss by a bout I m /year. Center-line velocities vary systematically with ice thickness and surface slope. In the upper half of the reach studied , effects of changing thickness a nd slope tend to compensate, a nd velocities are nearly constant; in the lower half; the effects are cumula tive a nd velocities decrease progressively down-stream .
    [Show full text]
  • Development Team
    Paper No: 4 Environmental Geology Module: 07 Glaciers Development Team Prof. R.K. Kohli Principal Investigator & Prof. V.K. Garg & Prof. Ashok Dhawan Co- Principal Investigator Central University of Punjab, Bathinda Prof. R. Baskar, Guru Jambheshwar University of Paper Coordinator Science and Technology, Hisar Dr Anita Singh, Central University of Jammu, Jammu Content Writer Dr. Somvir Bajar, Central University of Haryana, Content Reviewer Dr B W Pandey, Department of Geography, Delhi University, Delhi Anchor Institute Central University of Punjab 1 Environmental Geology Environmental Sciences Glaciers Description of Module Subject Name Environmental Sciences Paper Name Environmental Geology Module Glaciers Name/Title Module Id EVS/EG-IV/07 Pre-requisites 1. Understand glacier and differentiate the different types of glaciers 2. Describe glacier formation and glacier movement Objectives 3. Understand glacial budget and mass balance 4. To study different types of glacier landforms Keywords Glacier, Calving, Ablation, Accumulation 2 Environmental Geology Environmental Sciences Glaciers Module 07: Glaciers Objectives 5. Understand glacier and differentiate the different types of glaciers 6. Describe glacier formation and glacier movement 7. Understand glacial budget and mass balance 8. To study different types of glacier landforms 7.1 Glacier Glacier is a mass of surface ice on land and formed by accumulation of snow. Glaciers flow downhill under gravity due to its own weight. Glaciers are maintained by accumulation of now and melting of ice. The melted ice discharged into the lakes or the sea. Glaciers grow and shrink in response to the climate change. Meier (1974) provided a definition of a glacier: “A glacier may be defined as a large mass of perennial ice that originates on land by the recrystallization of snow or other forms of solid precipitation and that shows evidence of past or present flow.
    [Show full text]
  • Variations of Blue, Hoh, and White Glaciers During Recent Centuries*
    VARIATIONS OF BLUE, HOH, AND WHITE GLACIERS DURING RECENT CENTURIES* Calvin J. Heussert LACIERS in the Olympic Mountains of western Washington, as elsewhere G inNorth America,enlarged in late-postglacialtime and attained positions from which they have receded conspicuously. Former locations of the ice are marked bymoraines and overridden surfaces whichthe regional vegetationis slowly invading. An examination of aerialphotographs' of glaciers on Mt. Olympus taken in 1939 and 1952 clearly reveals the progress of recession. In 1952 Blue and Hoh glaciers (Fig. 1) appear rather inactive whereas a photograph of Blue Glacier taken about the turn of the century (Fig. 2) shows an activelydischarging tongue, well in advance of its position in the early 1950's. About 1900 glaciertermini were nevertheless well behind positions reached when the ice stood farther down the valleys in past centuries. No written accounts or measurements are available from this pre-1900 period, although the ages of trees growing on moraines and outwashoffer the means for fixing positions of the glaciersduring the timebefore theearliest observations. The minimum periods elapsed since glaciers may have been even farther advanced are established by the ages of the oldest trees in the forests beyond the recent outermost limitsof the ice. A reconnaissance of Blue and Hoh glaciers and the vicinity of White Glacier was made during the 1955 summer, and the former limits of the ice were determined and dated. The purpose was to record the variations of Mt. Olympusglaciers so that the climate of thisregion during the last several centuries might be interpreted from these changes and compared with other localities where similar studies have been made.
    [Show full text]
  • Oxygenisotope Ratios in the Blue Glacier, Olympic Mountains, Washington, U.S.A
    JOVR•TALOF GEOPHYSXCALRESEARCH ¾OLV•fE 65, NO. 12 DaCEUSER1960 Oxygen-IsotopeRatios in the Blue Glacier,Olympic Mountains, Washington, U.S.A. i•OBERTP. SHARP,SAMUEL EPSTEIN, AND IRENE VIDZIUNAS Cal#ornia Institute ot Technology Pasadena, Calitornia Abstract. The mean per mil deviation from a standard (average ocean water) in the O•]O •e ratio of 291 specimensof ice, tim, snow, and rain from the Blue Glacier is --12A; extremes are --8.6 and --192. This is consistentwith the moist temperate climatological en- vironment. The 0•/0 •øratio of snowdecreases with declining temperature of precipitation, and it also decreaseswith increasingaltitude at 0.5/100 meters. Analysesof the three principal types of ice, coarse-bubbly,coarse-clear, and fine, composing lower Blue Glacier, show that ratios for coarse-clearice are generally lower and for fine ice they are mostly higher than the ratios for coarse-bubblyice. This indicates that the fine ice representsmasses of firn and snow recently incorporatedinto the glacier by filling of crevasses or by infolding in areas of severedeformation. Coarse-clearice massesmay representfragments of coarse-bubblyice within a brecciaformed in the icefall. Becauseof unfavorable orientation, these fragments could have undergone exceptional recrystallization with reduction in air bubblesand, possibly,a relative decreasein 0 TM. A longitudinal septurn in the lower Blue Glacier is characterized by higher than normal O•8]0•ø ratios. These valuesare consistentwith an origin for this feature involving incorporation of much surficial snow and firn near the base of the icefall. Samples from longitudinal profiles on the ice tongue suggestthat ice closeto the snout comesfrom high parts of the accumulation area.
    [Show full text]
  • Glaciers of North America—
    Glaciers of North America— GLACIERS OF THE CONTERMINOUS UNITED STATES GLACIERS OF THE WESTERN UNITED STATES By ROBERT M. KRIMMEL With a section on GLACIER RETREAT IN GLACIER NATIONAL PARK, MONTANA By CARL H. KEY, DANIEL B. FAGRE, and RICHARD K. MENICKE SATELLITE IMAGE ATLAS OF GLACIERS OF THE WORLD Edited by RICHARD S. WILLIAMS, Jr., and JANE G. FERRIGNO U.S. GEOLOGICAL SURVEY PROFESSIONAL PAPER 1386–J–2 Glaciers, having a total area of about 580 km2, are found in nine western states of the United States: Washington, Oregon, California, Montana, Wyoming, Colorado, Idaho, Utah, and Nevada. Only the first five states have glaciers large enough to be discerned at the spatial resolution of Landsat MSS images. Since 1850, the area of glaciers in Glacier National Park has decreased by one-third CONTENTS Page Abstract ---------------------------------------------------------------------------- J329 Introduction----------------------------------------------------------------------- 329 Historical Observations -------------------------------------------------------- 330 FIGURE 1. Historical map of a part of the Sierra Nevada, California ------ 331 2. Early map of the glaciers of Mount Rainier, Washington------- 332 Glacier Inventories -------------------------------------------------------------- 332 Mapping of Glaciers------------------------------------------------------------- 333 TABLE 1. Areas of glaciers in the western conterminous United States -- 334 Landsat Images of the Glaciers of the Western United States--------- 335 FIGURE 3. Temporal
    [Show full text]
  • Flow of Blue Glacier, Olympic Mountains, Washington, U.S.A.*
    Journa/ DiG/a ciD/OK)', Vol. 13, No. 68,1974 FLOW OF BLUE GLACIER, OLYMPIC MOUNTAINS, WASHINGTON, U.S.A.* By MARK F. MEIER, (U.S. Geological Survey, Tacoma, Washington g8408, U .S.A.) W. BARCLAY KAMB, CLARENCE R . ALLEN and ROBERT P. SHARP (California Institute of Technology, Pasaciena, California gl 109, U.S.A.) ABSTRACT. Velocity and stra in-rate patterns in a small temperate valley glacier display flow effects of channel geometry, ice thickness, surface slope, a nd ablation. Surface velocities of 20- 55 m /year show year­ to-year fluctuations of I .5- 3 m /year. Tra nsverse profiles of velocity have the form of a higher-order para bola modified by the effects of flow around a broad bend in the cha nnel, which makes the velocity profile asym­ metric, with maximum velocity displaced toward the outside of the bend. M arginal sliding rates are 5- 22 m/ year against bedrock a nd nil against debris. Velocity vectors diverge from the glacier center-line near the terminus, in response to surface ice loss, but converge toward it near the firn line because of channel narrowing. Plunge of the vectors gives an em ergence fl ow component that falls short of bala ncing ice loss by a bout I m /year. Center-line velocities vary systematically with ice thickness and surface slope. In the upper half of the reach studied , effects of changing thickness a nd slope tend to compensate, a nd velocities are nearly constant; in the lower half; the effects are cumula tive a nd velocities decrease progressively down-stream .
    [Show full text]
  • Accidents in North American Mountaineering
    Accidents in North American Mountaineering 2010 Avalanche, Underestimated Hazard, Poor Position Alaska, Deltas, Canwell Glacier About mid-day on February 27, we (author and two others) parked at Miller Creek and began skinning up through sustained high winds towards the terminus of the Canwell Glacier. While skinning on the flat river valley, occasional “whoomphing” was heard and remarked about with casual interest. At one point a very large portion of the snowpack settled, forming a crack that was visible in the horizontal snowpack. As we made our way up-valley, we began to speculate about an objective. There wasn’t a lot of snow on the ridges bordering the glaciers, so we easily settled on the one part of the slope that actually had reasonable snow-cover, on the south side of the ridge separating the Canwell from the Fels Glacier. As we approached, we realized that the slope was steeper than it looked, and one of us remarked that it looked dangerous and might not be a good idea to ski. But time for the ski was running short, and we just decided to go skin up for one hour and have a look at the slope more carefully. We agreed we would choose our route on an intermediate ridge, and the expectation was that good route choices would allow us to travel safely. We arrived at the terminus of the Canwell Glacier and started skinning up towards the ridge on our north side. The base of the slope was covered by a 70-cm thick, very loose, powdery snow-cover, which had some depth- hoar at the base.
    [Show full text]
  • Voice of the Wild Olympics, Winter 2014
    VOICE of the WILD OLYMPICS Olympic Park Associates Founded in 1948 Volume 22 Number 1 Winter 2013-2014 Contents Book Reviews: Ascendance 3 Katie Gale 11 Remembrances: 4 Patrick Goldsworthy Phil Zalesky Update: Wild Olympics Campaign 5 Ancient Temperate Rainforest in the South Quinault Ridge Proposed Wilderness, Olympic National Forest. Wilderness Gifts: Water 6 Photo from Wild Olympics Campaign Olympic National Park’s Vanishing Glaciers 7 Olympics Bill Introduced in Congress Citizen Science: Marmot Survey 8 Senator Murray and Representative Kilmer Update: Team Up to Protect Olympic Wildlands & Rivers Spotted Owls Decline 9 In January OPA joined conservationists Popular roadless areas that would receive OPA’s New Trustees 10 across the Northwest celebrating the intro- wilderness protection in the legislation include: duction of the Wild Olympics Wilderness Deer Ridge, Lower Graywolf, Upper Dunge- Celebrate and Wild and Scenic Rivers Act of 2014. ness, Mount Townsend North, Dosewallips Wilderness Act’s 50th The bill, similar to the one introduced and Jupiter Ridges, Mounts Ellinore and with Great Old Broads 10 by Senator Murray and Representative Washington, South Fork Skokomish River, Dicks in 2012, would permanently pro- Moonlight Dome, South Quinault Ridge, Rug- Federal Closures: tect more than 126,000 acres of new Impacts on Peninsula 11 wilderness in Olympic National Forest. ged Ridge, and Gates of the Elwha. OPA and In addition, it would also protect 19 Wild our sister conservation organizations have Poem: and Scenic Rivers in the national forest and been working to protect most of these areas Plunging into the Wild 12 the national park, the first ever designated for decades.
    [Show full text]
  • Paleoenvironmental Change on the Olympic Peninsula, Washington: Forests and Climate from the Last Glaciation to the Present
    Paleoenvironmental Change on the Olympic Peninsula, Washington: Forests and Climate from the Last Glaciation to the Present Daniel G. Gavin1, David M. Fisher1, Erin M. Herring1, Ariana White1, and Linda B. Brubaker2 1. Department of Geography, University of Oregon, Eugene, Oregon. 2. School of Environment and Forest Sciences, University of Washington, Seattle, Washington. FINAL REPORT TO OLYMPIC NATIONAL PARK Contract J8W07100028 March 13, 2013 Table of Contents Acknowledgements ......................................................................................................... vii 1. Introduction ....................................................................................................................1 1.1 Aims of this report ............................................................................................................... 2 2. The modern landscape of the Olympic Peninsula .......................................................5 2.1 Geography of the Olympic Peninsula and Olympic National Park ................................ 5 2.2 Regional climate on the Olympic Peninsula ...................................................................... 5 2.3 Indicators of recent climate change on the Olympic Peninsula ....................................... 7 2.4 Vegetation zones of the Olympic Peninsula and climate controls on forest vegetation . 9 2.4.1 Sitka Spruce Zone ......................................................................................................... 10 2.4.2 Western Hemlock Zone ...............................................................................................
    [Show full text]
  • THE MOUNTAINEER VOLUME XIX Number One December 15, 1926
    THE MOUNTAINEER VOLUME XIX Number One December 15, 1926 Olympic Peninsula PUBLISttEt> BY THE MOUNTAINJ!,ER.S INCOllPOI\ATED 5 EAT TL E WAS H I N Ci TON. COPYRIG-HT. 1.926 The Mounrtiinee-n IncorporareJ w��Ta.PtN ,afUNTING co .. .. Oii MARION. atATTl I'. The MOUNTAINEER VOLUME NINETEEN Number One December 15, 1926 Olympic Peninsula Incorporated 1913 Organized 1906 EDITORIAL BOARD, 1926 Winona Bailey Lulie Nettleton Arthur Gist Agnes E. Quigley :Mildred Granger C. F. Todd Else Hubert Mrs. Stuart P. Walsh Mrs. Joseph T. Hazard, Associate Editor: Subscription Price, $2.00 Per Year . �nnual (only) Seve11ty-fiYe Cents. Published by The Mountaineers I ncorPora ted Seattle, Washington Entered as �eeond-class matter, December 15, 1920, at the Postoffice at SeaHle, Washington, under the Act of ?.Iarch 3, 1879. WHITE GLACIER Thomas E. Jeter This glacier whose streams feed the Hoh River thousands of feet below lies on the north side of Mount Olympus. CONTENTS Page Greetings ·····----------------------------------·--------·--·······Vilhjalmur Stefansso11 1926 Summer Outing in the Olympics............ Edmond S. Meany,],·..... 7 Down the Quinault River (Poem) ................Edmond S. Meany..... .... 19 Short Hikes in the Olympics............ ................ Ronald R. Ruddi111a11. 21 Some Unexplored Sections of the Olympics.... Theodore C. Lewis........ 25 Making the Olympics Accessible. .............. ......Frank H. Lamb....... 27 A Horne in the Olympics.......................... .....Margaret McCamey 30 Kidnaping in the Olympics.............................. Doris Huelsdonk .... 34 From the Leader of the Press Expedition ........J. H. Christie.......... 37 Summer Outing of 1927 ................... ............._F. B. Farquharson. 40 In Memoriam --------··-··········------·······················Edmond S. Meany.... 41 Members of the 1926 Summer Outing .................................... 42 Mountaineer Activities (Pictures)......... ........................................ 43 Our Forest Theatre.................................
    [Show full text]