The Spinning Magnet: The Electromagnetic Force That Created the Modern World–and Could Destroy It by Alanna Mitchell (PDF)

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The mystery of Earth’s invisible, life-supporting powerAlanna Mitchell’s globe-trotting history of the science of electromagnetism and the Earth’s magnetic field–right up to the latest indications that the North and South Poles may soon reverse, with apocalyptic results–will soon change the way you think about our planet.Award-winning journalist Alanna Mitchell’s science storytelling introduce intriguing characters–from the thirteenth-century French investigations into magnetism and the Victorian-era discover that electricity and magnetism emerge from the same fundamental force to the latest research. No one has ever told so eloquently how the Earth itself came to be seen as a magnet, spinning in space with two poles, and that those poles have dramatically reversed many time, often coinciding with mass extinctions. The most recent reversal was 780,000 years ago.Mitchell explores indications that the Earth’s magnetic force field is decaying faster than previously thought. When the poles switch, a process that takes many years, the Earth is unprotected from solar radiation storms that would, among other disturbances, wipe out much and possible all of our electromagnetic technology. Navigation for all kinds of animals is disrupted without a stable, magnetic North Pole. But can you imagine no satellites, no Internet, no smartphones–maybe no power grids at all?Alanna Mitchell offers a beautifully crafted narrative history of surprising ideas and science, illuminating invisible parts of our own planet that are constantly changing around us.

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Editorial Reviews: Review Praise for The Spinning Magnet”The Earth’s magnetic field — an invisible cloak that shields our bodies and our technologies from deadly harm — tends to be taken for granted. In reality it’s a fickle, ill-understood phenomenon. Alanna Mitchell delves into the mystery, in an engrossing book that features a new surprise on every page.”—Sean Carroll, author of The Big Picture: On the Origins of Life, Meaning, and the Universe Itself”In The Spinning Magnet, Alanna Mitchell weaves a scientific mystery in the best possible way, exploring the ancient puzzle of our planet’s electromagnetic field, following scientists as they attempt to decipher its clues, leading us to a better understanding of Earth’s invisible and powerful electromagnetic field. The result is a compelling tale of unseen and unforeseen natural forces – and a reminder that we’ve staked our home on a planet that remains infinitely strange, dangerous – and ever full of wonder.” —Deborah Blum, author ofThe Poisoner’s Handbook: Murder and the Birth of Forensic Medicine in Jazz Age New York”A fascinating untold story of science that is full of mystery and intrigue, and written with a great deal of style.” —Mark Miodownik, New York Times bestselling author of Stuff Matters, winner of the Royal Society’s Winton Prize”In The Spinning Magnet, Alanna Mitchell pulls off the rare trifecta in science writing: an engrossing plot of a planetary mystery, authentic character portraits of scientists and their passion for their work, and explanations of complex physics in easily understandable terms.”—Sabine Stanley, Professor of Earth and Planetary Sciences, Applied Physics Lab, Johns Hopkins University “Most of us don’t think much about magnetism or the Earth’s magnetic field. We recognize the importance of navigational compasses and the usefulness of those little magnets that decorate our kitchen refrigerators, but we don’t feel magnetism’s presence in our daily lives and we suspect we could probably live without it. Think again! In The Spinning Magnet, Alanna Mitchell draws us into a spellbinding scientific detective story, told over the ages, as she nimbly explains magnetism’s role in everything that matters. Each chapter is filled with exciting new revelations written in clear crisp prose. A skilled writer, Mitchell puts magnetism on the map!”—Timothy J. Jorgensen, author of Strange Glow: The Story of Radiation, winner of the American Institute of Physics’ Science Communication Award“[Mitchell] makes vivid the process of science … A complex, well-told account of ‘this spinning magnet we live on.'”—Kirkus Reviews“Captivating scientific history… an invaluable contribution to the popular science shelf.” —Booklist“Mitchell’s nontechnical discussion is substantively accessible, and her vivid writing holds the reader’s attention. … Pop science readers and science policy wonks will find plenty to think—and worry—about here.” –Publisher’s Weekly“There is little doubt that the magnetic field will reverse again. In the meantime, The Spinning Magnet gives readers a nontechnical description of electromagnetism and a measured assessment of the possible consequences for our modern world if it does so in the near future.” –Science“An intriguing story of humankind’s recent and evolving understanding of the integral electromagnetic properties of our planet that should hold the interest of both teen and adult readers.” –Library Journal”Mitchell’s portrait gallery is researched with a depth and breadth that make its protagonists’ triumphs and failures compelling. She also gives entertaining accounts of today’s working geoscientists. … Her interviews provide insights into their thoughts and actions that transcend the stereotypes of inscrutable nerd or heroic explorer.” –Nature“We don’t usually feature nonfiction books on this list, but science journalist Mitchell’s narrative history of the science of electromagnetism—with a look toward the future and the imminent, inevitable reversing of the North and South Poles—sounds as thrilling as any scifi tale.” -io9“Leaves readers tingling with anticipation… A thorough investigation of the scientific discoveries surrounding the electromagnetic field and what might happen when this force field fails.” -Shelf Awareness“In the same vein as Elizabeth Kolbert’s The Sixth Extinction, Mitchell’s captivating book shocks us into contemplating the physical forces that keep our world spinning that we take for granted every day.” —BookPage About the Author ALANNA MITCHELL is an acclaimed science journalist and author of Sea Sick: The Global Ocean in Crisis, which won the Grantham Prize for excellence in environmental journalism. She won a National Magazine Award in 2014 for a feature on the biology of extinction and in 2015 won a New York International Radio Festival Silver Medal for her science documentary on neonicotinoid pesticides. She has written for The New York Times Science section and is a contributor to CBC Radio’s Quirks & Quarks. She lives in Toronto, Canada. Excerpt. © Reprinted by permission. All rights reserved. Chapter 1 the beginnings of things Jacques Kornprobst, the man who can read the secrets of the rocks, was agitated. He had arrived twenty minutes early to pick me up at the hotel in Clermont-Ferrand, an ancient French university town perched on an annealed crack in the planet’s crust. He had the entry code at the ready to get into the free parking lot behind the building. The code had failed him. Some drivers cruise the streets nonchalantly, certain that the perfect parking spot will open up at just the right time. Kornprobst was not among them. Parking in this city of 150,000 had become troublesome over the decades he had lived there, and as he had mapped out the day’s tightly choreographed itinerary he had made intricate plans about where to park. And now, the first parking spot of the day had fallen through. Inside the hotel he sprinted, red-faced, fingertips frigid in the spring chill. “Kornprobst!” he rapped out as he met me for the first time. Then he turned swiftly to the reception desk to let off a stream of injured French, explaining to the bewildered woman sitting there-she had been so friendly earlier, solicitous about replenishing the croissant basket and tinkering with the cafŽ-au-lait machine-about the affront. He had called the day before to secure the code. And now, today, he said, chin thrust slightly forward, it was malfunctioning. Abruptly, she left through a back door. He darted out front to a tiny blue Renault car that was parked haphazardly on a curve at the corner, performed a roundabout U-turn through the city’s tortured roads, and then nosed up to the gate with its uncooperative code. The receptionist stood there, punching in numbers, shivering. He drummed his fingers on the steering wheel. Finally, the barrier began to rise and the receptionist, without so much as a glance behind her, returned inside to her desk. Kornprobst smiled grimly, thrust the little car into gear, gunned the engine, and zoomed triumphantly into a parking spot. He was watching the clock. He was on a mission to memorialize the life and work of Bernard Brunhes, a French physicist who, along with his research assistant Pierre David, made an astounding, violently unsettling, and controversial find at the turn of the last century. Brunhes, whose name is pronounced “brune,” discovered that the planet’s two magnetic poles-north and south-had once switched places. In the decades following his discovery, his colleagues, originally aghast at Brunhes’s finding, proved that the poles have reversed not just once, but many times on an unpredictable, or “aperiodic,” schedule. The last time was 780,000 years ago. But despite the fact that our current magnetic epoch is named after him, Brunhes has largely slipped out of the scientific memory. He does not even rate his own entry in the Encyclopedia of Geomagnetism and Paleomagnetism, the bible of the discipline of reading patterns in the Earth’s magnetic fields. Nor is he lionized in France, usually so careful to honor its own. In fact, he’s all but unknown even in his homeland, along with his grand scientific finding that the poles can switch places, that up can become down. Kornprobst, a fellow physicist, felt that he must right this wrong. He was so committed to Brunhes’s memory that some years ago he took the trouble to find the spot in the countryside where Brunhes hacked a piece of crumbly terracotta rock-similar to the stuff of Greek vases-out of a roadcut and made his great discovery. Kornprobst painstakingly pieced together the clues about where it could be and is one of a handful of people in the world who can usually find it. The first time he made the pilgrimage to the site, he left frustrated, having failed to identify the right seam of rock. He’s found it several times since, but it’s so overgrown, so unmarked, that success is always touch and go. Kornprobst thought that Brunhes should at least have a commemorative panel at the university in Clermont-Ferrand, so he sweated through a couple of years writing to geological agencies and eminent physicists all over the world jostling their elbows about Brunhes’s contribution to science, raising the money to erect it. Then he arranged for a ceremony and lecture to accompany its inauguration at the university in 2014. It was through that ceremony that I found Kornprobst. He wrote an article about it for Eos, a journal of the American Geophysical Union. I read it and sent him an email asking him if he would help me understand why Brunhes was so important and maybe even find that seam of terracotta. He wrote back thirteen minutes later to say he would be delighted. I was at the hotel in Clermont-Ferrand two weeks later. Sporting a thick, off-white cable-knit sweater the same hue as his rakish hair, Kornprobst left the car in the lot and we set off briskly on foot from the hotel through the back streets of Clermont-Ferrand. It is one of the oldest cities in France, founded more than two millennia ago on the site of what was then a sacred grove of trees. And so we were marching through time, across the history of science. Up the road named after Pierre Teilhard de Chardin, a Jesuit priest and paleontologist who deeply offended the Vatican for asserting that the book of Genesis is more allegory than fact. Past the geology department of the downtown campus of UniversitŽ Blaise Pascal, named after the seventeenth-century mathematician and physicist whose seminal experiment on barometric pressure was conducted a few kilometers outside the city by a brother-in-law (“There is the belief that Pascal experimented with pressure here,” Kornprobst declaimed, pointing vigorously down the street, “but it’s not true!”). Across a road named after the nineteenth-century zoologist Karl Kessler. And finally, to rue de Rabanesse, named after the tiny pale stone Renaissance castle that was Brunhes’s home and first observatory. Kornprobst gestured to it triumphantly, eyebrows raised, as if it explained a great deal. It looked like nothing out of the ordinary. It was standing forgotten on an overgrown patch of land across the street from a busy art school, surrounded by two layers of forbidding wire fence. Many of its lower windows-once elegant-were partially filled in with cement blocks. The parging that had covered the volcanic fieldstone that made up its walls had decayed, leaving gaps along the seams so you could see how it had all been fitted together. Its turret, where Brunhes collected meteorological information beginning in 1900, was still sturdy, reaching six floors into the sky, fifteenth-century iron fretwork still robust. This observatory is where the tale of Brunhes begins. And where the tale of Brunhes begins, so too does the story of the discovery of the planet’s long string of pole reversals. And that story, in turn, contains the tale of the mysterious magnetic organism in the core of the planet and how it has become deeply disturbed once more, yet again deciding whether to reverse. It was here that Brunhes, whose name means “brown” in the Occitan language of the ancient troubadours of this land, began to dream of understanding magnetism, the Earth’s secret power. We never feel it and rarely see it, but all the same, scientists and philosophers have been trying to understand it for thousands of years. For most of that time, people have imagined it to be local and transient. Magic, even. And fickle magic at that. In fact, magnetism is one of the few essential powers of the universe. To understand it, you have to go back in time to the birth of the universe, to see how the universe is arranged. And you have to do that in the company of theoretical physicists, who have developed the most precise mathematical laws so far to describe reality. Chapter 2 the unpaired spinning electron Today, magnetism is properly known as electromagnetism, one of the universe’s four fundamental physical forces. A fundamental force is one that simply exists. It is a never-ending characteristic. If you compare it to mathematics, it’s conceptually akin to a prime number-like 3 or 13-that can’t be divided into any combination of whole numbers except itself and one. A fundamental force can’t be reduced into a more basic force; it simply is. In theory, there are an infinite number of prime numbers. But in the universe today, there are only four fundamental physical forces-at least that we know of: gravity, strong nuclear interactions, weak nuclear interactions, and electromagnetism. (Caveat: scientists continue to look for a mysterious fifth force and make occasional, highly contested claims that they have found it. Stay tuned.) Each of these forces is intrinsic to the workings of the universe, indispensable, inescapable. They were born along with the universe, the sun, stars, moon, and skies. Gravity is the force that made Isaac Newton’s apple fall to the ground and that keeps you from falling off the face of the Earth as it spins. It governs bulk matter and attracts but doesn’t repel. It is the weakest of the forces but stretches to infinite space. The nuclear interactions govern the insides of atoms but nothing larger. Strong nuclear interactions hold the cores of atoms together. Weak ones (called weak because their sphere of influence is even smaller than strong nuclear interactions) allow atoms to fall apart and metamorphose into other types of atoms. That makes the weak nuclear force the ultimate alchemist. It is responsible for radioactive decay. The energy of our sun, which makes Earth the warm, livable place it is, is the result of both types of nuclear forces. As you read this, the weak interaction is allowing hydrogen protons to shed enough energy to become heavy hydrogen (deuterium) and then the strong interaction allows the atoms that result to fuse together into helium atoms. So what is electromagnetism? It is the force that holds matter together. Apart from gravity, which holds us down on Earth, everything we see around us is due to magnetic and electric forces, explained the American theoretical physicist Sean Carroll. It is the basis of the structure of the atom, holding electrons in place and allowing atoms to link up into molecules. But where did the structure of the atom come from? From the birth of the universe itself. So, Big Bang, about 13.7 billion years ago. The universe is created. What makes up the universe and everything in it? Is it atoms and the elements they form? To quantum field theorists, the answer can be stripped back to something more fundamental than atoms. To them, the universe is fashioned of fields: a field for each of the fundamental forces and thirteen other fields governing matter. A field is simply a mathematical way of talking about fluidlike substances that are spread out everywhere throughout the universe and have a value everywhere in the world. They ripple and sway. It’s a difficult concept. In his famous physics lectures to undergraduates at the California Institute of Technology, the late American physicist Richard Feynman said he had never been able to develop a mental image of the electromagnetic field: “How do I imagine the electric and magnetic field? What do I actually see? What are the demands of scientific imagination? Is it any different from trying to imagine that the room is full of invisible angels? No, it is not like imagining invisible angels. It requires a much higher degree of imagination to understand the electromagnetic field than to understand invisible angels.” Some portions of the electromagnetic field can be discerned. A wave of light is a bump in the electromagnetic field that travels through space. A particle, on the other hand, exists in only one location and nowhere else. But, like light, a particle is still a facet of a field, a little wave tied up into a bundle of energy. And particles make up atoms, or the stuff we can see and feel. The most basic particles, for our purposes here, are electrons and two kinds of quarks: up and down. Each of them has its own field. If you were to think about it in biological terms, they are like the base pairs of DNA that are the foundation of every living thing on Earth. The magic of the universe is that, conceptually, any of these quarks could be exchanged for any other quark. The same goes for electrons. They and their fields are the building blocks of all matter, including you. The inevitable implication of this, to a theoretical physicist, is that what we observe is only a portion of what is there. What we normally think of as empty space is filled with this powerful electromagnetic force field that gives matter its concreteness, as well as the other forces and fields. To physicists, this is humdrum reality. By the time the universe is a few millionths of a second old, it has cooled down enough for quarks to join together to create protons and neutrons, the bits that will eventually form the cores of atoms. (The word “atom” comes from the Greek meaning “indivisible.” Wrong, as it turns out.) Electrons don’t join up to make anything bigger; they remain solo. These particles aren’t forming atoms at this point; the universe is still too hot. They’re just bits. At about the 100-second mark in the life of this new universe, things have cooled down enough for some protons and neutrons to link up and make the heavy centers, or nuclei, of helium atoms-two protons, two neutrons. Give it another 380,000 years and now it’s cool enough that some of those simple nuclei have got electrons in the space around them. The electrons are negative. The protons are positive. They are responding to the maxims of the electromagnetic field: Opposite charges attract and like charges repel. So the negative electrons are drawn to the positive protons. That attraction keeps the electrons inhabiting the space around the nucleus. Neutrons, as the name suggests, are neutral. Why are protons positive and electrons negative and neutrons neutral? No one has satisfactorily explained that; they seem simply to have been born with those differences and we happened to endow them with that nomenclature. Why do opposite charges attract? Again, it just seems to be part of how the fields showed up. Most of the atom’s weight is in its center, in the protons and neutrons that are the nucleus. The electrons are lightweights, usually in motion. Some chemists like to say that if the whole atom were the size of a baseball stadium, the nucleus would be about the size of a baseball in the middle. That means most of an atom is what the early theorists of atomic structure used to think of as empty space. Today we know that it is filled with invisible fields. Because atoms create matter, that also means that most matter, not just space, is invisible fields. That includes the matter that makes up your body. I sometimes imagine what it must have felt like for the scientist who figured that out. I imagine him looking at his hand with renewed intensity, trying to peer through it. Read more

Reviews from Amazon users which were colected at the time this book was published on the website:

⭐Great history lesson, easy to read, and the depth of uncertainty, given the enormous variability of the strength and direction of the field, was ultimately comforting. It’ll probably be fine for a long long time.

⭐Magnetism

⭐Alanna Mitchell really did a great job with this. As a science guy, I honestly knew little about magnets or electricity and she educated me big time. More important is the reality of earth as a spinning magnet as such that its currents (i.e. Van Allen Belts) are the difference between all the life on our planet and the desertion of places like Mars and the moon.There are some frightening but necessary speculations on what will happen when the poles inevitably reverse and/or the sun emits a major solar flare. I will be thinking about these for the rest of my life even if we are fortunate enough to never have to deal with them.Lots of history lessons, lots of chemistry (my first love), and quite a bit of astronomy (my second science love). There were small parts I skimmed through but most of it I read every word, especially the second half of the book.Science buffs like myself will love this book.

⭐I loved this book! I have written my own novel (fiction) about this topic, and I relied heavily on material from this book. It was a fabulous resource!

⭐Remarkably invaluable quality! Excellent packaging. Remarkably grand delivery.

⭐This is a remarkable book, unique in many ways. Tracing the history of magnetic discovery, we are led from the early disoveries of geological memory – a story largely untold – to the realisation that our planet, as a gigantic magnet, has experienced multiple magnetic pole reversals, and significant disturbances in force fields. The text is wide in scope, from embracing Faraday to the controversies surrounding continental drift. Lucidly written using expert input, it’s obvious the author has travelled extensively in researching this book. We are left in the end wondering when the next decay and reversal of the earth’s magnetic poles could occur, and the dramatic implications this has for our future. Highly recommended reading.

⭐READABLE SCIENCE in an engaging format. Answered so many questions I had on the topic – and some I didn’t know I had. Highly recommended to the curious epicurean mind! Fascinating and fun without being frivolous. Plus, the hard copy has cool fonts (not sure if paperback does). Well done, Alanna Mitchell!

⭐I ordered this book because supposedly “Q” has this book as recommended reading. Oh my. I thought more of Q Anon than this book… It has to be nepotism of some kind in case anybody wants to know who the real Q is… Just so disappointing.Because of my academic experience in geology, I know that the north-south poles are due (actually overdue) to change, this book seemed to be a likely good read on that basis only. Not so.Nothing is logical here, only emotional. Connections are absent. There are some references at the end of the book, but references are contrived. Huh? Very sad in my humble opinion.Clearly, I am not recommending buying this book (even if you are a Q afficiando – alas).For example. On pages 263 and 264 you can read (if you spend the money to buy the book): “They need to know up from down because they continually travel between the water and the mud, pivoting between an oxygenated environment and one that doesn’t have oxygen.” We have been told these important organisms (described as bacteria in pond sediments) need to know up from down. No thought in the logic tells about whether the pond water (or any water) more oxygenated at the bottom would give a different result. Just exactly how does up versus down rank here? How does up versus down make any sense at all to a scientist? Give me a break. Up from down is not important if oxygenated versus non-oxygenated is the impetus of movement. This is total bull. And more illogical blithering idiot statements abound.

⭐I bought the book to read about hand magnets etc but this covered very advanced understanding of magnetic fields and the planet. I found it a good read but some well above my understanding.

⭐Makes you aware that what you might think is permanent isn’t nescessarily so.

⭐I like this book very much. Well researched story

⭐I believe that even if a person young or old with hardly any interest in science were to begin reading this book their interest in the world in general would be honed since all is connected.The way all is presented is intriguing introducing men of Science over a period where history is made each and every time something is invented and how it influenced others to take it even further and allow us presently to exist. The importance of Mathematics from it’s simplest form to that of all disciplines is portrayed as a catalyst allowing two or more ideas to interact with a outcome that proves or disproves. In the end generating even more ideas

⭐I have no scientific training but my curiosity was aroused by news reports that the magnetic north is moving further from true north. The book kept my interest when reviewing the amazing progress made in understanding the electromagnetic fields that arise from deep within our planet, protecting us from harmful solar radiation. Based on global scientific data and many studies it lays clear the challenges facing humanity and all life on the planet we call home. A fascinating read.

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