Here are 100 books that Quantum Physics fans have personally recommended if you like
Quantum Physics.
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Since my first college course in quantum physics, I have been fascinated with this enigmatic, infinitely interesting theory. It's our most fundamental description of the universe, it's been found to be unerringly accurate, yet it's quite subtle to interpret. Even more intriguingly, "nobody really understands quantum physics" (as Richard Feynman put it). For example, the theory's central concept, the wave function, is interpreted radically differently by different physicists. I have always yearned to grasp, at least to my own satisfaction, a comprehensive understanding of this theory. Since retirement 23 years ago, I have pursued this passion nearly full-time and found some answers, leading to several technical papers and a popular book.
Guilder uses historical vignettes to describe how entanglement came to be regarded as a – or perhaps the – central pillar of quantum physics. For example, we share a streetcar ride through Copenhagen in 1923 with Niels Bohr, Albert Einstein, and Arnold Sommerfeld. Although we don't know precisely what they discussed, Guilder indicates what they probably discussed based on quotations from letters and other evidence. Thus, the book reads like a historical novel. It centers on the distant correlations, dubbed (by Einstein and Erwin Schrodinger) "spooky action at a distance." Since 1964, physicists have shown this astonishing phenomenon, now called "non-locality," to be clearly predicted by quantum theory and fully confirmed by experiment. This development is the "rebirth" of quantum physics referred to in the title. Guilder is a non-scientist who writes beautifully with a good grasp of physics.
In The Age of Entanglement, Louisa Gilder brings to life one of the pivotal debates in twentieth century physics. In 1935, Albert Einstein famously showed that, according to the quantum theory, separated particles could act as if intimately connected–a phenomenon which he derisively described as “spooky action at a distance.” In that same year, Erwin Schrödinger christened this correlation “entanglement.” Yet its existence was mostly ignored until 1964, when the Irish physicist John Bell demonstrated just how strange this entanglement really was. Drawing on the papers, letters, and memoirs of the twentieth century’s greatest physicists, Gilder both humanizes and dramatizes…
I am totally fascinated by the quest of how Nature does it. In particular, I love the fact that humans managed to enters the strange world of atoms and photons by just using their brute intellectual force and imagination. This world obeys precise rules, but very different ones from those we get used to since childhood. For example, the laws that govern the microscopic world allow for indeterminacy and randomness. Moreover, some random events may manifest themselves at several locations at once, leading to the phenomenon of quantum non-locality. I am very fortunate that I could spend all my professional time on such fascinating conceptual questions, combined with highly timely new technologies.
This is a wonderful and highly convincing analysis of quantum non-locality, written by one of the top expert philosophers of science. Personally, I learned a lot from this book, which clearly influenced me and helped me to become an expert in the field. The book goes deep into explaining why we live in a world full of non-local correlations and what that means. It analyses in depth the tension between quantum non-locality and relativity. Moreover, it contains several original ideas, like, e.g., how many bits of communication are needed to simulate quantum non-locality. It is still today a very timely book.
Modern physics was born from two great revolutions: relativity and quantum theory. Relativity imposed a locality constraint on physical theories: since nothing can go faster than light, very distant events cannot influence one another. Only in the last few decades has it become clear that quantum theory violates this constraint. The work of J. S. Bell has demonstrated that no local theory can return the predictions of quantum theory. Thus it would seem that the central pillars of modern physics are contradictory. Quantum Non-Locality and Relativity examines the nature and possible resolution of this conflict. Beginning with accurate but non-technical…
I am totally fascinated by the quest of how Nature does it. In particular, I love the fact that humans managed to enters the strange world of atoms and photons by just using their brute intellectual force and imagination. This world obeys precise rules, but very different ones from those we get used to since childhood. For example, the laws that govern the microscopic world allow for indeterminacy and randomness. Moreover, some random events may manifest themselves at several locations at once, leading to the phenomenon of quantum non-locality. I am very fortunate that I could spend all my professional time on such fascinating conceptual questions, combined with highly timely new technologies.
John Steward Bell is one of the giants of the twentieth-century sciences, sitting beside Einstein, Bohr, Shannon. I don’t hesitate to predict that history will set him at the firmament of all sciences, thanks to his revolutionary discovery of quantum non-locality. This biography is a must for everyone willing to understand the personality of John Bell, the father of what became after his sudden death the second quantum revolution.
This book gives a readable non-mathematical account of the upbringing, education and academic achievement of John Stewart Bell, the celebrated physicist from Belfast, who was born in 1928.
Bell has become famous for what he described as his 'hobby', analysing the fundamental aspects of quantum theory, where he clarified a long-standing debate between the two most important figures of twentieth century physics, Albert Einstein and Niels Bohr, and showed that, contrary to belief over the previous thirty years, quantum theory could be supplemented with extra 'hidden variables'. His crucial 'Bell's Theorem' or 'Bell's Inequalities' demonstrated a contradiction between quantum theory…
Tap Dancing on Everest, part coming-of-age memoir, part true-survival adventure story, is about a young medical student, the daughter of a Holocaust survivor raised in N.Y.C., who battles self-doubt to serve as the doctor—and only woman—on a remote Everest climb in Tibet.
I am totally fascinated by the quest of how Nature does it. In particular, I love the fact that humans managed to enters the strange world of atoms and photons by just using their brute intellectual force and imagination. This world obeys precise rules, but very different ones from those we get used to since childhood. For example, the laws that govern the microscopic world allow for indeterminacy and randomness. Moreover, some random events may manifest themselves at several locations at once, leading to the phenomenon of quantum non-locality. I am very fortunate that I could spend all my professional time on such fascinating conceptual questions, combined with highly timely new technologies.
This book tells the fascinating story of the people and events behind the turbulent changes in attitudes to quantum theory in the second half of the 20th century. Science is sometimes quite abstract. But it is made by very concrete persons whose characters shape the various scientific communities.
This book tells the fascinating story of the people and events behind the turbulent changes in attitudes to quantum theory in the second half of the 20th century. The huge success of quantum mechanics as a predictive theory has been accompanied, from the very beginning, by doubts and controversy about its foundations and interpretation. This book looks in detail at how research on foundations evolved after WWII, when it was revived, until the mid 1990s, when most of this research merged into the technological promise of quantum information. It is the story of the quantum dissidents, the scientists who brought…
In school, I wasn’t fond of physics. Most of my education focused on the history of human civilization and culture. I rediscovered physics partly thanks to the books mentioned here—and the strangeness of quanta. My studies, exposure to Tao and Zen philosophies, and exploration of physics have given me a unique perspective and awareness: humanity is merely a tiny particle in the universe, neither central nor the king of all creation. Nothing new, of course—Buddha, Heraclitus, and Shakespeare all knew it well.
This wasn’t my first book on quantum physics; I had read several others, watched numerous programs, and browsed countless articles. But only this one helped me grasp the true essence of a wave, illuminating how what we perceive as 'real' might be no more than 'ripples on water.'
Quantum physics isn’t difficult; it’s strange and counterintuitive. This book helped me navigate that strangeness and to understand that we may be mere observers—actors playing assigned roles rather than directors of the play.
Everybody has heard that we live in a world made of atoms. But far more fundamentally, we live in a universe made of quanta. Many things are not made of atoms: light, radio waves, electric current, magnetic fields, Earth's gravitational field, not to mention exotica such a neutron stars, black holes, dark energy, and dark matter. But everything, including atoms, is made of highly unified or "coherent" bundles of energy called "quanta" that (like everything else) obey certain rules. In the case of the quantum, these rules are called "quantum physics." This is a book about quanta and their unexpected,…
I have always been fascinated by how the world works. What gives gravity so much power? Why is it easier to lift things with levers and pulleys? Why do we have electricity inside of our own bodies?! The world is amazing. My job editing nonfiction books for kids puts me on the front lines of some of the smartest science writing out there. While I had no hand in the making of the following five picture books about physics, they are still some of my favorites because of the way they peel back the mysterious layers of the world to show us the science hidden in our daily lives.
Fun and super clear graphics combined with straightforward discussions of complex topics make this book a hit. The writing is more expository than narrative, which will appeal to kids who love fact books and encyclopedias. Another one that both adults and kids can learn a ton from!
Everything around us – trees, buildings, food, light, water, air and even ourselves – is composed of minute particles, smaller than a nanometer (a billionth of a meter). Quantum physics is the science of these particles and without it none of our electronic devices, from smartphones to computers and microwave ovens, would exist.
But quantum physics also pushes us to the very boundaries of what we know about science, reality and the structure of the universe. The world of quantum physics is an amazing place, where quantum particles can do weird and wonderful things, acting totally unlike the objects we…
I am a professor of philosophy at New York University, but my interests have always fallen at the intersection of physics and philosophy. Unable to commit to just one side or the other, I got a joint degree in Physics and Philosophy from Yale and a PhD in History and Philosophy of Science at the University of Pittsburgh. My fascination with Bell’s Theorem began when I read an article in Scientific American in 1979, and I have been trying to get to the bottom of things ever since. My most recent large project is a Founder and Director of the John Bell Institute for the Foundations of Physics.
John Bell’s theorem about the unavoidability of what Einstein called “spooky action-at-a-distance” in quantum mechanics set off the second quantum revolution, leading to quantum computation, quantum cryptography, and quantum teleportation among other insights. This book collects Bell’s most important papers which range in style from professionally mathematical to popular and intuitive, so there is something for everyone. Beginners can start with “Quantum Mechanics for Cosmologists” or “Six Possible Worlds of Quantum Mechanics” or “Bertlmann’s Socks and the Nature of Reality” or “La Nouvelle Cuisine”. Experts can learn from “Against ‘Measurement’”. People interested in the mathematical details can find them, and people scared by math can largely avoid them.
John Bell, FRS was one of the leading expositors and interpreters of modern quantum theory. He is particularly famous for his discovery of the crucial difference between the predictions of conventional quantum mechanics and the implications of local causality, a concept insisted on by Einstein. John Bell's work played a major role in the development of our current understanding of the profound nature of quantum concepts and of the fundamental limitations they impose on the applicability of the classical ideas of space, time and locality. This book includes all of John Bell's published and unpublished papers on the conceptual and…
I am a professor of philosophy at New York University, but my interests have always fallen at the intersection of physics and philosophy. Unable to commit to just one side or the other, I got a joint degree in Physics and Philosophy from Yale and a PhD in History and Philosophy of Science at the University of Pittsburgh. My fascination with Bell’s Theorem began when I read an article in Scientific American in 1979, and I have been trying to get to the bottom of things ever since. My most recent large project is a Founder and Director of the John Bell Institute for the Foundations of Physics.
Ghirardi, together with Alberto Rimini and Tulio Weber, developed the first mathematically rigorous “objective collapse” interpretation of quantum formalism. This book is aimed at a popular audience, and includes discussion of quantum computation and quantum cryptography, which is absent from the other books on the list. The mathematics is slightly greater than in Albert’s book, but does not go beyond a high school level.
Quantum mechanics, which describes the behavior of subatomic particles, seems to challenge common sense. Waves behave like particles; particles behave like waves. You can tell where a particle is, but not how fast it is moving--or vice versa. An electron faced with two tiny holes will travel through both at the same time, rather than one or the other. And then there is the enigma of creation ex nihilo, in which small particles appear with their so-called antiparticles, only to disappear the next instant in a tiny puff of energy. Since its inception, physicists and philosophers have struggled to work…
I am a professor of quantum physics—the most notoriously complicated science humans have ever invented. While the likes of Albert Einstein commented on how difficult quantum physics is to understand, I disagree! Ever since my mum asked me—back while I was a university student—to explain to her what I was studying, I’ve been on a mission to make quantum physics as widely accessible as possible. Science belongs to us all and we should all have an opportunity to appreciate it!
Through Two Doors at Once is the most complete and lucid description of the archetypal quantum experiment, the so-called “double-slit experiment.” Anil Ananthaswamy interviews quantum scientists and weaves modern understanding into the history of one of the most famous science experiments ever.
How can matter behave both like a particle and a wave? Does a particle exist before we look at it or does the very act of looking bring it into reality? Is there a place where the quantum world ends and our perceivable world begins?
Many of science's greatest minds including Thomas Young, Albert Einstein and Richard Feynman have grappled with the questions embodied in the simple yet elusive 'double-slit' experiment in order to understand the fabric of our universe. With his extraordinary gift for making the complicated comprehensible, Anil Ananthaswamy travels around the world and through history, down to…
The scenario we are facing is scary: within a few decades, sea levels around the world may well rise by a metre or more as glaciers and ice caps melt due to climate change. Large parts of our coastal cities will be flooded, the basic outline of our world will…
Since my first college course in quantum physics, I have been fascinated with this enigmatic, infinitely interesting theory. It's our most fundamental description of the universe, it's been found to be unerringly accurate, yet it's quite subtle to interpret. Even more intriguingly, "nobody really understands quantum physics" (as Richard Feynman put it). For example, the theory's central concept, the wave function, is interpreted radically differently by different physicists. I have always yearned to grasp, at least to my own satisfaction, a comprehensive understanding of this theory. Since retirement 23 years ago, I have pursued this passion nearly full-time and found some answers, leading to several technical papers and a popular book.
This is a competent, charming account of the various mind-boggling quantum phenomena. It includes the uncertainty principle, the quantum atom, how quanta interact, the quantum vacuum, and the Standard Model. The book also ventures into the discussion of the transistor (the device behind the digital revolution) and the death of stars. Uniquely, we learn whyall these results follow the basic principles of quantum physics. The authors explain these phenomena in terms of a qualitative version of Feynman's path-analysis approach to quantum physics. I hasten to emphasize that this analysis is understandable by non-scientists, and shines a nice light on why the quantum world has the unexpected properties that it does have. Cox's popular writings are widely read in the UK. Both authors are physics professors at Manchester University.
In The Quantum Universe , Brian Cox and Jeff Forshaw approach the world of quantum mechanics in the same way they did in Why Does E=mc2? and make fundamental scientific principles accessible,and fascinating,to everyone. The subatomic realm has a reputation for weirdness, spawning any number of profound misunderstandings, journeys into Eastern mysticism, and woolly pronouncements on the interconnectedness of all things. Cox and Forshaw's contention? There is no need for quantum mechanics to be viewed this way. There is a lot of mileage in the weirdness" of the quantum world, and it often leads to confusion and, frankly, bad science.…
