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Shining Big Sea Water: The Story of Lake Superior
Shining Big Sea Water: The Story of Lake Superior
Shining Big Sea Water: The Story of Lake Superior
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Shining Big Sea Water: The Story of Lake Superior

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In Shining Big Sea Water, historian Norman K. Risjord offers a grand tour of Lake Superior's remarkable history, taking readers through the centuries and into the lives of those who have traveled the lake and inhabited its shores.

Through lively, informative chapters, Risjord begins with the lake's cataclysmic geological birth, then explores the lives of native peoples along the shore before European contact and during the fur trade, showing how Superior functioned as an unusual "blue water highway" for Indians, early explorers, industries, and settlers. He outlines the development of such cities as Sault Ste. Marie, Michigan; Ashland, Wisconsin; and Two Harbors, Minnesota, and tells the fascinating histories of life-saving lighthouses and famous shipwrecks. In the final chapter, Risjord looks to the future, offering a clear-eyed account of the environmental and economic challenges faced by America's largest freshwater lake.

Interspersed throughout the book are handy tips for travelers, highlighting historically significant sites that illustrate key pieces of Lake Superior's natural and human history, including national lakeshores in the United States and provincial parks in Canada.
LanguageEnglish
Release dateJul 24, 2009
ISBN9780873517515
Shining Big Sea Water: The Story of Lake Superior
Author

Norman K. Risjord

Norman K. Risjord is the author of several books, including Wisconsin: The Story of the Badger State. He is professor emeritus of history at the University of Wisconsin-Madison.

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    Shining Big Sea Water - Norman K. Risjord

    CHAPTER ONE

    OF BEDROCK AND ICE

    RisjordCh1.tif

    LAKE SUPERIOR, the largest freshwater lake in the world, displays its geological past to good effect. Its irregular shoreline of bays, inlets, and peninsulas; the colorful palisades of rock on Ontario’s north shore; and Michigan’s dramatic Au Sable Dunes are footprints from the march of time.

    Billions of years ago, the earth was a mixture of water and rocky landmasses that were proto-continents or what geologists call cratons. The cratons were rooted in the earth’s mantle (the superheated rock between the crust and the molten core), and parts of them periodically sank into the mantle to be metamorphosed with the addition of new elements, such as nickel, cobalt, and magnesium. One of these cratons, formed about 2.5 billion years ago, extended from present-day Greenland, across eastern Canada, and as far as central Michigan, Wisconsin, and Minnesota. Known as the Canadian Shield, this mass of granitic bedrock can be seen today in the cliffs along Lake Superior’s north shore or where it has been scraped bare by the glaciers of the past two million years.

    Rooted in the unstable magma, the cratons moved around over millions of years due to plate tectonics. Shortly after the Canadian Shield was formed, it collided with other cratons, creating a supercontinent that included northern Asia and much of today’s Europe. About 2.1 billion years ago the North American craton fragmented along a line that roughly parallels the south shore of present-day Lake Superior and the north shores of lakes Michigan and Huron. The seas swept in, and for several million years Wisconsin and Michigan lay under water. The lands around this arm of the sea—still without vegetation—eroded, and sand was washed into the shallow water, accumulating in some places to a depth of several hundred feet. Under heat and pressure it hardened into sandstone; if the folds of the earth brought it closer to the hot magma, it solidified into quartzite. When the land rose out of the water (due to another craton collision), the newly fashioned sedimentary rock formations emerged. The sandstone can be seen today in the red cliffs at the tip of the Bayfield Peninsula, and it is the basic rock of the Apostle Islands. The quartzite hills around Marquette, Michigan, are remnants of the metamorphosed sandstone.

    The sedimentary rocks that materialized from the shallow sea in northern Michigan, Wisconsin, and Minnesota contained large deposits of iron ore. The origin of this ore remains somewhat a mystery. Ore-bearing sediments accumulated around the world at the same time, about two billion years ago. There are no iron ore deposits from an earlier or a later period. The best explanation for this phenomenon is the presence, for the first time, of oxygen in the atmosphere. Single-celled plants had appeared almost as soon as the oceans were formed, and these blue-green algae were capable of photosynthesis, the process of converting the atmosphere’s carbon dioxide into free oxygen. The oxygen joined nitrogen in the atmosphere and was dissolved into the ocean. Iron is quite soluble in oxygen-deficient waters and would have been present in large quantities in the earliest oceans. With the oxygen it formed ore compounds—hematite, pyrite—that are insoluble. The precipitates collected in depressions at the bottom of the sea and later emerged as iron ranges in Michigan, Wisconsin, and Minnesota.

    1-1picturedrocks.tif

    The picturesque markings of Michigan’s Pictured Rocks are created by mineral-rich water seeping through cracks in the sandstone cliffs. Wave action has bored caves in the softer sandstone. The layers were created by the interaction of land and water billions of years ago.

    About 1.8 billion years ago a craton drifted up from the south (possibly after splitting off from Africa) and collided with the Canadian Shield craton, forming an arc from southern Ontario across northern Michigan and Wisconsin and southwest to the Minnesota-Iowa border. The intruding craton slipped under the Canadian Shield, creating an enormous volcanic uplift which, after eons of weathering and erosion, can be seen today in Iron Mountain, Michigan, and the Northern Highland of Wisconsin. Geologists believe this ancient mountain range might, at one time, have been as high as the present Rockies.

    The final chapter in the geological formation of the basin that would become Lake Superior was a cataclysmic event that began about 1.1 billion years ago and ended a hundred million years later. It began with a rift in the landmass that had become the continent of North America. The break—resembling the continental rift in East Africa today—was several hundred miles wide and in the shape of an arc with the pinnacle being the basin of Lake Superior. One arm stretched southwest down the St. Croix valley, across Minnesota and Iowa, and into central Kansas. The other arm reached across Michigan and ended near its border with Ohio. Basaltic lava spewed to the surface along this rift and pillowed in some places to a height of one or two miles. Toward the end of this volcanic period the land that is now the Lake Superior basin subsided, but several spectacular features remained: the basaltic ridge known as the Keweenaw Peninsula of Michigan and the basalt cliffs along the northwest shore of the lake from Duluth to Grand Marais. Other remnants are Isle Royale and the Sleeping Giant on Thunder Bay, its eight-hundred-foot sheer cliff the highest on the north shore.


    VISITING HISTORY

    Red Cliff (Ojibwe) Indian Reservation (Highway 13 north of Bayfield, Wisconsin) features immense cliffs of red sandstone on the lake’s shore.

    Ouimet Canyon Provincial Park (Highway 11/17 about forty miles east of Thunder Bay, Ontario) encloses a five-hundred-foot-deep canyon that provides a spectacular view of the billion-year-old Laurentian Shield.

    The North Shore Drive (Duluth to Two Harbors, Minnesota), a National Scenic Byway, is an alternative to four-lane Minnesota Highway 61. In addition to beautiful vistas of the lake, the byway features the North Shore’s ancient basalt formations. The scenic drive can be continued on Highway 61 from Two Harbors to Grand Portage.

    The Sleeping Giant (Highway 11 and Ontario 587, Thunder Bay, Ontario) is a basalt rock formation on the Sibley Peninsula that forms the eastern side of Thunder Bay. It is part of a one-hundred-square-mile Natural Environment Park whose Visitor Center and a two-hundred-site campground are on Marie Louise Lake, the largest of several glacial remnants on the peninsula.


    Copper deposits were another remnant of the Keweenawan eruption. As the lava cooled and fissured, superheated water brought copper and nickel sulfides to the surface, and the solutions settled into crevices of the cooling rocks. The most important deposits were on the Keweenaw Peninsula and on Isle Royale. Although much of the copper was in the form of an ore (with oxygen and sulfur), nodules of almost pure copper were left on the surface, particularly on the Keweenaw. Lake Superior agates were another product of the volcanic eruption. As the lava cooled, silica and iron oxides washed into cavities in the basaltic rock. Variations in the amount of iron and silica released at any one time produced the banded layering that makes agate one of the loveliest of semiprecious stones.

    1-2.tif

    The sleeping giant rock formation at the tip of Sibley Peninsula, Ontario, was created by basaltic lava during the Earth’s distant past. From right to left: the giant’s head, Adam’s apple, chest, waist, and knees. In the foreground is Marie Louise Lake, one of Glacial Lake Superior’s many remnants on the Sibley Peninsula.

    About 570 million years ago, the southern half of the North American continent sank once again under the sea. Water covered present-day Michigan and the eastern corner of Lake Superior. The rest of the future lake bed, the northern half of Wisconsin, and nearly all of Minnesota remained above water, although the landscape was still barren. The continent straddled the equator at that time, with today’s Thunder Bay crossed by that imaginary line, and the warm seas swarmed with the first animals—worms, snails, and, most abundantly, crablike creatures only an inch or so in size, trilobites. By the time the seas retreated for the last time about 250 million years ago, ferns and mosses covered the land, insects had made their appearance, and reptiles including dinosaurs had begun to evolve.

    While the seas were advancing and retracting throughout this three-hundred-million-year period, the North American tectonic plate collided with the Eurasian one, creating a supercontinent (Gondwanaland), which allowed the intercontinental exchange of animals, including dinosaurs and the first mammals. The supercontinent began to break up about two hundred million years ago, and a narrow Atlantic Ocean separated Europe and America by about one hundred million years ago.

    Grasses made their appearance about this time, and the basin that would become Lake Superior was probably a grassy plain surrounded by the highlands created by the Keweenawan eruption. The basin drained into a northward flowing river that led ultimately to the Arctic Ocean. Until two million years ago, when the most recent glacial age, the Pleistocene, began, the climate of North America was much warmer than at present, and its woods and grasslands sustained an abundance of animal life. Horses, which originated in North America, were common, and they shared the prairies with mammoths, camels, an ancestor of the rhinoceros, and various carnivorous predators, including the famed saber-toothed tiger. All of these large animals would become extinct toward the end of the Ice Age, though some, like the horse and the camel, would migrate to Asia before their relatives in North America vanished.

    The Wisconsin Glacier

    According to geologists, although numerous glacial advances occurred in North America over the last two million years, the one responsible for the birth of Lake Superior was the most recent one, called the Wisconsin glaciation because of its impact on the topography of the Badger State. Many theories set out the causes of glaciation. The movement of tectonic plates (South America separated from Africa and joined the New World at the beginning of this period, 2.5 million years ago) affected oceanic thermal currents and thus caused major shifts in weather patterns. Changes in the earth’s elliptical orbit around the sun may have been a contributing factor. North America became particularly vulnerable to the ice sheets as the Earth’s axis tilted and the equator moved south to its present position, leaving two-thirds of the continent north of the 45th parallel.

    Glaciation_Map.tif

    The glaciers that covered the region that would become Lake Superior extended as far south as today’s central Iowa and Illinois but bypassed a large segment of Wisconsin.

    When the climate cooled, winter snows in the Arctic failed to melt in the summer, and the snow accumulated year after year, century after century. The Wisconsin glaciation originated in two highlands, east and west of Hudson Bay, about seventy thousand years ago. At these centers, the snow eventually reached a height of almost two miles. Under this immense weight, the bottom layers recrystallized to form ice, which oozed and flowed with the incline of the land. When the two ice sheets joined, their weight was such that it dented the earth’s crust, allowing the ocean to enter Hudson Bay after the ice melted. New snows replenished the mass, and the wall of ice crept south at a rate of about two hundred feet each year.

    The moving ice gathered everything in its path, from giant boulders to sand and gravel. The debris added to the scouring effect, and the earth was laid bare to the bedrock of the Canadian Shield. When the advancing ice reached the wooded valley between the Minnesota and Wisconsin highlands, it split into lobes that followed ancient rifts and rivers. One lobe moved westward and plowed out the basin that would become Lake Superior. Another lobe moved southward along a river valley that would develop into Lake Michigan. Since much of the Lake Superior lowland consisted of sand and gravel that had eroded from the Wisconsin and Minnesota highlands, the glacier was able to plow deeply, gouging a lake bed that would reach seven hundred feet below sea level. (Lake Superior today reaches a depth of 1,300 feet.) For several thousand years, the Wisconsin highlands acted as a dam that prevented further movement to the south. As a result, the Superior ice lobe pushed westward into central Minnesota, where it halted when the climate began to warm.

    1-4LakeTerraces.tif

    J. Elliot Cabot’s 1848 sketch Lake Terraces makes visible the different levels of lakeshore as Lake Minong receded to present Lake Superior.

    The eastward lobe split into the Green Bay and Lake Michigan lobes, the first covering eastern Wisconsin, the second reaching into northern Illinois. To the south of these lobes, a tundra of moss and spruce parkland stretched to the Ohio River. Beyond, a spruce forest reached almost to the Gulf of Mexico, where it yielded to deciduous hardwoods.

    The earth’s climate began to warm again about eighteen thousand years ago. The ice halted its advance and began a stutter-step retreat from the Superior basin that lasted for another eight thousand years. The rock and gravel it had gathered was left in a succession of moraines and oblong hills called drumlins. The western half of Lake Superior was free of ice about thirteen thousand years ago and created in northern Wisconsin and northeastern Minnesota a glacial lake slightly larger than Lake Superior’s current size. It drained south through the St. Croix valley, joining the re-forming Mississippi River west of the current Twin Cities. Lake Superior was completely ice free by about twelve thousand years ago, and the St. Marys River sent its waters south and east into lakes Huron and Michigan. As the glaciers gained ground about five hundred years later, the Superior basin refilled with ice, which stayed for perhaps another fifteen hundred years. Once again ice free by about ten thousand years ago, the upper Great Lakes formed a giant freshwater sea that drained eastward through the Ottawa River and later southward into the present-day Chicago and Illinois rivers. And then, some two thousand years ago, bedrock rebounded at Sault Ste. Marie to separate Lake Superior from Lake Huron, and the contours of the present Great Lakes emerged.

    In the wake of retreating ice, an arctic tundra comprising mosses, arctic grasses, dwarf birch, and willow covered the land. Spruce rapidly replaced the tundra and dominated the western shores of Lake Superior by about eleven thousand years ago. Large mammals including the woolly mammoth, the musk ox, and the caribou, able to withstand the cold, had moved onto the tundra even before the boreal forest appeared. As the climate continued to warm, spruce were forced north; white pine and then hardwoods such as birch, maple, and oak crept onto the shores of the great inland sea. About five thousand years ago the climate cooled to its present state, and spruce eventually dominated once again the

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