Following the end of the First World War the Mediterranean Fleet found itself heavily involved in the Eastern Mediterranean, the Sea of Marmora, the Black Sea and to a lesser extent, the Adriatic. Naval commanders were faced with complex problems in a situation of neither war nor peace. The collapse of the Ottoman, Russian and Habsburg empires created a vacuum of power in which different factions struggled for control or influence. In the Black Sea this involved the Royal Navy in intervention in 1919 and 1920 on the side of those Russians fighting the Bolsheviks. By 1920 the Allies were also faced with the challenge of the Turkish nationalists, culminating in the Chanak crisis of 1922. The 1923 Treaty of Lausanne enabled the Mediterranean Fleet finally to return to a peacetime routine, although there was renewed threat of war over Mosul in 1925-1926. These events are the subject of the majority of the documents contained in this volume. Those that comprise the final section of the book show the Mediterranean Fleet back to preparation for a major war, applying the lessons of World War One and studying how to make use of new weapons, aircraft carriers and aircraft.

In Synchronicity Paul Halpern tells the little-known story of the unlikely friendship between the Nobel-prize-winning quantum physicist Wolfgang Pauli and the father of psychoanalysis, Carl Jung. In the 1930s, Pauli and Jung began collaborating on a unified theory of quantum and the mind, the result of which was Jung's synchronicity principle-the idea that events connected by meaning need not be explained by causality. Pauli's work on entanglement theory, which allowed for instantaneous cause and effect relationships, was particularly appealing to Jung, as it seemed to give weight to his controversial theory of a collective unconscious. Casting their relationship within a larger intellectual history of entanglement theory, Halpern poses a question that has mystified physicists and philosophers alike since the times of Aristotle: Is the speed of light finite, as Einstein posited, or is it, as Pauli and the proponents of entanglement theory asserted, variable across time and dimensions? As Halpern works his way through the history of the physics of cause and effect, he shows that this centuries-old debate is not only relevant at the smallest scales of particle physics but also at the largest scales of the cosmos itself.

Following the end of the First World War the Mediterranean Fleet found itself heavily involved in the Eastern Mediterranean, the Sea of Marmora, the Black Sea and to a lesser extent, the Adriatic. Naval commanders were faced with complex problems in a situation of neither war nor peace. The collapse of the Ottoman, Russian and Habsburg empires created a vacuum of power in which different factions struggled for control or influence. In the Black Sea this involved the Royal Navy in intervention in 1919 and 1920 on the side of those Russians fighting the Bolsheviks. By 1920 the Allies were also faced with the challenge of the Turkish nationalists, culminating in the Chanak crisis of 1922. The 1923 Treaty of Lausanne enabled the Mediterranean Fleet finally to return to a peacetime routine, although there was renewed threat of war over Mosul in 1925-1926. These events are the subject of the majority of the documents contained in this volume. Those that comprise the final section of the book show the Mediterranean Fleet back to preparation for a major war, applying the lessons of World War One and studying how to make use of new weapons, aircraft carriers and aircraft.

In the past decade, Paul Halpern has brought readers three stunning histories of science -- Einstein's Dice and Schroedinger's Cats, The Quantum Labyrinth, and Synchronicity -- that reveal the twisted, bizarre, and illuminating stories of physics' greatest thinkers and ideas. In Flashes of Creation, Halpern turns to what might be the biggest story of them all: the discovery of the origins of the universe and everything in it. Today, the Big Bang is so deeply entrenched in our understanding of the universe that to doubt it would seem crazy. And that is pretty much what has happened to the last major opponent of the theory, British astronomer Fred Hoyle. If anyone knows his name today, they probably think he went off the deep end-or at least was so very wrong for so long as to seem completely obtuse. But the hot-headed Hoyle saw himself as a crusader for physics, defending scientific progress from a band of charlatans. His doggedness was equalled by one man alone: Russian-American physicist George Gamow, who saw the idea of the Big Bang as essential to explaining where the Universe came from, and why it's full of the matter that surrounds us. The stakes were high! And the ensuing battle, waged in person and through the media over decades, was as fiery as the cosmic cataclysm the theory describes. Most of us might guess who turned out to be right (Gamow, mostly) and who noisily spun out of control as the evidence against his position mounted (Hoyle). Unfortunately for Hoyle, he is mostly remembered for giving the theory the silliest name he could think of: "The Big Bang." But as Halpern so eloquently demonstrates, even the greatest losers in physics -- including those who seem as foolish and ornery as Fred Hoyle -- have much to teach us, about boldness, imagination, and even the universe itself.

An accessible look at the hottest topic in physics and the experiments that will transform our understanding of the universe

The biggest news in science today is the Large Hadron Collider, the world's largest and most powerful particle-smasher, and the anticipation of finally discovering the Higgs boson particle. But what is the Higgs boson and why is it often referred to as the God Particle? Why are the Higgs and the LHC so important? Getting a handle on the science behind the LHC can be difficult for anyone without an advanced degree in particle physics, but you don't need to go back to school to learn about it. In "Collider," award-winning physicist Paul Halpern provides you with the tools you need to understand what the LHC is and what it hopes to discover.Comprehensive, accessible guide to the theory, history, and science behind experimental high-energy physicsExplains why particle physics could well be on the verge of some of its greatest breakthroughs, changing what we think we know about quarks, string theory, dark matter, dark energy, and the fundamentals of modern physicsTells you why the theoretical Higgs boson is often referred to as the God particle and how its discovery could change our understanding of the universeClearly explains why fears that the LHC could create a miniature black hole that could swallow up the Earth amount to a tempest in a very tiny teapot""Best of 2009 Sci-Tech Books (Physics)"""-Library Journal"""Halpern makes the search for mysterious particles pertinent and exciting by explaining clearly what we don't know about the universe, and offering a hopeful outlook for future research.""-"Publishers Weekly"Includes a new author preface, ""The Fate of the Large Hadron Collider and the Future of High-Energy Physics""

The world will not come to an end any time soon, but we may learn a lot more about it in the blink of an eye. Read "Collider" and find out what, when, and how.

A playful and entertaining look at science on The Simpsons This amusing book explores science as presented on the longest-running and most popular animated TV series ever made: The Simpsons. Over the years, the show has examined such issues as genetic mutation, time travel, artificial intelligence, and even aliens. "What's Science Ever Done for Us?" examines these and many other topics through the lens of America's favorite cartoon. This spirited science guide will inform Simpsons fans and entertain science buffs with a delightful combination of fun and fact. It will be the perfect companion to the upcoming Simpsons movie. The Simpsons is a magnificent roadmap of modern issues in science. This completely unauthorized, informative, and fun exploration of the science and technology, connected with the world's most famous cartoon family, looks at classic episodes from the show to launch fascinating scientific discussions mixed with intriguing speculative ideas and a dose of humor. Could gravitational lensing create optical illusions, such as when Homer saw someone invisible to everyone else? Is the Coriolis effect strong enough to make all toilets in the Southern Hemisphere flush clockwise, as Bart was so keen to find out? If Earth were in peril, would it make sense to board a rocket, as Marge, Lisa, and Maggie did, and head to Mars? While Bart and Millhouse can't stop time and have fun forever, Paul Halpern explores the theoretical possibilities involving Einstein's theory of time dilation. Paul Halpern, PhD (Philadelphia, PA) is Professor of Physics and Mathematics at the University of the Sciences in Philadelphia and a 2002 recipient of a John Simon Guggenheim Memorial Fellowship. He is also the author of The Great Beyond (0-471-46595-X).

Praise for "The Great Beyond": "A marvelous book-very clear, very readable. A brilliant introduction to the math and physics of higher dimensions, from Flatland to superstrings. Its greatest strength is a wealth of fascinating historical narrative and anecdote. I enjoyed it enormously." - Ian Stewart, author of "Flatterland". "A remarkable journey from Plato's cave to the farthest reaches of human thought and scientific knowledge. This mind-boggling book allows readers to dream strange visions of hyperspace, chase light waves, explore Klein's quantum odyssey and Kaluza's cocoon, leap through parallel universes, and grasp the very essence of conscience and cosmos. Buy this book and feed your head." - Clifford Pickover, author of "A Passion for Mathematics". "Halpern looks with a bemused eye at the wildest ideas currently afoot in physics. He takes us into the personal world of those who relish and explore seemingly outlandish notions, and does it with a light, engaging style." - Gregory Benford, author of "Foundation's Fear". "An informative, stimulating, and thoughtful presentation at the very frontiers of contemporary physics.;It is quite on a par with Brian Greene's "The Elegant Universe" or his more recent "The Fabric of the Cosmos", and as such, deserves to receive wide non-specialist coverage among an intelligent, curious, thinking public." - Professor E. Sheldon, "Contemporary Physics".

In Fall 1939, Richard Feynman, a brash and brilliant recent graduate of MIT, arrived in John Wheeler's Princeton office to report for duty as his teaching assistant. The prim and proper Wheeler timed their interaction with a watch placed on the table. Feynman caught on, and for the next meeting brought his own cheap watch, set it on the table next to Wheeler's, and also began timing the chat. The two had a hearty laugh and a lifelong friendship was born. At first glance, they would seem an unlikely pair. Feynman was rough on the exterior, spoke in a working class Queens accent, and loved playing bongo drums, picking up hitchhikers, and exploring out-of-the way places. Wheeler was a family man, spoke softly and politely, dressed in suits, and had the manners of a minister. Yet intellectually, their roles were reversed. Wheeler was a raging nonconformist, full of wild ideas about space, time, and the universe. Feynman was very cautious in his research, wanting to prove and confirm everything himself. Yet when Feynman saw merit in one of Wheeler's crazy ideas and found that it matched experimental data, their joint efforts paid off phenomenally. The brilliance and originality of each physicist stimulated the other's imagination, leading to a rethinking of the nature of time and reality that proved essential for late-20th century breakthroughs in particle physics. Instead of a linear flow, Feynman's concept of "sum over histories" showed how the path a particle takes is a blend of all possible options that a particle could follow. Wheeler's attempts to remake particle physics from the ground up, spurred the now landmark idea of wormholes, and influenced his student Hugh Everett's conception of the Many Worlds Interpretation of quantum mechanics. The two thinkers pioneered the use of doodles and diagrams in explaining quantum interactions, giving birth to the now essential Feynman diagrams that show possible backward- and forward-in-time paths for particles. And this is only the tip of the iceberg. As The Quantum Labyrinth reveals in a riveting read, together, Feynman and Wheeler made sure that quantum physics would never be the same again.

When the fuzzy indeterminacy of quantum mechanics overthrew the orderly world of Isaac Newton, Albert Einstein and Erwin Schroedinger were at the forefront of the revolution. Neither man was ever satisfied with the standard interpretation of quantum mechanics, however, and both rebelled against what they considered the most preposterous aspect of quantum mechanics: its randomness. Einstein famously quipped that God does not play dice with the universe, and Schroedinger constructed his famous fable of a cat that was neither alive nor dead not to explain quantum mechanics but to highlight the apparent absurdity of a theory gone wrong. But these two giants did more than just criticize: they fought back, seeking a Theory of Everything that would make the universe seem sensible again.In Einstein's Dice and Schroedinger's Cat , physicist Paul Halpern tells the little-known story of how Einstein and Schroedinger searched, first as collabourators and then as competitors, for a theory that transcended quantum weirdness. This story of their quest,which ultimately failed,provides readers with new insights into the history of physics and the lives and work of two scientists whose obsessions drove its progress.Today, much of modern physics remains focused on the search for a Theory of Everything. As Halpern explains, the recent discovery of the Higgs Boson makes the Standard Model,the closest thing we have to a unified theory, nearly complete. And while Einstein and Schroedinger failed in their attempt to explain everything in the cosmos through pure geometry, the development of string theory has, in its own quantum way, brought this idea back into vogue. As in so many things, even when they were wrong, Einstein and Schroedinger couldn't help but get a great deal right.

As global markets toppled during the 2008 financial crisis, the Canadian market for non-bank asset-backed commercial paper (ABCP) seemed on the verge of collapsing. Fueled by a top rating from DBRS, ABCP had found its way into the portfolios of some of Canada's most sophisticated investors as well as vulnerable retail investors who didn't know what they were holding. The failure of the $32 billion market could have tipped Canadian and foreign credit default swap markets into chaos if it weren't for the swift actions of a few powerful asset holders. Collectively, through the Montreal Accord and led by veteran Canadian lawyer Purdy Crawford, they managed to hold the Canadian ABCP market back from the brink of collapse by crafting a complex and innovative solution. Back from the Brink goes behind the scenes of the ABCP crisis to examine how a solution was reached and lessons learned that could prevent or mitigate future crises. The authors also examine the imaginative use of the Companies' Creditors Arrangement Act and describe the roles played by the banks, the major investors, rating agencies, and the financial regulators in the crisis's origins and conclusions. Back from the Brink holds important lessons for anyone interested in Canadian law, the future of complex investments, and Canada's capital markets.

Pluto joined the Planet Club in 1930, but didn't quite fit in. He is much tinier than the gas giants in the outer part of the Solar System. He has a lot more moons than any of the inner planets. His orbit is much more stretched out than any of the other worlds' paths around the Sun. The other members of the Planet Club didn't know what to make of him. Then one day, Pluto received some bad news... Explore the story of Pluto as seen through the eyes of the planets themselves. Witness the rise and fall of Pluto's membership in the Planet Club. Why was he demoted and what happened next? Introduce young minds to the fascinating science of astronomy with this entertaining picture book about the Solar System. Great for ages four to ten Masterful illustrations by Vance Lehmkuhl make this book a true gem. Astronomy for children has never been more fun Praise for What's the Matter with Pluto? -"Delightful What a wonderful way to get young ones interested in the mysteries constantly unfolding in the sky above us. Smart, fun, and educational - all at the same time. ." -Christine Lavin, Singer-songwriter: "Shining My Flashlight on the Moon," "Planet X," "Just One Angel 2.0" "In 'What's the Matter with Pluto, ' Paul Halpern and Vance Lehmkuhl lay out the facts of planetary life with humor, clarity, and a surprising amount of depth. No other issue in astronomy has engendered such passionate feelings and outright confusion from children and adults alike as the "demotion" of Pluto from planetary status, and the abandonment of traditional mnemonics as the solar system went from nine planets to eight. Halpern and Lehmkuhl describe the history of Pluto's discovery, what makes it so different from the others, and ultimately its expulsion from 'The Planet Club, ' with a light tone, but enough rigor that even the most ardent Plutonian defender would be hard-pressed to argue." -Dave Goldberg, Astrophysicist and Science Writer: "The Universe in the Rearview Mirror," "A User's Guide to the Universe" 10% of the royalties received for this book will be donated to the hunger charity Philabundance.

A comparative overview of common images of the universe from world art and folklore and their similarities to our current scientific understanding.

An amazing journey throughout the universe in a search for other planets and the possibility of extraterrestrial life.

A guide to the myriad possibilities for cosmic apocalypse. Inspired by the end of the millennium, science writer Paul Halpern tackles the fate of human civilization and our planet in this meditation on the end of the world. Beginning with the religious origins of the idea of apocalypse, Halpern shows how science has borrowed the metaphor to describe potential worldwide catastrophes. He spins out various scenarios for destruction, from nuclear war and global warming to a great flood and a new Ice Age. He argues that while human history will someday come to a close - even if we survived for billions of years, we would eventually face the end of the universe itself - in the meantime we have gained extraordinary control over our fate as a species. Faced with the power to steer our planet toward paradise or transform it into hell, he says, we must take steps to avoid those catalysts of apocalypse that are within our control.