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The Edge Of Physics: A Journey to Earth's Extremes to Unlock the Secrets of the Universe – A Science Writer's Adventures at the Frontiers of Cosmology and Quantum Mechanics
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In this deeply original book, science writer Anil Ananthaswamy sets out in search of the telescopes and detectors that promise to answer the biggest questions in modern cosmology. Why is the universe expanding at an ever faster rate? What is the nature of the "dark matter" that makes up almost a quarter of the universe? Why does the universe appear fine-tuned for life? Are there others besides our own?
Ananthaswamy soon finds himself at the ends of the earth—in remote and sometimes dangerous places. Take the Atacama Desert in the Chilean Andes, one of the coldest, driest places on the planet, where not even a blade of grass can survive. Its spectacularly clear skies and dry atmosphere allow astronomers to gather brilliant images of galaxies billions of light-years away. Ananthaswamy takes us inside the European Southern Observatory’s Very Large Telescope on Mount Paranal, where four massive domes open to the sky each night "like dragons waking up."
He also takes us deep inside an abandoned iron mine in Minnesota, where half-mile-thick rock shields physicists as they hunt for elusive dark matter particles. And to the East Antarctic Ice Sheet, where engineers are drilling 1.5 miles into the clearest ice on the planet. They’re building the world’s largest neutrino detector, which could finally help reconcile quantum physics with Einstein’s theory of general relativity.
The stories of the people who work at these and other dramatic research sites—from Lake Baikal in Siberia to the Indian Astronomical Observatory in the Himalayas to the subterranean lair of the Large Hadron Collider—make for a compelling new portrait of the universe and our quest to understand it. An atmospheric, engaging, and illuminating read, The Edge of Physics depicts science as a human process, bringing cosmology back down to earth in the most vivid terms.
- Print length336 pages
- LanguageEnglish
- Publication dateJanuary 14, 2011
- Dimensions5.25 x 0.84 x 8 inches
- ISBN-100547394527
- ISBN-13978-0547394527
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Editorial Reviews
Review
"Part history lesson, part travel log, part adventure story, The Edge of Physics is a wonder-steeped page-turner." — SEED Magazine, 3/2/10 "These experiments and others are heroic in every sense, and Ananthaswamy captures their excitement--and the personalities of the scientists behind them--with enthusiasm and insight." Publishers Weekly, 1/4/10. "Sure to appeal to general readers interested in science books without the philosophy and mathematics found in drier, more academic physics titles." — Library Journal. "Physicists are trying to understand the furthest reaches of space and the furthest extremes of matter and energy. To do it, they have to trek to some of the furthest places on Earth—from deep underground, to forbidding mountains, to the cold of Antarctica. Anil Ananthaswamy takes us on a thrilling ride around the globe and around the cosmos, to reveal the real work that goes into understanding our universe."—Sean Carroll, California Institute of Technology, and author of From Eternity to Here: The Quest for the Ultimate Theory of Time "An excellent book. The author has a great knack for making difficult subjects comprehensible. I thoroughly enjoyed it."—Sir Patrick Moore, former president of the British Astronomical Society and presenter of the BBC’s The Sky at Night "Ananthaswamy’s juxtaposition of extreme travel and extreme science offers a genuinely novel route into the story of modern cosmology. His tale turns on the price of success: we already know so much about our universe that it becomes hugely difficult—even risky—to pry loose from nature that next burst of insight. The result is a well written and genuinely accessible account of what it takes to push past the edge of human knowledge."—Thomas Levenson, author of Newton and the Counterfeiter and Einstein in Berlin "Clean, elegant prose, humming with interest."—Robert MacFarlane, author of Mountains of the Mind and The Wild Places
"The Edge of Physics...is, quite simply, the ultimate physics-adventure travelogue...as an adventure story and a fly-on-the-wall account of remote places that most of us will never visit, The Edge of Physics is brilliant." —PhysicsWorld
"Ananthaswamy displays a writer's touch for the fascinating detail...whether he is in an abandonded iron mine in Minnesota's Mesabi Range or the frigid Siberian expanse of Lake Baikal, he finds intrepid physicists and explains to us why these weird places are the only locations on the planet where these experiments could be done." —Washington Post
"A grand tour of modern day cosmology’s sacred places...evocative...engaging…refreshing...a taste of science in the heroic mode." —Sky At Night "Ananthaswamy, a science writer and editor, smoothly weaves together the stories of people who help push science forward, from principal investigators to research institute gardeners, with exquisitely clear explanations of the questions they hope to solve -- and why some research can be done only at the edge of the world." —ScienceNews "A remarkable narrative that combines fundamental physics with high adventure... Ananthaswamy is a worthy guide for both journeys." —New Scientist “The Edge of Physics is an accomplished and timely overview of modern cosmology and particle astrophysics. Ananthaswamy’s characterizations of the many physicists he meets are on the mark... Ananthaswamy conveys that cutting-edge science is a human endeavour.” —Nature
"Ananthaswamy’s investigation of current experiments in physics bypasses the mathematics of the field, making it easier for the average reader to dig in and enjoy the amazing discoveries and research methods that he encounters. The author has a knack for intertwining an overview of the purpose of these experiments with a finely balanced dose of related history and trivia. He also exhibits poetic touches here and there as he shares colorful vignettes from each of his destinations." —Curled Up With A Good Book.com "While Ananthaswamy—a consulting editor at New Scientist inLondon—focuses heavily on the science, The Edge of Physics reads like a travel-adventure story or a work offiction." —Failure Magazine
"From the top of Hawaii’s Mauna Kea to Switzerland’s Large Hadron Collider and more, Ananthaswamy paints a vivid picture of scientific investigations in harsh working conditions...even for readers who don’t know a neutrino from Adam, these interesting tales of human endeavor make The Edge of Physics a trip worth taking." The BookPage
About the Author
Excerpt. © Reprinted by permission. All rights reserved.
It was the day after Christmas in 2004, a bright winter's day in Berkeley, California. I was outside a café at the corner of Shattuck and Cedar, waiting for Saul Perlmutter, an astrophysicist at the University of California. The campus is nestled at the base of wooded hills that rise steeply from the city's edge. About 1,000 feet up in the hills is the Lawrence Berkeley National Laboratory (LBNL). In the 1990s, the UC campus and LBNL housed several members of two teams of astronomers that simultaneously but independently discovered something that caused ripples of astonishment, even alarm. Our universe, it seems, is being blown apart.
Perlmutter was the leader of one of those teams. His enthusiastic, wide-eyed gaze, enhanced by enormous glasses, along with a forehead made larger by a receding hairline, reminded me of Woody Allen. But what he had found was no laughing matter. In fact, Perlmutter admitted that their discovery had thrown cosmology into crisis. The studies of distant supernovae by the two teams had shown that the expansion of the universe, first observed by Edwin Hubble in 1929, was accelerating - not, as many had predicted, slowing down. It was as if some mysterious energy were creating a repulsive force to counter gravity. Unsure as to its exact nature, cosmologists call it dark energy. More important, it seems to constitute nearly three-quarters of the total matter and energy in the universe.
Dark energy is the latest and most daunting puzzle to confront cosmologists, adding to another mystery that has haunted them for decades: dark matter. Nearly 90 percent of the mass of galaxies seems to be made of matter that is unknown and unseen. We know it must be there, for without its gravitational pull the galaxies would have disintegrated. Perlmutter pointed out that cosmologists in particular, and physicists in general, are now faced with the stark reality that roughly 96 percent of the universe cannot be explained with the theories at hand. All our efforts to understand the material world have illuminated only a tiny fraction of the cosmos.
And there are other mysteries. What is the origin of mass? What happened to the antimatter that should have been produced along with matter after the big bang? After almost a century of spectacular success at explaining our world using the twin pillars of modern physics - quantum mechanics and Einstein's general theory of relativity - physicists have reached a plateau of sorts. As Perlmutter put it, he and others are now looking to climb a steep stairway toward a new understanding of the universe, with only a foggy idea of what awaits them at the top.
Part of this seemingly superhuman effort will involve reconciling quantum mechanics with general relativity into a theory of quantum gravity. In situations where the two domains collide - where overwhelming gravity meets microscopic volumes, such as in black holes or in a big bang - the theories don't work well together. In fact, they fail miserably. One of the most ambitious attempts to bring them together is string theory, an edifice of incredible mathematical complexity. Its most ardent proponents hope that it will lead us not just to quantum gravity but to a theory of everything, allowing us to describe every aspect of the universe with a few elegant equations. But the discovery of dark energy and recent developments in string theory itself have conspired to confound. On yet another winter's day in the Bay Area, more than two years after meeting Perlmutter, I got a taste of just how grave things had gotten in physics.
It was a late February afternoon in 2007. A conference room on the ballroom level of the San Francisco Hilton was filled to capacity for this session at the annual meeting of the American Association for the Advancement of Science (AAAS). Three physicists were arguing about dark energy and how it relates to some of the most serious questions one can ask: Why is our universe the way it is? Is it fine-tuned for the existence of life? Dark energy, it turns out, is not merely mysterious; it seems to be at about the right value for the formation of stars and galaxies. “The great mystery is not why there is dark energy. The great mystery is why there is so little of it,” Leonard Susskind, Felix Bloch Professor of Theoretical Physics at Stanford and co-inventor of string theory, told the audience at the Hilton. He continued in a poetic vein: “The fact that we are just on the knife edge of existence, [that] if dark energy were very much bigger we wouldn't be here, that's the mystery.”
The hope until recently had been that string theory would explain this, that dark energy's value would fall out naturally as a solution to the theory's equations - as would the answers to other puzzling questions. Why does the proton weigh almost two thousand times more than the electron? Why is gravity so much weaker than the electromagnetic force? Essentially, why do the fundamental constants of nature have the values they do? The question of dark energy is emblematic of such concerns. Nothing in the laws of physics can explain why many aspects of our universe are what they are. They seem to be extraordinarily fine-tuned to produce a universe capable of supporting life - a fact that bothers physicists no end.
But string theory's hoped-for denouement is nowhere in sight. Indeed, some physicists are slowly abandoning the notion that everything about the universe can be reduced to a handful of equations. In San Francisco, Susskind rose to address this issue. His talk was titled “Why the Rats Are Fleeing the Ship.” However, abandoning reductionism hasn't meant abandoning string theory. Quite the contrary. For Susskind and many others, it has meant embracing the theory in all its mathematical glory, despite its mind-boggling consequences. One of the most outlandish implications of string theory, as it stands today, is the existence of a multiverse. The idea is that our universe is just one of a possible 10 to the five hundredth power universes, if not more. And in this extraordinary scenario lies an answer to the conundrum of why dark energy and other fundamental constants have the values they do. In a multiverse, all values of dark energy and fundamental constants are possible; in fact, the laws of physics can differ from universe to universe. To explain our universe, physicists don't have to resort to tweaking and fine-tuning. If a multiverse exists, then there is a fi- nite probability, however small, that our universe randomly emerged with the properties it has. The laws governing it give rise to stars and galaxies - and, indeed, planets and intelligent life, including physicists asking the question: Why is the universe the way it is?
This is the so-called anthropic principle, which, loosely stated, says that our universe is what it is because we are here to say so, and if it were any different we wouldn't exist to inquire. The idea is viewed by many as a cop-out, for then physicists don't have to work so hard to explain all things from first principles. Another speaker, cosmologist Andrei Linde, Susskind's colleague at Stanford, recalled his efforts to talk about the anthropic principle to physicists at Fermilab, outside Chicago, nearly twenty years ago. Linde had been warned that eggs were thrown at people who talked about such things, so he began by discussing something else entirely and switched topics midway, on the assumption that the Fermilabbers wouldn't “have enough time to go to Safeway and buy eggs.”
Given string theory's support for a multiverse, the anthropic principle is gaining traction. But string theory itself is so far from being experimentally verified that many physicists find it difficult, if not impossible, to take its implications seriously. The third participant that afternoon, cosmologist Lawrence Krauss, then of Case Western Reserve University, summed up the argument for the opposition. “I think you can imagine a theory where the multiverse would be science. If one had a theory, a real theory, a real theory that predicted lots of things we see about the universe, predicted lots of things we could test, but also predicted lots of things we couldn't test, then I think most of us would say we believe the things we cannot test [such as the existence of a multiverse],” he said.
Susskind was staring daggers at Krauss by then. But Susskind's somber tone at the end of the session suggested that it wasn't going to be easy to answer critics. “All I can say is that we worry about this,” he said. “[String theory] is the biggest question in physics right now. Can we make observational science out of it?”
One thing all three speakers agreed on: Only experiments could break this impasse.
The greatest advances in physics have come when theory has moved in near-lockstep with experiment. Sometimes the theory has come first and sometimes it's the other way around. For instance, it was an experiment performed in 1887 by Albert Michelson and Edward Morley - showing that the speed of light is independent of the motion of the observer - that influenced Einstein's 1905 formulation of the special theory of relativity. A decade later, Einstein produced the general theory of relativity, but it was only after experiments in 1919 verified its fascinating implication - the bending of starlight by the sun's gravity - that the theory gained widespread acceptance. And throughout the early to mid-1900s, theorists and experimentalists jostled and outdid each other as they shaped quantum mechanics. An equally fruitful collaboration occurred in the 1960s and 1970s, when particle physicists theorized about the fundamental particles and forces that make up the material world and experiments confirmed their startlingly accurate predictions. But this energetic interplay is now deadlocked. The discovery of dark energy and dark matter, along with the failure, so far, of experiments to find the Higgs boson (thought to give elementary particles their mass), has allowed theorists free rein. Ideas abound, adrift in a sea of speculation. Can the next generation of experiments in cosmology and particle physics help anchor the theories to reality?
This book is my attempt at an answer. It is a quest that took me from London, where I lived and worked, to the distant reaches of the Earth, from desolate deserts to the depths of derelict mines, from mountaintops to the bottom of the world, looking for cutting-edge experiments that promise to drag physics out of its theoretical morass. Many of the experiments I visited are tackling, each in its own way, the twin mysteries of dark matter and dark energy. But I also went to see the telescopes and detectors that are searching for antimatter, the Higgs boson, and neutrinos, which are elusive subatomic particles pervading the universe. Neutrinos barely interact with matter and travel unhindered through space, carrying information about the distant reaches of the cosmos in ways that no other particle can. All these experiments are building the steps of Perlmutter's metaphorical stairway. My journey, too, became a metaphor: for the forays that scientists are making to the very limits of their understanding - to the edge of physics.
The story begins with a pilgrimage to the 100-inch telescope at Mount Wilson in California, where Hubble discovered that our universe is expanding, thus laying the observational foundation for the big-bang theory and modern cosmology. The 100-inch pushed the technological boundaries of its time, but it has long been outstripped by modern telescopes now scanning the night skies. Every evening, they open their giant domes to peer more than halfway across the universe, gathering light, sometimes one photon at a time. The instruments that analyze this light are equally powerful, such as the 8.6-ton spectrograph that's helping astronomers study the universe slice by slice with incredible accuracy. In contrast are the small, hockey-puck-size silicon and germanium detectors, so exquisitely engineered that they are handled like works of art. They wait patiently, day after day, week after week, for the merest hint of dark matter.
These experiments are dwarfed by gigantic balloons that soar into the stratosphere bearing experiments that search for primordial antimatter and study the cosmic microwave background (a radiation left over from the big bang).
Experimental physics reaches its pinnacle at the Large Hadron Collider, the world's largest particle smasher. Machines weighing thousands of tons monitor the paths of subatomic particles with micrometer precision. These particles spew forth from collisions of proton beams - each beam carrying as much energy as a 400-ton train going 150 kilometers per hour. Superconducting magnets that are colder than deep space strain to keep these beams confined to their paths around a 27-kilometer-long underground tunnel. New particles that emerge from the cauldron of proton smashups may contain anything from the Higgs boson to dark matter to the first hints of extra dimensions.
These magnificent telescopes and detectors can work only in the most extreme settings. Their surreal environments are the unsung characters in this unfolding story - venues rarely appreciated and often overlooked. The cold, dry air above the Atacama Desert high in the Chilean Andes, where not a blade of grass can grow, allows starlight that has traveled for billions of years to enter a telescope without being smudged in its final approach by something as mundane as water vapor. (Space-based instruments, of course - such as the Hubble Space Telescope - don't have to contend with the atmosphere's deleterious effect on light.) The crystalline clarity of Lake Baikal in Siberia is crucial to a pioneering underwater neutrino telescope, and Russian physicists endure the piercing cold to camp on the frozen lake and work on their submerged instrument.
Descending into the Earth's crust affords similar benefits. Deep within an abandoned iron mine in Minnesota, physicists hunt for dark matter, their detectors shielded from the chaos of cosmic rays by a half mile of rock. The sweat-drenched miners who dug these mines with nothing more than drill bits and sledgehammers could hardly have imagined the role their mine now plays in deciphering the nature of our universe. Meanwhile, a vast and arid land in the interior of South Africa - a desolate expanse devoid of pollution - has been proposed as the site of the world's biggest radio telescope, its three thousand antennas capable of sweeping across vast swaths of the universe faster than any instrument ever built.
As extreme destinations go, there are few that compare with Antarctica, on average the coldest, driest, and highest continent on Earth. It's a land so frigid that a sharp intake of breath can sear one's lungs. Moist exhaled air freezes in an instant, and mortal danger, in the form of snow-covered crevasses, is only a moment of distraction away. Still, cosmologists cherish the Antarctic Plateau for its thin, dry, stable, and unpolluted air, and they are building gigantic telescopes to probe the cosmic microwave background with a precision that's impossible to emulate almost anywhere else on Earth. But it's not just the air above Antarctica that attracts the scientists. They are also turning the kilometers-thick ice at the South Pole into a neutrino detector. Nowhere else does there exist a block of material so massive, clear, and solid that it can be used to study the slipperiest particle in the universe. A frozen wasteland could lead us toward the correct theory of quantum gravity.
This book is a paean to the remote regions that are the soul of today's experimental cosmology. They astonish with their eloquence, whether it's the Milky Way strewn across a dark Chilean sky or the ethereal Hanle Valley ensconced in a secluded corner of the Tibetan Plateau, shielded from the world by the 8,000-meter peaks of the Greater Himalayas. Despite their differences, these places share a profound minimalism: There is nothing extraneous, none of the noise or distractions of modern society. A glaciologist I met in Antarctica spoke of the “absolute stillness” he felt on that continent, faced with only the elements, which were too extreme to ignore. Cosmology needs these places if it is to solve the pressing questions of our existence.
Product details
- Publisher : Mariner Books
- Publication date : January 14, 2011
- Language : English
- Print length : 336 pages
- ISBN-10 : 0547394527
- ISBN-13 : 978-0547394527
- Item Weight : 10.9 ounces
- Dimensions : 5.25 x 0.84 x 8 inches
- Best Sellers Rank: #434,383 in Books (See Top 100 in Books)
- #75 in Optics for Physics
- #107 in Scientific Experiments & Projects
- #110 in Physics of Mechanics
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About the author

ANIL ANANTHASWAMY is former deputy news editor and current consultant for New Scientist. He is a guest editor at UC Santa Cruz’s science-writing program and teaches an annual science journalism workshop at the National Centre for Biological Sciences in Bangalore, India. He is a freelance feature editor for the Proceedings of the National Academy of Science’s “Front Matter” and has written for National Geographic News, Discover, and Matter. He has been a columnist for PBS NOVA’s The Nature of Reality blog. He won the UK Institute of Physics’ Physics Journalism award and the British Association of Science Writers’ award for Best Investigative Journalism. His first book, The Edge of Physics, was voted book of the year in 2010 by Physics World.
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- 5 out of 5 stars
Shiva’s Dance:
Reviewed in the United States on January 6, 2019What a fantastic book! Join Anil Ananthaswamy on his pilgrimage around the world to visit as many of the most famous, and unusual, Observatories that he can get to. In his 2010 book “The Edge of Physics” Ananthaswamy shares his experiences on this global journey. Along the way he interviewed some of the top minds in astronomy and theoretical physics, seeking answers to many of the most pressing questions in modern science: Is Supersymmetry a valid theory? Is there actually a Higgs Boson?* And the hunt for Cosmological Neutrinos and the Neutralinos. As a layman-reader I really enjoyed this book although there were portions of the text that left me feeling somewhat overwhelmed by the complex theories of particle physics and the mysteries of cosmological history. But Ananthaswamy is very good at explaining these difficult concepts, his writing is layman friendly and very readable. Part travel log, part history and cutting edge science, this entertaining book left me hungry for more of the same. Starting out in California, USA, the author visits the Mt. Wilson Observatory and takes a side trip to visit a Camaldolese Monastery in the Santa Lucia Mountains to spend some time with one of the resident Monks and experience some really dark skies. From there he continued on to more exotic locations; the VLT at Cerro Paranal Observatory in Chile’s Atacama Desert; the Karoo region of So. Africa, possibly the future home of the SKA (Square Kilometer Array)— the other contender is in Australia; the controversial observatories atop Mauna Kea, Hawaii and with IceCube in Antarctica drilling for the Square Kilometer Neutrino Detector. The list goes on but, for me, the high point was his visit to CERN in Geneva, Switzerland to see ATLAS: the huge particle detector for the Large Hadron Collider (LHC). While touring each facility the author discussed the ultimate goals of the scientists and engineers work and live there. And what are those goals? High on everybody’s list was a theory that combines General Relativity and Quantum Mechanics but they would also like to confirm Supersymmetry, look for validation to String Theory and the Multiverse. Ananthaswamy’s description of CERN and ATLAS is breathtaking. Working and doing research at CERN is definitely not for the faint of heart. With the dawning of the Space Age it wasn’t long before new observatories were being sent to “The Final Frontier” in the form of satellites like Hubble and Planck that can “park” at one of the Lagrangian Points to make their observations. And so the book closes with a look to the future when a new generation of scientists, and their tools, will be rewriting the composition and history of our universe. I thoroughly enjoyed this challenging book and I highly recommend it to anyone interested reading about space, time and the universe. I had no technical or downloading problems with this Kindle edition.
(* Higgs Boson was Discovered at CERN in 2012)
Last Ranger
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Adventurous Science or Scientific Adventure
Reviewed in the United States on January 23, 2012Anil's book contains different stories relating to Physics experiments conducted in different parts of the world, most of them remotely located. Travelling to those desolate places is the adventure part. Describing the instruments and the experiments along with the relevant background in Physics. The mix of Physics and adventure makes this book very exciting. A background of high school Physics is enough to understand the experiments.
Starting with the 60 inch and the 100 inch telescopes at Mount Wilson near Los Angeles, built by George Hale in the beginning of 1900s. Peeping through these telescopes, the famous astronomer Edwin Hubble and his equally famous assistant Milton Humason, found out in the early twentieth century that the different galaxies are retreating from each other. This gave rise to the concept of an expanding Universe. Extrapolating this expansion backwards in time led to the now widely accepted Big Bang theory. Later George Hale built a 200 inch telescope in Mount Palomar, further south to escape the light pollution caused by the growing city of Los Angeles.
The action then moves to a deep mine in Minnesota at Soudan. At the bottom of this abandoned mine is a very sensitive detector for detecting Cold Dark Matter. It is now postulated that most of the matter in the universe consists of dark matter, which is not visible to us as normal matter consisting of atoms. It does not contain the regular subatomic particles like electrons, protons and neutrons etc. Instead it is speculated to contain a very weakly interacting particle called neutralino. The sensitive detectors consist of ultra-pure germanium and silicon crystals cooled to 40 degree micorokelvins, just a shade above the absolute zero of -273 degree celsius. The detectors have not detected any neutralinos yet. The search is on !
The action then shifts to Lake Baikal in Russia. It has a neutrino observatory deep beneath the ice. Neutrinos, discovered by the famous physicist Wolfgang Pauli, are copiously generated by our Sun. They move quickly rarely interacting with any matter in its path. Millions of them pass through our bodies each second and we don't even know about them. There are very energetic neutrinos which are generated in the galactic centers. Studying them could give us clues about the formation of galaxies. Neutrinos form a streak of blue light when they hit water. A huge amount of pure water contained in Lake Baikal acts as a natural detector for these rare neutrinos from the center of the galaxy.
Next stop is the Cerro Paranal in the Atacama Desert in Chile. Just 12km from Pacific coast, on a mountain 2635 meters high, there is Very Large Telescope (VLT) consisting of 4 telescopes each of 8.2 meters in diameter. The telescopes are used in conjunction with an advanced spectrograph (which can detect different light colors or absence of any color, coming from different sources). This is one of the most advanced telescopes in the world used to study the Cosmos.
Next is a location which will most likely house a radio telescope called the Square Kilometer Array. Unlike an optical telescope, which consists of mirrors and lenses, radio telescopes consist of a an array of radio antennas, all of them connected to a radio receiver. The combined signals are scanned for sources like Pulsars and Quasars which emit only radio waves, and no light. Radio telescopy was started by Karl Jansky when he first observed radio signals coming from the center of our galaxy, the Milky Way. The location of this telescope is likely to be finalized this year (2012). A mention is made of GMRT (Giant Meter Radio Telescope), an array of 30 dishes each of 45meters in diameter, located about 50 miles north of Pune in India. Indian astronomer Govind Swarup built each antenna cheaply from 16 tubular steel frames tied by steel ropes.
Stage now shifts to the most desolate of all places, Antarctica. The experiments, called BESS, are conducted by launching balloons packed with detectors. These detectors look for anti matter. Anti matter is opposite of matter. They annihilate each other when they come in contact. It is speculated that there is some anti matter in the universe. Some stars and galaxies may be made of antimatter. Matter and anti matter may have formed in nearly equal amounts during the birth of the universe, and thereafter most of the anti matter got annihilated on contact with matter. A few hundred miles from the balloon launch site, at the south pole is an experiment called IceCube, which has sensors dug deep into ice cores, to look for neutrinos. It is similar to the Lake Baikal neutrino observatory, but operating in most extreme conditions.
Next is the very famous huge particle collider in Europe (spanning the borders of Switzerland, France, Italy) called Large Hadron Collider (LHC). Consisting of a massive underground ring several kilometers in diameter, it generates highest energies on the planet to accelerate the protons and make them collide. Built to understand the beginning of the universe, it looks for a particle known as Higgs Boson, which is also called the God particle (incidentally Peter Higgs himself is an atheist). One of the detectors which looks for the aftermath of the collisions, is called ATLAS, which consist of massive superconducting magnets. If confirmed, Higgs Boson will open a new chapter in Physics.
Towards the end of the book, it also mentions about newer telescopes in space, i.e. Planck launched in 2009 to study the Cosmic Background Microwave radiation in greater detail. Laser Interferometry Space Antenna (LISA), to be launched later this decade, will consist of 3 satellites positioned at the vertices of a triangle, million miles apart, to detect gravity waves. The gravity waves, if detected, would represent a ripple in the fabric of space and time.
10 people found this helpfulSending feedback...Sending feedback...HelpfulThank you for your feedback.Sorry, we failed to record your vote. Please try againThanks, we'll investigate in the next few days.Sorry, We failed to report this review. Please try again - 3 out of 5 stars
Oooopsie...
Reviewed in the United States on March 20, 2018While I just began reading this book, and am optimistic about enjoying and learning from it, a major typo in the last sentence of the second paragraph has me wondering what lies ahead. You can see the error in the short preview of the book on Amazon - it appears that the words "...quarters of the..." are missing from that sentence. Without these words, the sentence is meaningless. I am hoping this is a singular error, and will amend this review after my reading.
UPDATE: one day later, after coming upon another editing error which I failed to document, I find on the third page of chapter 2 that the word 'insignificant' has become 'insignia cant' in the eBook. My fear is that this is a common problem herein... what has happened to proofreading and editing, especially in a semi-scientific book?!?
15 people found this helpfulSending feedback...Sending feedback...HelpfulThank you for your feedback.Sorry, we failed to record your vote. Please try againThanks, we'll investigate in the next few days.Sorry, We failed to report this review. Please try again - 5 out of 5 stars
Great insite to this topic and history that is not to far back.
Reviewed in the United States on February 11, 2019I don't read fast and so I had the talk app added at this time. (Don't know how I did it but it worked this time) I love the writing in its everyday speech. Loved the history behind the topic. I learned that we are not far from this time period and I even had enter action with some of the people that were involved with the time line. My son was even in Chile where the telescope was being used. My family live in close proximity to the person that was involved with the Palomar Observatory. While going on in ones life you really are not aware of history being made and when you do it can just blow you away. So fantastic. Have not finish the book yet but have other things going but will keep the task on the front burner. Give it a try. Also if you have a challenge with reading find out how to use the talking books and hope you can connect with areas you have not tried before. Oh this is not too techy so far. Those that are visual learners can picture or image in your minds eye what is being said, or that is how I am able to get what is going on. Happy trails to discovery.
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Poetic, Prosaic And Pedantic.
Reviewed in the United States on May 10, 2018Anil and his editor Amanda Cook, cobbled together an amazing book, combining science, cultural, physical and anthropological geography, geology, travel to exotic and revered scientific locations on earth, then providing glimpses into both deep space and quantum mechanics. (This sentence is a microcosm of much of the style of the book.)
I reveled in some amazingly poetic prose as he described the locations that housed or supported an amazing array of telescopes located in places few care to venture. Fortunately for us, he went to those often hostile places and spent as much time writing on the geographies mentioned above, as the hard-core science that motivated their existence.
It’s a complex story. It includes acronyms and names enough to dissuade a reader from continuing, but then he slips in something fascinating about places or an Ideas, both here on earth and into the multiverse.
He is careful to include a multitude of scientists and support personnel, past and present, who labor in difficult places without much recognition or human comfort. It’s a Who’s Who of science, and very few receive awards or devices, theories or systems named for them, all do their part to bring knowledge to we who glibly receive it from our easy chairs.
If nothing else resonates with the reader, the glossaries and indices at the end of the book can be used for further study and clarification.
Four stars only reflect my inability to understand large sections of the scientific prose, not the author’s vast knowledge or broad-based education, which is quite stunning.
I found that having Google Earth and Wikipedia close by enabled me to stop and see many of the places and images contained in his writing. Pictures in the text or at the end of the book would have made this far more enjoyable.
If one reads only what they can easily understand, this will be well worth their investment in time. As my father used to say “Eat the meat and spit out the bones
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A book that will make you stand up cheer
Reviewed in the United States on March 16, 2010The legendary advertisement that was supposed to have been placed in a London newspaper by Sir Ernest Shackleton reads: MEN WANTED: FOR HAZARDOUS JOURNEY. SMALL WAGES, BITTER COLD, LONG MONTHS OF COMPLETE DARKNESS, CONSTANT DANGER, SAFE RETURN DOUBTFUL. HONOUR AND RECOGNITION IN CASE OF SUCCESS. Whether true or not, it is this spirit that animates the physicists who strive to discover the secrets of our universe at some of the most inhospitable places on Earth, under harrowing conditions that would give pause to the most intrepid explorer. Anil Ananthaswamy follows them and provides us with a window into their world. The result is a fascinating book which frames the tenets of Physics in a manner that is accessible to practically anyone. More importantly, it frames those eternal questions that have piqued the interest of mankind since the development of cognizance: Why are we here? Where did we come from? What lies outside the Universe, are there any other "heres"? The questions themselves awaken a sense of awe, but it is even more interesting to look into the lives of those who did not stop there, but decided to do something about it. From the Fraunhofer lines in stellar spectra to Digital Optical Modules embedded in a cubic kilometer of ice beneath the Earth's South Pole, to the coldest place in the known universe (which, oddly enough, is in a tunnel underneath Geneva), it is heartening to hear the stories of seemingly ordinary people who are striving to do extraordinary things. The result is a stirring, awe-inspiring good read, which has a definite tendency to make you want to stand up and cheer. Luckily for me, this could be accomplished with the minimum of fuss from my favorite armchair.
April 15, 2010: Some reviewers have made a note of the fact that the book does not have any high-quality pictures. To access additional content, pictures, videos and other details can be found at the web site for this book, [..] plus the author's blog on his travels to remote parts of the planet. Check it out!
20 people found this helpfulSending feedback...Sending feedback...HelpfulThank you for your feedback.Sorry, we failed to record your vote. Please try againThanks, we'll investigate in the next few days.Sorry, We failed to report this review. Please try again - 4 out of 5 stars
Good Overview
Reviewed in the United States on November 29, 2010The book is unique in that :
- it is not mired in detail but rather intended to give the reader a good high-level overview of the state-of-the-art.
- it is a focus on experimental physics, although does point out the raison d'etre for the experiement.
- it is more of narrative of the author's travel - inspires one to do the same and go on a "Physication (physics vacation)".
- it actually chronicles bits of the lives of numerous unsung players and characters, whose dedication to science is just remarkable.
What would have been useful is some more description or pointers to the Physics itself and a summary which chronicles all efforts towards a given goal (e.g. finding neutrinos - and then having the author point out which ones he visited and why).
But all in all a good read from where you can launch your own "physication" or exploration into an area of physics that catches your fancy.
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It’s supreme physics to the enthusiasts.
Reviewed in the United States on May 15, 2020Well I really enjoyed reading this book many years after my first encounter with physics and chemistry. Amazing how little we were taught in years past. At this much and much higher level, knowledge becomes relative and understanding is just temporary and faint. Yet I couldn’t put this book down as it put the history of this science together from visits to various experimentation sights and described their past research results and their consequences. Highly recommended.
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Top reviews from other countries
CharM5 out of 5 starsA great book for a beginner like me.
Reviewed in Canada on April 11, 2019I really enjoyed this book. I have to admit, I'm a total novice when it comes to physics. My only claim is that I'm extremely curious about all things. This book provided easy to understand and entertaining explanations on physics theories and how physicists are setting out to prove them. The author wrote wonderful descriptions of the various, and sometimes extreme, environments scientists are using to carry out their experiments. Because The Edge of Physics held my interest from cover to cover, I have a better understanding of how science is attempting to solve the unknown aspects about our universe.
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D Crosby5 out of 5 starsGood physics book
Reviewed in France on September 30, 2025My husband loves the book which I bought for him.
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Glen5 out of 5 starsBret reading
Reviewed in Australia on January 29, 2019Brilliant summary of the frontiers of cosmology. Partly travelogue, history and scientific explanation of the frontiers of current research experimentation.
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Amazon Kunde5 out of 5 starsalles bestens
Reviewed in Germany on October 16, 2013meine Erwartungen wurden voll erfüllt - würde jederzeit wieder kaufen - meine Erwartungen wurden voll erfüllt - würde jederzeit wieder kaufen
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D. Shearer5 out of 5 starsgreat read.
Reviewed in the United Kingdom on October 17, 2020a great read very interesting if you have any interest in modern astronomy and particle physics, but not involved in the field. Some basic knowledge of the basis of particle physics and astronomy. It is just a little out of date but still as very very good read. I thoroughly enjoyed it
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