Winter world The ingenuity of animal survival

Bernd Heinrich, 1940-

Book - 2003

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Subjects
Published
New York, NY : Ecco c2003.
Language
English
Main Author
Bernd Heinrich, 1940- (-)
Edition
1st ed
Physical Description
347 p. : ill. ; 24 cm
Bibliography
Includes bibliographical references.
ISBN
9780061129070
9780060197445
Contents unavailable.
Review by Booklist Review

The ways animals cope during cold winter months are highlighted in this new title from Bernd Heinrich, the award-winning author of Mind of the Raven (1999), physiological ecologist, and professor at the University of Vermont. Some animals, such as voles, stay awake all winter in tunnels and grassy nests built under the snow. Other small mammals, such as chipmunks and ground squirrels, spend winter hibernating. Some insects supercool through chemicals in their blood that inhibit freezing, while others do the opposite and survive by promoting self-freezing. Many other animals remain active all winter and retire to warm nests or dens when not seeking food. Heinrich is a graceful writer, taking the reader along as he uncovers aggregations of wintering bugs, follows a weasel's tracks in the snow, or watches the tiny kinglets fluff their feathers for insulation as they search for wintering caterpillars. Liberally illustrated with the author's pencil drawings, this title will be sought out by fans of good nature writing. --Nancy Bent

From Booklist, Copyright (c) American Library Association. Used with permission.
Review by Publisher's Weekly Review

How do bears, bees, frogs and other creatures stay alive in a barren, subzero landscape? A veteran natural history author and University of Vermont biology professor, Heinrich (Mind of the Raven) uses the New England winter as a laboratory for investigating the adaptability and evolution of animals. In short, dense, lucid chapters that will intrigue both natural history buffs and neophytes, Heinrich discusses the survival strategies-such as hibernation and nest building-of mammals, birds and reptiles. He shows how bears endure months of hibernation without losing muscle mass or bone density, how an air-breathing snapping turtle survives six months at the bottom of a frozen pond and how honeybees keep the temperature in their hives at a balmy 36 degrees Celsius no matter how cold it is outside. The narrative is full of exuberant first-person observations from Heinrich's walks through the Maine and Vermont woods ("I hit the tree with an ax. One flying squirrel with huge black eyes and soft gray pelage popped its head out.... After I started to climb the tree I saw three heads looking out. No-it was four!"), and he reflects on such subjects as the ethics of hunting and the implications of animal survival strategies-particularly the bear's ability to stay in shape without exercise-for human health. Throughout the book, Heinrich returns to the example of the mysterious golden-crowned kinglet, a bird whose tiny body-not much bigger than a walnut-loses heat so quickly that it seems to defy the rules of winter survival, and whose perseverance symbolizes the improbable, miraculous feats of endurance of all the animals of the north. Nature lovers will delight in this lively, fascinating study. (Jan.) (c) Copyright PWxyz, LLC. All rights reserved

(c) Copyright PWxyz, LLC. All rights reserved
Review by Library Journal Review

This account of how wild animals survive in cold winters is based in large part on the writer's own astute observations of the behavior of a variety of species of birds, squirrels, mice, insects, and other creatures. Heinrich (biology, Univ. of Vermont; Mind of the Raven) has a cabin and property in the Maine woods, which often serves as a living laboratory for him and his students. One of his special interests, which he discusses at length here, is how the tiny golden-crowned kinglet, a bird not much larger than a hummingbird, survives the long, harsh winters of New England. Heinrich is constantly observing and asking questions about what he sees, giving readers an inside glimpse at the workings of science and nature. At times, he also relates the research of other scientists, always in understandable English. A more scholarly, less personal treatment of this subject is provided by Peter J. Marchand's Life in the Cold: An Introduction to Winter Ecology, now in its third edition. Heinrich's book is recommended for public and undergraduate college libraries.-William H. Wiese, Iowa State Univ. Lib., Ames (c) Copyright 2010. Library Journals LLC, a wholly owned subsidiary of Media Source, Inc. No redistribution permitted.

(c) Copyright Library Journals LLC, a wholly owned subsidiary of Media Source, Inc. No redistribution permitted.
Review by Kirkus Book Review

An array of ways to beat the cold when central heating isn't an option, from National Book Award nominee Heinrich (Racing the Antelope, 2001, etc.). The cleverness of evolutionary design is everywhere on display in this look at how animals cope with winter. Like the good teacher he must be at the University of Vermont, Heinrich takes pains to be clear, laying a groundwork of information for what follows. He starts at the molecular level, explaining the properties of water and the difference between heat and temperature, then providing an outline of various life-maintenance techniques used by creatures from insects to bears--methods that include aestivation and brumation, freezing point depression, antifreeze, ice-nucleation sites, thermal hyteresis, and supercooling, all allowing these organisms to survive the "regularly occurring famine" that winter brings on its heels. Heinrich's description of snow's thermal qualities makes it understandable that a broad range of animals use it for insulation, but what he clearly delights in are the startling discoveries resulting from fieldwork undertaken by both himself and others. We learn about the differing bill morphologies of birds, about the spring peepers and chorus frogs that freeze solid after suffusing their cells with glucose, the arctic ground squirrels that heat up from their torpor to get a little REM sleep, and the chronobiology of flying squirrels as they set their internal clocks without external cues. There's the role of camouflage, as in the weasel turning white, and the unique architecture of birds' nests ("the more different or exotic the nest appearances there are for different species, the less any one would stand out to predators"), not to mention the many insects, whose "success is derived from exploiting individual specificity." Heinrich relates each creature's method as a story, slowly revealing its canny, outrageous, or dumbfounding aspects--letting the reader sit back and marvel. The stories are plain engrossing--in their elucidation, their breadth of examples, and their barely contained sense of awe and admiration. (Drawings throughout)

Copyright (c) Kirkus Reviews, used with permission.

Winter World The Ingenuity of Animal Survival Chapter One Fire and Ice Microscopic life evolved some 3.5 billion years ago in the Precambrian period during the first and longest chapter of life that covers about 90 percent of geological time. No one knows exactly what the earth was like when microbial life began but we do know that at some time the earth was a hot and hellish place with an atmosphere that lacked oxygen. Early microbes, probably bluegreen algae or bacterialike organisms, invented photosynthesis to harness sunlight as a source of energy. They took carbon dioxide out of the air as their food, and they generated oxygen as a waste product that further transformed the atmosphere and hence the climate. They developed DNA for storing information, invented sex, which produced variation for natural selection, and evolution took off on its unending and largely unpredictable course. Molecular fingerprinting suggests that every life-form on earth today originated from the same bacterialike ancestor. That ancestor eventually led to the three main surviving branches of life, the archaea, bacteria, and the eukaryotes (the organisms made of cells with a nucleus that include algae, plants, fungi, and animals). Remnants of the first ancient pre-oxygen-using life may still exist little-changed today. They are thought to be sulphur-consuming bacteria now living only in the few remaining places where the ancient and to us hellish conditions still remain. These habitats include hot springs and deep oceanic thermal vents where water at 300°C (that stays liquid there rather than turning to steam because it is under intense pressure in depths of some 3,600 meters) issues up from the ocean floor. One of the species living at the edge of these hot water vents is Pyrolobus fumarii , which can't grow unless heated to at least 90°C, and which it tolerates 113°C. As the earth cooled new environments became available and new single-celled and then multicelled organisms evolved from these or similar species to invade ever-new and cooler environments. Some cells much later also escaped their ancestral conditions by invading other cells, finding that environment conducive for survival and adapting to it. Such initially parasitic organisms ultimately evolved into cooperative or symbiotic relationships with their hosts. Perhaps the most fateful of these eventually mutually beneficial associations occurred when some Precambrian green algae successfully grew inside other cells, to ultimately become chloroplasts, while their hosts then became green plants . The ability to capture solar energy that ushered in the multicellular life and the fantastic diversity of life we see today was followed by or concurrent with one other critical parasitic-turned-symbiotic cellular invasion. The availability of oxygen from plants led to energy and oxygen-guzzling bacteria, and when some of these invaded other cells they became mitochondria and their hosts became animals. Mitochondria are the cell's source of power or energy-use, and having mitochondria with access to oxygen allowed vastly greater rates of energy expenditure. It made the evolution of multicellular animals possible. One of the ultimate expressions of the high-energy way of life that is powered by the use of mitochondria is, of course, animals like the kinglets that maintain a liveness at an, to us, almost unimaginably high and sustained rate through a northern winter. The metabolic fires generated by the mitochondria can be fanned to run on high, given the availability of much oxygen, or they may be turned down low. Life is the process that harnesses, and more importantly, controls that fire. It produces heat, and heat is often synonymous with life. Temperature is, to us, a sensation measured on a scale of hot to cold. Physically, it is molecular motion , and we can measure it with a thermometer because the greater the motion of the molecules of a substance, say mercury, the farther apart they are spaced. We measure this molecular expansion as mercury (or some other liquid) in a column is displaced up a calibrated scale. The molecular motion, as such, is not life but a prerequisite for it. Heat, on the other hand, is the energy that goes in or out of the system to change temperature. Some substances must absorb more energy (from the sun for example) before their molecules are set into motion, raising the temperature. One calorie is the unit of energy defined to raise one gram of water one degree Celsius. Substances, like rock, heat up with much less energy than that required to heat water. Again, energy is not life, but a prerequisite for it, and life is insatiable for it. What is truly miraculous, therefore, is that life continues and even thrives in winter, when the sun is low. There is no upper limit of temperature. Within our solar system, the surface temperature of the sun is about 6,000°C; the center is about 3,000 times higher, or 18,000,000°C. The lower temperature limit in the universe, on the other hand, is finite. It's the point at which all molecular motion stops and the heat energy content is zero. That temperature precludes living, but from adaptations to the winter world that I will discuss, it need not destroy life. Life can, at least theoretically, persist on hold at the lowest temperature in the universe. Our centigrade scale is defined as a 100-arbitrary-unit division of heat energy content of water, between when water molecules leave the crystal structure to become liquid (0°C) and 100°C when the liquid water boils at sea level. The zero energy content of matter, or lowest temperature limit in the universe, is defined as 0°K on the Kelvin scale and it corresponds to -273.15°C or -459.7° on the Fahrenheit scale. Since life as we know it is water-based, the active cellular life that most of us are familiar with is restricted to the very narrow temperature range between the freezing and boiling points of water (which vary somewhat depending on pressure and presence of dissolved solutes) where the controlled rates of energy use become possible. We are composed mostly of water ... Winter World The Ingenuity of Animal Survival . Copyright © by Bernd Heinrich. Reprinted by permission of HarperCollins Publishers, Inc. All rights reserved. Available now wherever books are sold. Excerpted from Winter World: The Ingenuity of Animal Survival by Bernd Heinrich All rights reserved by the original copyright owners. Excerpts are provided for display purposes only and may not be reproduced, reprinted or distributed without the written permission of the publisher.