Einstein Theory Of Relativity Quotes

If my theory of relativity is proven successful, Germany will claim me as a German and France will declare me a citizen of the world. Should my theory prove untrue, France will say that I am a German, and Germany will declare that I am a Jew.

Since the mathematicians have invaded the theory of relativity I do not understand it myself any more.

No matter how old you are now. You are never too young or too old for success or going after what you want. Here’s a short list of people who accomplished great things at different ages 1) Helen Keller, at the age of 19 months, became deaf and blind. But that didn’t stop her. She was the first deaf and blind person to earn a Bachelor of Arts degree. 2) Mozart was already competent on keyboard and violin; he composed from the age of 5. 3) Shirley Temple was 6 when she became a movie star on “Bright Eyes.” 4) Anne Frank was 12 when she wrote the diary of Anne Frank. 5) Magnus Carlsen became a chess Grandmaster at the age of 13. 6) Nadia Comăneci was a gymnast from Romania that scored seven perfect 10.0 and won three gold medals at the Olympics at age 14. 7) Tenzin Gyatso was formally recognized as the 14th Dalai Lama in November 1950, at the age of 15. 8) Pele, a soccer superstar, was 17 years old when he won the world cup in 1958 with Brazil. 9) Elvis was a superstar by age 19. 10) John Lennon was 20 years and Paul Mcartney was 18 when the Beatles had their first concert in 1961. 11) Jesse Owens was 22 when he won 4 gold medals in Berlin 1936. 12) Beethoven was a piano virtuoso by age 23 13) Issac Newton wrote Philosophiæ Naturalis Principia Mathematica at age 24 14) Roger Bannister was 25 when he broke the 4 minute mile record 15) Albert Einstein was 26 when he wrote the theory of relativity 16) Lance E. Armstrong was 27 when he won the tour de France 17) Michelangelo created two of the greatest sculptures “David” and “Pieta” by age 28 18) Alexander the Great, by age 29, had created one of the largest empires of the ancient world 19) J.K. Rowling was 30 years old when she finished the first manuscript of Harry Potter 20) Amelia Earhart was 31 years old when she became the first woman to fly solo across the Atlantic Ocean 21) Oprah was 32 when she started her talk show, which has become the highest-rated program of its kind 22) Edmund Hillary was 33 when he became the first man to reach Mount Everest 23) Martin Luther King Jr. was 34 when he wrote the speech “I Have a Dream." 24) Marie Curie was 35 years old when she got nominated for a Nobel Prize in Physics 25) The Wright brothers, Orville (32) and Wilbur (36) invented and built the world's first successful airplane and making the first controlled, powered and sustained heavier-than-air human flight 26) Vincent Van Gogh was 37 when he died virtually unknown, yet his paintings today are worth millions. 27) Neil Armstrong was 38 when he became the first man to set foot on the moon. 28) Mark Twain was 40 when he wrote "The Adventures of Tom Sawyer", and 49 years old when he wrote "Adventures of Huckleberry Finn" 29) Christopher Columbus was 41 when he discovered the Americas 30) Rosa Parks was 42 when she refused to obey the bus driver’s order to give up her seat to make room for a white passenger 31) John F. Kennedy was 43 years old when he became President of the United States 32) Henry Ford Was 45 when the Ford T came out. 33) Suzanne Collins was 46 when she wrote "The Hunger Games" 34) Charles Darwin was 50 years old when his book On the Origin of Species came out. 35) Leonardo Da Vinci was 51 years old when he painted the Mona Lisa. 36) Abraham Lincoln was 52 when he became president. 37) Ray Kroc Was 53 when he bought the McDonalds Franchise and took it to unprecedented levels. 38) Dr. Seuss was 54 when he wrote "The Cat in the Hat". 40) Chesley "Sully" Sullenberger III was 57 years old when he successfully ditched US Airways Flight 1549 in the Hudson River in 2009. All of the 155 passengers aboard the aircraft survived 41) Colonel Harland Sanders was 61 when he started the KFC Franchise 42) J.R.R Tolkien was 62 when the Lord of the Ring books came out 43) Ronald Reagan was 69 when he became President of the US 44) Jack Lalane at age 70 handcuffed, shackled, towed 70 rowboats 45) Nelson Mandela was 76 when he became President

E=mc2

I heard that in relativity theory, space and time are the same thing. Einstein discovered this when he kept showing up three miles late for his meetings.

The future is not a gift-it is an achievement.

If you've never done anything wrong it's probably because you have never tried anything new.

Dear Habicht, / Such a solemn air of silence has descended between us that I almost feel as if I am committing a sacrilege when I break it now with some inconsequential babble... / What are you up to, you frozen whale, you smoked, dried, canned piece of soul...?

After all, what is art? Art is the creative process and it goes through all fields. Einstein’s theory of relativity – now that is a work of art! Einstein was more of an artist in physics than on his violin. Art is this: art is the solution of a problem which cannot be expressed explicitly until it is solved.

Einstein's relativity work is a magnificent mathematical garb which fascinates, dazzles and makes people blind to the underlying errors. The theory is like a beggar clothed in purple whom ignorant people take for a king... its exponents are brilliant men but they are metaphysicists rather than scientists.

Asked in 1919 whether it was true that only three people in the world understood the theory of general relativity, [Eddington] allegedly replied: 'Who's the third?

A theory is more impressive the greater the simplicity of its premises, the more different are the kinds of things it relates, and the more extended its range of applicability.

Since the mathematicians have grabbed hold of the theory of relativity, I myself no longer understand it.

Einstein has a feeling for the central order of things. He can detect it in the simplicity of natural laws. We may take it that he felt this simplicity very strongly and directly during his discovery of the theory of relativity. Admittedly, this is a far cry from the contents of religion. I don't believe Einstein is tied to any religious tradition, and I rather think the idea of a personal God is entirely foreign to him.

One day you have Einstein, puzzling over the theory of relativity, the next you’ve got the Manhattan Project and a big hole in the ground.

Silence is the hardest scream

Till now it was believed that time and space existed by themselves, even if there was nothing else--no sun, no earth, no stars--while now we know that time and space are not the vessel for the universe, but could not exist at all if there were no contents, namely, no sun, earth and other celestial bodies.

If Relativity Theory kills our deepest convictions, why not start by finding out why we believed in them for millennia?

of the actual objects of physical reality. Physical objects are not in space, but these objects are spatially extended.

Einstein didn't invent the theory of relativity while he was multitasking at the Swiss patent office." quoting, David Meyer, a cognitive scientist at the University of Michigan

it is not difficult to understand why the general principle of relativity (on the basis of the equivalence principle) has led to a theory of gravitation.

Why should anyone raise an eyebrow because a latter-day Einstein’s wife expects her husband to put aside that lifeless theory of relativity and help her with the work that is supposed to be the essence of life itself: diaper the baby and don’t forge to rinse the soiled diaper in the toilet paper before putting it in the diaper pail, and then wax the kitchen floor.

You don't have to have a college degree to serve. You don't have to make your subject and your verb agree to serve. You don't have to know about Plato and Aristotle to serve. You don't have to know Einstein's theory of relativity to serve. You only need a heart full of grace. A soul generated by love. And you can be that servant.

The importance of C.F. Gauss for the development of modern physical theory and especially for the mathematical fundament of the theory of relativity is overwhelming indeed; also his achievement of the system of absolute measurement in the field of electromagnetism. In my opinion it is impossible to achieve a coherent objective picture of the world on the basis of concepts which are taken more or less from inner psychological experience.

The greatest threat to a robust, autonomous civil society is the ever-growing Leviathan state and those like Obama who see it as the ultimate expression of the collective. Obama compounds the fallacy by declaring the state to be the font of entrepreneurial success. How so? It created the infrastructure - roads, bridges, schools, Internet - off which we all thrive. Absurd. We don't credit the Swiss postal service with the Special Theory of Relativity because it transmitted Einstein's manuscript to the Annalen der Physik.

More careful reflection teaches us, however, that the special theory of relativity does not compel us to deny ether...To deny the ether is ultimately to assume that empty space has no physical qualities whatever.

result: every description of events in space involves the use of a rigid body to which such events have to be referred. The resulting relationship takes for granted that the laws of Euclidean geometry hold for ‘distances’, the ‘distance’ being represented physically by means of the convention of two marks on a rigid body.

Fundamental ideas play the most essential role in forming a physical theory. Books on physics are full of complicated mathematical formulae. But thought and ideas, not formulae, are the beginning of every physical theory.

if, relative to K, K’ is a uniformly moving co-ordinate system devoid of rotation, then natural phenomena run their course with respect to K’ according to exactly the same general laws as with respect to K. This statement is called the Principle of Relativity (in the restricted sense).

The Theory of Relativity confers an absolute meaning on a magnitude which in classical theory has only a relative significance: the velocity of light. The velocity of light is to the Theory of Relativity as the elementary quantum of action is to the Quantum Theory: it is its absolute core.

Einstein has put an end to this isolation; it is now well established that gravitation affects not only matter, but also light.

If one could see an infinite distance, they would observe the back of their head. That is Einstein's theory in a nut-shell".

Kada sedite sat vremena kraj lepe devojke, to prodje kao minut. Sedite minut na vrelu pec i to ce trajati kao sat. To se zove relativitet.

Einstein's work is to make physics more philosophical (in a good sense),

Roger Penrose and I showed that Einstein’s general theory of relativity implied that the universe must have a beginning and, possibly, an end.

The first half of the twentieth century, beginning with Albert Einstein’s 1905 papers on relativity and quantum theory, featured a revolution driven by physics.

Einstein, my upset stomach hates your theory [of General Relativity]—it almost hates you yourself! How am I to' provide for my students? What am I to answer to the philosophers?!!

Despite the earnest belief of most of his fans, Einstein did not win his Nobel Prize for the theory of relativity, special or general. He won for explaining a strange effect in quantum mechanics, the photoelectric effect. His solution provided the first real evidence that quantum mechanics wasn’t a crude stopgap for justifying anomalous experiments, but actually corresponds to reality. And the fact that Einstein came up with it is ironic for two reasons. One, as he got older and crustier, Einstein came to distrust quantum mechanics. Its statistical and deeply probabilistic nature sounded too much like gambling to him, and it prompted him to object that “God does not play dice with the universe.” He was wrong, and it’s too bad that most people have never heard the rejoinder by Niels Bohr: “Einstein! Stop telling God what to do.

In essence what relativity says is that space and time are not absolute but relative both to the observer and the thing being observed, and the faster one moves the more pronounced these effects will become. We can never accelerate ourselves to the speed of light, and the harder we try(the faster we go) the more distorted we become, relative to an outside observer.

Some years ago I read a book that brought Einstein's theory of relativity down to an eighth grade level. This convinced me that any subject can be made easy. In other words, always beware of anyone who tells you a topic is above you or better left to experts. This person may, for some reason, be trying to shut you out. You CAN understand almost anything.

Regardless of one's point of view, it's quite easy to see that Darwinism is not in the same league as the hard sciences. For instance, Darwinists will often compare their theory favorably to Einsteinian physics, claiming that Darwinism is just as well established as general relativity. Yet how many physicists, while arguing for the truth of Einsteinian physics, will claim that general relativity is as well established as Darwin’s theory? Zero.

difform motion will in every case produce the same effects as gravitation.

How did it come to pass that I was the one to develop the theory of relativity? The reason, I think, is that a normal adult never stops to think about problems of space and time. These are things which he has thought of as a child. But my intellectual development was retarded, as a result of which I began to wonder about space and time only when I had already grown up. Naturally I could go deeper into the problem than a child with normal abilities.

Einstein's paper on the photoelectric effect was the work for which he ultimately won the Nobel Prize. It was published in 1905, and Einstein has another paper in the very same journal where it appeared - his other paper was the one that formulated the special theory of relativity. That's what it was like to be Einstein in 1905; you publish a groundbreaking paper that helps lay the foundation of quantum mechanics, and for which you later win the Nobel Prize, but it's only the second most important paper that you publish in that issue of the journal.

As mathematicians were uncovering the connection between zero and infinity, physicists began to encounter zeros in the natural world; zero crossed over from mathematics to physics. In thermodynamics a zero became an uncrossable barrier: the coldest temperature possible. In Einstein's theory of general relativity, a zero became a black hole, a monstrous star that swallows entire suns. In quantum mechanics, a zero is responsible for a bizarre source of energy-infinite and ubiquitous, present even in the deepest vacuum-and a phantom force exerted by nothing at all.

Mankind has uncovered two extremely efficient theories: one that describes our universe's structure (Einstein's gravity: the theory of general relativity), and one that describes everything our universe contains (quantum field theory), and these two theories won't talk to each other.

... but then I was so utterly entranced by our discussion of Einstein's relative theory -" "Relativity," Ling corrected quickly under her breath. "- that I completely lost track of the time. "Funny," Ling whispered. "What?" Henry said. "Lost track of..." Ling shook her head, "never mind.

I sometimes ask myself how it came about that I was the one to develop the theory of relativity. The reason, I think, is that a normal adult never stops to think about problems of space and time. These are things which he has thought of as a child. But my intellectual development was retarded, as a result of which I began to wonder about space and time only when I had already grown up.

I think a strong claim can be made that the process of scientific discovery may be regarded as a form of art. This is best seen in the theoretical aspects of Physical Science. The mathematical theorist builds up on certain assumptions and according to well understood logical rules, step by step, a stately edifice, while his imaginative power brings out clearly the hidden relations between its parts. A well constructed theory is in some respects undoubtedly an artistic production. A fine example is the famous Kinetic Theory of Maxwell. ... The theory of relativity by Einstein, quite apart from any question of its validity, cannot but be regarded as a magnificent work of art.

I had a sneaking suspicion that time was not constant, but I guess I could never prove it. I suppose it didn’t really matter. I even had a theory that time didn’t go in straight line at all. I knew I was no Albert Einstein, but I had the sneaking suspicion that everything had happened, was happening, or would happen was really happening all the time. There was no past, present, and future. Everything was going on all at once and forever. If that was true, then each moment was eternity.

Einstein's theory, experimentally corroborated for the last hundred years, regardless of how outlandish and opposed to our prejudices (disguised as they are with the 'common sense' costume), is rational, consistent, and intelligible to the layperson - if s/he has the audacity of accepting the unfounded nature of those prejudices.

If Einstein had upended our everyday notions about the physical world with his theory of relativity, the younger man, Kurt Gödel, had had a similarly subversive effect on our understanding of the abstract world of mathematics.

The owner of the means of production is in a position to purchase the labor power of the worker. By using the means of production, the worker produces new goods which become the property of the capitalist. The essential point about this process is the relation between what the worker produces and what he is paid, both measured in terms of real value. Insofar as the labor contract is "free," what the worker receives is determined not by the real value of the goods he produces, but by his minimum needs and by the capitalists' requirements for labor power in relation to the number of workers competing for jobs. It is important to understand that even in theory the payment of the worker is not determined by the value of his product.

I have known a great many intelligent people in my life. I knew Max Planck, Max von Laue, and Wemer Heisenberg. Paul Dirac was my brother-in-Iaw; Leo Szilard and Edward Teller have been among my closest friends; and Albert Einstein was a good friend, too. And I have known many of the brightest younger scientists. But none of them had a mind as quick and acute as Jancsi von Neumann. I have often remarked this in the presence of those men, and no one ever disputed me. [...] But Einstein's understanding was deeper than even Jancsi von Neumann's. His mind was both more penetrating and more original than von Neumann's. And that is a very remarkable statement. Einstein took an extraordinary pleasure in invention. Two of his greatest inventions are the Special and General Theories of Relativity; and for all of Jancsi's brilliance, he never produced anything so original.

The myth of quantum consciousness sits well with many whose egos have made it impossible for them to accept the insignificant place science perceives for humanity, as modern instruments probe the farthest reaches of space and time. ... quantum consciousness has about as much substance as the aether from which it is composed. Early in this century, quantum mechanics and Einstein’s relativity destroyed the notion of a holistic universe that had seemed within the realm of possibility in the century just past. First, Einstein did away with the aether, shattering the doctrine that we all move about inside a universal, cosmic fluid whose excitations connect us simultaneously to one another and to the rest of the universe. Second, Einstein and other physicists proved that matter and light were composed of particles, wiping away the notion of universal continuity. Atomic theory and quantum mechanics demonstrated that everything, even space and time, exists in discrete bits – quanta. To turn this around and say that twentieth century physics initiated some new holistic view of the universe is a complete misrepresentation of what actually took place. ... The myth of quantum consciousness should take its place along with gods, unicorns, and dragons as yet another product of the fantasies of people unwilling to accept what science, reason, and their own eyes tell them about the world.

I’m not sure why I enjoy debunking. Part of it surely is amusement over the follies of true believers, and [it is] partly because attacking bogus science is a painless way to learn good science. You have to know something about relativity theory, for example, to know where opponents of Einstein go wrong. . . . Another reason for debunking is that bad science contributes to the steady dumbing down of our nation. Crude beliefs get transmitted to political leaders and the result is considerable damage to society.

where there is mass there is gravity. And where there is gravity there is curved space, according to Einstein’s general theory of relativity. And where space is curved it can mimic the curvature of an ordinary glass lens and alter the pathways of light that pass through.

Many of us have no grasp of quantum theory, or Einstein’s theories of special and general relativity, but this does not in itself lead us to oppose these theories! Darwinism, unlike ‘Einsteinism’, seems to be regarded as fair game for critics with any degree of ignorance.

The objective and merit of Einstein's theory is to identify those physical magnitudes which are absolute, i.e. common for all Inertial Frames, distinguishing them from those which are a mere perspective, only shared by those observers in repose within a given Inertial Frame.

It is comprehensible that a person could not have arrived at such a far-reaching change of view by continuing to follow the old beaten paths, but only by introducing some sort of new idea. Indeed, Einstein arrived at his theory through a train of thought of great originality.

Einstein, like myself, found Bern pleasant but boring. And so I wonder: If the Swiss were more interesting, might he never have daydreamed as much as he did? Might he never have developed the Special Theory of Relativity? In other words, is there something to be said for boredom?

However we select from nature a complex (of phenomena) using the criterion of simplicity, in no case will its theoretical treatment turn out to be forever appropriate...But I do not doubt that the day will come when that description (the general theory of relativity), too, will have to yield to another one, for reasons which at present we do not yet surmise. I believe that that this process of deepening the theory has no limits.

I believe that the Big-Bang Theory and the Evolution Theory, as well as Einstein’s Special Relativity Theory which does not allow for the existence of faster-than-light (superluminal) phenomena, all have flaws in them and must be replaced by new theories that can give Mankind a more concise view of our Universe. But the fact is exceptional discoveries and theories that challenge official science have been ignored by the Establishment for decades.

Einstein, twenty-six years old, only three years away from crude privation, still a patent examiner, published in the Annalen der Physik in 1905 five papers on entirely different subjects. Three of them were among the greatest in the history of physics. One, very simple, gave the quantum explanation of the photoelectric effect—it was this work for which, sixteen years later, he was awarded the Nobel prize. Another dealt with the phenomenon of Brownian motion, the apparently erratic movement of tiny particles suspended in a liquid: Einstein showed that these movements satisfied a clear statistical law. This was like a conjuring trick, easy when explained: before it, decent scientists could still doubt the concrete existence of atoms and molecules: this paper was as near to a direct proof of their concreteness as a theoretician could give. The third paper was the special theory of relativity, which quietly amalgamated space, time, and matter into one fundamental unity. This last paper contains no references and quotes to authority. All of them are written in a style unlike any other theoretical physicist's. They contain very little mathematics. There is a good deal of verbal commentary. The conclusions, the bizarre conclusions, emerge as though with the greatest of ease: the reasoning is unbreakable. It looks as though he had reached the conclusions by pure thought, unaided, without listening to the opinions of others. To a surprisingly large extent, that is precisely what he had done.

In gravitational fields there are no such thing as rigid bodies with Euclidean properties; thus the fictitious rigid body of reference is of no avail in the general theory of relativity. ... For this reason non-rigid reference-bodies are used, which are, as a whole, not only moving in any way whatsoever, but which also suffer alterations in form ad lib. during their motion... This non-rigid reference-body, ... might appropriately be termed a "reference mollusc,"...

It was a hundred years later that Einstein gave a theory (general relativity) which said that the geometry of the universe is determined by its content of matter, so that no one geometry is intrinsic to space itself. Thus to the question, "Which geometry is true?" nature gives an ambiguous answer not only in mathematics, but also in physics

Einstein was remarkable for his powers of concentration; he could work uninterruptedly for hours and even days on the same problem. Some of the topics that interested him remained on his mind for decades. For relaxation he turned to music and to sailing, but often his work would continue during these moments as well; he usually had a notebook in his pocket so that he could jot down any idea that came to him. Once, after the theory of relativity had been put forth, he confessed to his colleague Wolfgang Pauli, "For the rest of my life I want to reflect on what light is." It is perhaps not entirely an accident that a focus on light is also the first visual act of the newborn child.

We thus obtain the following result: every description of events in space involves the use of a rigid body to which such events have to be referred. The resulting relationship takes for granted that the laws of Euclidean geometry hold for ‘distances’, the ‘distance’ being represented physically by means of the convention of two marks on a rigid body.

Comrades, revolutionary youths, revolutionary faculty and staff, we must clearly understand the reactionary nature of Einstein’s theory of relativity. This is most apparent in general relativity: Its static model of the universe negates the dynamic nature of matter. It is anti-dialectical! It treats the universe as limited, which is absolutely a form of reactionary idealism.…” As

An observer who is sitting eccentrically on the disc K' is sensible of a force which acts outwards in a radial direction, and which would be interpreted as an effect of inertia (centrifugal force) by an observer who was at rest with respect to the original reference-body K. But the observer on the disc may regard his disc as a reference body which is “at rest”; on the basis of the general principle of relativity he is justified in doing this. The force acting on himself, and in fact on all other bodies which are at rest relative to the disc, he regards as the effect of a gravitational field.

The difference between Lorentz's Transformation in Lorentz's theory and Lorentz's Transformation in Einstein's Special Relativity is not mathematical but ontological and epistemological and, being so, it was to be expected the emergence of historians, scientists, and philosophers that, not having understood in depth the philosophical content and transcendence of the theory, would minimize Einstein's contribution.

There are two foundational pillars upon which modern physics rests. One is Albert Einstein's general relativity, which provides a theoretical framework for understanding the universe on the largest of scales: stars, galaxies, clusters of galaxies, and beyond to the immense expanse of the universe itself. The other is quantum mechanics, which provides a theoretical framework for understanding the universe on the smallest of scales: molecules, atoms, and all the way down to subatomic particles like electrons and quarks. Through years of research, physicists have experimentally confirmed to almost unimaginable accuracy virtually all predictions made by each of these theories. But these same theoretical tools inexorably lead to another disturbing conclusion: As they are currently formulated, general relativity and quantum mechanics cannot both be right.

Descartes, in his Third Meditation, said that God re-created the body at each successive moment. So that time was a form of sustenance. On earth time was marked by the sun and moon, by rotations that distinguished day from night, that had led to clocks and calendars. The present was a speck that kept blinking, brightening and diminishing, something neither alive nor dead. How long did it last? One second? Less? It was always in flux; in the time it took to consider it, it slipped away. In one of her notebooks from Calcutta were jottings in Udayan’s hand, on the laws of classical physics. Newton’s theory that time was an absolute entity, a stream flowing at a uniform rate of its own accord. Einstein’s contribution, that time and space were intertwined. He’d described it in terms of particles, velocities. A system of relations among instantaneous events. Something called time

Time is relative. In human life, time is experience. The faster you archive a significant experience to your memory, the more you live in the same clock time. In physics, experience is represented by the distance traveled, and this entire thing is called the Relativity of Time. I want to age and die through archiving my experiences, not watching my biological clock. Please don't waste my clock time with mediocrity and egotism, let me use it towards serving to others.

Yet, emotionally I could not bring myself to accept either his presence, or his reality. My problem was not a religious problem. God could certainly create as many variations of intelligent humans as he wanted. Presumably God put humans here on this earth, and all non-humans on some other far-away planet orbiting some other far-away star. My problem was a scientific problem. For the Tall White guard to be standing there in the hot sun, for real, would mean that everything I had been taught about Einstein and the Theory of Relativity was simply incorrect.

Evolution endowed us with intuition only for those aspects of physics that had survival value for our distant ancestors, such as the parabolic orbits of flying rocks (explaining our penchant for baseball). A cavewoman thinking too hard about what matter is ultimately made of might fail to notice the tiger sneaking up behind and get cleaned right out of the gene pool. Darwin’s theory thus makes the testable prediction that whenever we use technology to glimpse reality beyond the human scale, our evolved intuition should break down. We’ve repeatedly tested this prediction, and the results overwhelmingly support Darwin. At high speeds, Einstein realized that time slows down, and curmudgeons on the Swedish Nobel committee found this so weird that they refused to give him the Nobel Prize for his relativity theory. At low temperatures, liquid helium can flow upward. At high temperatures, colliding particles change identity; to me, an electron colliding with a positron and turning into a Z-boson feels about as intuitive as two colliding cars turning into a cruise ship. On microscopic scales, particles schizophrenically appear in two places at once, leading to the quantum conundrums mentioned above. On astronomically large scales… weirdness strikes again: if you intuitively understand all aspects of black holes [then you] should immediately put down this book and publish your findings before someone scoops you on the Nobel Prize for quantum gravity… [also,] the leading theory for what happened [in the early universe] suggests that space isn’t merely really really big, but actually infinite, containing infinitely many exact copies of you, and even more near-copies living out every possible variant of your life in two different types of parallel universes.

The fundamental theories of modern physics explain the world in jarringly counter-intuitive ways. For example, most non-physicists consider it self-evident that when you hold your arm out horizontally you can feel the force of gravity pulling it downwards. But you cannot. The existence of a force of gravity is, astonishingly, denied by Einstein’s general theory of relativity, one of the two deepest theories of physics. This says that the only force on your arm in that situation is that which you yourself are exerting, upwards, to keep it constantly accelerating away from the straightest possible path in a curved region of spacetime

Finally, in 1905, he found the answer. His name was Albert Einstein, and his theory was called special relativity. He discovered that you cannot outrace a lightbeam, because the speed of light is the ultimate velocity in the universe. If you approach it, strange things happen. Your rocket becomes heavier, and time slows down inside it. If you were to somehow reach light speed, you would be infinitely heavy and time would stop. Both conditions are impossible, which means you cannot break the light barrier. Einstein became the cop on the block, setting the ultimate speed limit in the universe. This barrier has bedeviled generations of rocket scientists ever since.

Black holes were invented by J. Robert Oppenheimer and Hartland Snyder in 1939. Starting from Einstein's theory of general relativity, Oppenheimer and Snyder found solutions of Einstein's equations that described what happens to a massive star when it has exhausted its supplies of nuclear energy. The star collapses gravitationally and disappears from the visible universe, leaving behind only an intense gravitational field to mark its presence. The star remains in a state of permanent free fall, collapsing endlessly inward into the gravitational pit without ever reaching the bottom. This solution of Einstein's equations was profoundly novel. It has had enormous impact on the later development of astrophysics.

A full explanation of this is beyond the scope of this book, suffice to say that Einstein was forced into this bold move primarily because Maxwell’s equations for electricity and magnetism were incompatible with Newton’s 200-year-old laws of motion. Einstein abandoned the Newtonian ideas of space and time as separate entities and merged them. In Einstein’s theory there is a special speed built into the structure of spacetime itself that everyone must agree on, irrespective of how they are moving relative to each other. This special speed is a universal constant of nature that will always be measured as precisely 299,792,458 metres (983,571,503 feet) per second, at all times and all places in the Universe, no matter what they are doing. This

The importance of experimental proof, on the other hand, does not mean that without new experimental data we cannot make advances. It is often said that science takes steps forward only when there is new experimental data. If this were true, we would have little hope of finding the theory of quantum gravity before measuring something new, but this is patently not the case. Which new data were available to Copernicus? None. He had the same data as Ptolemy. Which new data did Newton have? Almost none. His real ingredients were Kepler's laws and Galileo's results. What new data did Einstein have to discover general relativity? None. His ingredients were special relativity and Newton's theory. It simply isn't true that physics only advances when it is afforded new data.

Some gifted people have all five and some less. Every gifted person tends to lead with one. As I read this list for the first time I was struck by the similarities between Dabrowski’s overexcitabilities and the traits of Sensitive Intuitives. Read the list for yourself and see what you identify with: Psychomotor This manifests as a strong pull toward movement. People with this overexcitability tend to talk rapidly and/or move nervously when they become interested or passionate about something. They have a lot of physical energy and may run their hands through their hair, snap their fingers, pace back and forth, or display other signs of physical agitation when concentrating or thinking something out. They come across as physically intense and can move in an impatient, jerky manner when excited. Other people might find them overwhelming and they’re routinely diagnosed as ADHD. Sensual This overexcitability comes in the form of an extreme sensitivity to sounds, smells, bright lights, textures and temperature. Perfume and scented soaps and lotions are bothersome to people with this overexcitability, and they might also have aversive reactions to strong food smells and cleaning products. For me personally, if I’m watching a movie in which a strobe light effect is used, I’m done. I have to shut my eyes or I’ll come down with a headache after only a few seconds. Loud, jarring or intrusive sounds also short circuit my wiring. Intellectual This is an incessant thirst for knowledge. People with this overexcitability can’t ever learn enough. They zoom in on a few topics of interest and drink up every bit of information on those topics they can find. Their only real goal is learning for learning’s sake. They’re not trying to learn something to make money or get any other external reward. They just happened to have discovered the history of the Ming Dynasty or Einstein’s Theory of Relativity and now it’s all they can think about. People with this overexcitability have intellectual interests that are passionate and wide-ranging and they study many areas simultaneously. Imaginative INFJ and INFP writers, this is you. This is ALL you. Making up stories, creating imaginary friends, believing in Santa Claus way past the ordinary age, becoming attached to fairies, elves, monsters and unicorns, these are the trademarks of the gifted child with imaginative overexcitability. These individuals appear dreamy, scattered, lost in their own worlds, and constantly have their heads in the clouds. They also routinely blend fiction with reality. They are practically the definition of the Sensitive Intuitive writer at work. Emotional Gifted individuals with emotional overexcitability are highly empathetic (and empathic, I might add), compassionate, and can become deeply attached to people, animals, and even inanimate objects, in a short period of time. They also have intense emotional reactions to things and might not be able to stomach horror movies or violence on the evening news. They have most likely been told throughout their life that they’re “too sensitive” or that they’re “overreacting” when in truth, they are expressing exactly how they feel to the most accurate degree.

The reciprocal relationship of epistemology and science is of noteworthy kind. They are dependent upon each other. Epistemology without contact with science becomes an empty scheme. Science without epistemology is—insofar as it is thinkable at all—primitive and muddled. However, no sooner has the epistemologist, who is seeking a clear system, fought his way through to such a system, than he is inclined to interpret the thought-content of science in the sense of his system and to reject whatever does not fit into his system. The scientist, however, cannot afford to carry his striving for epistemological systematic that far. He accepts gratefully the epistemological conceptual analysis; but the external conditions, which are set for him by the facts of experience, do not permit him to let himself be too much restricted in the construction of his conceptual world by the adherence to an epistemological system. He therefore must appear to the systematic epistemologist as a type of unscrupulous opportunist: he appears as realist insofar as he seeks to describe a world independent of the acts of perception; as idealist insofar as he looks upon the concepts and theories as free inventions of the human spirit (not logically derivable from what is empirically given); as positivist insofar as he considers his concepts and theories justified only to the extent to which they furnish a logical representation of relations among sensory experiences. He may even appear as Platonist or Pythagorean insofar as he considers the viewpoint of logical simplicity as an indispensable and effective tool of his research. (Einstein 1949, 683–684)

Although Jung's concept of a collective unconscious has had an enormous impact on psychology and is now embraced by untold thousands of psychologists and psychiatrists, our current understanding of the universe provides no mechanism for explaining its existence. The interconnectedness of all things predicted by the holographic model, however, does offer an explanation. In a universe in which all things are infinitely interconnected, all consciousnesses are also interconnected. Despite appearances, we are beings without borders. Or as Bohm puts it, "Deep down the consciousness of mankind is one. "1 If each of us has access to the unconscious knowledge of the entire human race, why aren't we all walking encyclopedias? Psychologist Robert M. Anderson, Jr., of the Rensselaer Polytechnic Institute in Troy, New York, believes it is because we are only able to tap into information in the implicate order that is directly relevant to our memories. Anderson calls this selective process personal resonance and likens it to the fact that a vibrating tuning fork will resonate with (or set up a vibration in) another tuning fork only if the second tuning fork possesses a similar structure, shape, and size. "Due to personal resonance, relatively few of the almost infinite variety of 'images' in the implicate holographic structure of the universe are available to an individual's personal consciousness, " says Anderson. "Thus, when enlightened persons glimpsed this unitive consciousness centuries ago, they did not write out relativity theory because they were not studying physics in a context similar to that in which Einstein studied physics.

The reason for this is that the universe bends, in a way we can’t adequately imagine, in conformance with Einstein’s theory of relativity (which we will get to in due course). For the moment it is enough to know that we are not adrift in some large, ever-expanding bubble. Rather, space curves, in a way that allows it to be boundless but finite. Space cannot even properly be said to be expanding because, as the physicist and Nobel laureate Steven Weinberg notes, “solar systems and galaxies are not expanding, and space itself is not expanding.” Rather, the galaxies are rushing apart. It is all something of a challenge to intuition. Or as the biologist J. B. S. Haldane once famously observed: “The universe is not only queerer than we suppose; it is queerer than we can suppose.” The analogy that is usually given for explaining the curvature of space is to try to imagine someone from a universe of flat surfaces, who had never seen a sphere, being brought to Earth. No matter how far he roamed across the planet’s surface, he would never find an edge. He might eventually return to the spot where he had started, and would of course be utterly confounded to explain how that had happened. Well, we are in the same position in space as our puzzled flatlander, only we are flummoxed by a higher dimension.

Relativistic twins? When one looks at the paths that Newton and Einstein followed while pursuing their theories of gravity, one is struck by the many similarities: the unexplained data on orbits, the sudden insight about falling objects, the need for a new mathematics, the calculational difficulties, the retroactive agreements, the controversy, the problem-plagued expeditions, and the final triumph and acclaim.. Both men had worked in the same eccentric and lonely way, divorced from other scientists, armed with a great feeling of self-reliance while struggling with new concepts and difficult mathematics, and both produced earth-shaking results. One can't help but wonder if these two greatest of scientists, born 237 years apart, were "relativistically related", conceived as twins in some ethereal plane in a far-off galaxy and sent to earth to solve a matter of some gravity.

as the earth orbits around the sun, different stars appear to pass behind the sun and have their light deflected. They therefore change their apparent position relative to other stars. FIGURE 2.8 It is normally very difficult to see this effect, because the light from the sun makes it impossible to observe stars that appear near to the sun in the sky. However, it is possible to do so during an eclipse of the sun, when the sun’s light is blocked out by the moon. Einstein’s prediction of light deflection could not be tested immediately in 1915, because the First World War was in progress, and it was not until 1919 that a British expedition, observing an eclipse from West Africa, showed that light was indeed deflected by the sun, just as predicted by the theory. This proof of a German theory by British scientists was hailed as a great act of reconciliation between the two countries after the war.

Wars and chaoses and paradoxes ago, two mathematicians between them ended an age d began another for our hosts, our ghosts called Man. One was Einstein, who with his Theory of Relativity defined the limits of man's perception by expressing mathematically just how far the condition of the observer influences the thing he perceives. ... The other was Goedel, a contemporary of Eintstein, who was the first to bring back a mathematically precise statement about the vaster realm beyond the limits Einstein had defined: In any closed mathematical system--you may read 'the real world with its immutable laws of logic'--there are an infinite number of true theorems--you may read 'perceivable, measurable phenomena'--which, though contained in the original system, can not be deduced from it--read 'proven with ordinary or extraordinary logic.' Which is to say, there are more things in heaven and Earth than are dreamed of in your philosophy, Horatio. There are an infinite number of true things in the world with no way of ascertaining their truth. Einstein defined the extent of the rational. Goedel stuck a pin into the irrational and fixed it to the wall of the universe so that it held still long enough for people to know it was there. ... The visible effects of Einstein's theory leaped up on a convex curve, its production huge in the first century after its discovery, then leveling off. The production of Goedel's law crept up on a concave curve, microscopic at first, then leaping to equal the Einsteinian curve, cross it, outstrip it. At the point of intersection, humanity was able to reach the limits of the known universe... ... And when the line of Goedel's law eagled over Einstein's, its shadow fell on a dewerted Earth. The humans had gone somewhere else, to no world in this continuum. We came, took their bodies, their souls--both husks abandoned here for any wanderer's taking. The Cities, once bustling centers of interstellar commerce, were crumbled to the sands you see today.

In my opinion, the black hole is incomparably the most exciting and the most important consequence of general relativity. Black holes are the places in the universe where general relativity is decisive. But Einstein never acknowledged his brainchild. Einstein was not merely skeptical, he was actively hostile to the idea of black holes. He thought that the black hole solution was a blemish to be removed from his theory by a better mathematical formulation, not a consequence to be tested by observation. He never expressed the slightest enthusiasm for black holes, either as a concept or as a physical possibility. Oddly enough, Oppenheimer too in later life was uninterested in black holes, although in retrospect we can say that they were his most important contribution to science. The older Einstein and the older Oppenheimer were blind to the mathematical beauty of black holes, and indifferent to the question whether black boles actually exist. How did this blindness and this indifference come about?

Why does the theory of evolution provoke such objections, whereas nobody seems to care about the theory of relativity or quantum mechanics? How come politicians don’t ask that kids be exposed to alternative theories about matter, energy, space and time? After all, Darwin’s ideas seem at first sight far less threatening than the monstrosities of Einstein and Werner Heisenberg. The theory of evolution rests on the principle of the survival of the fittest, which is a clear and simple – not to say humdrum – idea. In contrast, the theory of relativity and quantum mechanics argue that you can twist time and space, that something can appear out of nothing, and that a cat can be both alive and dead at the same time. This makes a mockery of our common sense, yet nobody seeks to protect innocent schoolchildren from these scandalous ideas. Why? The theory of relativity makes nobody angry, because it doesn’t contradict any of our cherished beliefs. Most people don’t care an iota whether space and time are absolute or relative. If you think it is possible to bend space and time, well, be my guest. Go ahead and bend them. What do I care? In contrast, Darwin has deprived us of our souls. If you really understand the theory of evolution, you understand that there is no soul. This is a terrifying thought not only to devout Christians and Muslims, but also to many secular people who don’t hold any clear religious dogma, but nevertheless want to believe that each human possesses an eternal individual essence that remains unchanged throughout life, and can survive even death intact.

A good question is like the one Albert Einstein asked himself as a small boy—“What would you see if you were traveling on a beam of light?” That question launched the theory of relativity, E=MC2, and the atomic age. A good question is not concerned with a correct answer. A good question cannot be answered immediately. A good question challenges existing answers. A good question is one you badly want answered once you hear it, but had no inkling you cared before it was asked. A good question creates new territory of thinking. A good question reframes its own answers. A good question is the seed of innovation in science, technology, art, politics, and business. A good question is a probe, a what-if scenario. A good question skirts on the edge of what is known and not known, neither silly nor obvious. A good question cannot be predicted. A good question will be the sign of an educated mind. A good question is one that generates many other good questions. A good question may be the last job a machine will learn to do. A good question is what humans are for.

The generalized theory of relativity has furnished still more remarkable results. This considers not only uniform but also accelerated motion. In particular, it is based on the impossibility of distinguishing an acceleration from the gravitation or other force which produces it. Three consequences of the theory may be mentioned of which two have been confirmed while the third is still on trial: (1) It gives a correct explanation of the residual motion of forty-three seconds of arc per century of the perihelion of Mercury. (2) It predicts the deviation which a ray of light from a star should experience on passing near a large gravitating body, the sun, namely, 1".7. On Newton's corpuscular theory this should be only half as great. As a result of the measurements of the photographs of the eclipse of 1921 the number found was much nearer to the prediction of Einstein, and was inversely proportional to the distance from the center of the sun, in further confirmation of the theory. (3) The theory predicts a displacement of the solar spectral lines, and it seems that this prediction is also verified.

The Undivided Wholeness of All Things Most mind-boggling of all are Bohm's fully developed ideas about wholeness. Because everything in the cosmos is made out of the seamless holographic fabric of the implicate order, he believes it is as meaningless to view the universe as composed of "parts, " as it is to view the different geysers in a fountain as separate from the water out of which they flow. An electron is not an "elementary particle. " It is just a name given to a certain aspect of the holomovement. Dividing reality up into parts and then naming those parts is always arbitrary, a product of convention, because subatomic particles, and everything else in the universe, are no more separate from one another than different patterns in an ornate carpet. This is a profound suggestion. In his general theory of relativity Einstein astounded the world when he said that space and time are not separate entities, but are smoothly linked and part of a larger whole he called the space-time continuum. Bohm takes this idea a giant step further. He says that everything in the universe is part of a continuum. Despite the apparent separateness of things at the explicate level, everything is a seamless extension of everything else, and ultimately even the implicate and explicate orders blend into each other. Take a moment to consider this. Look at your hand. Now look at the light streaming from the lamp beside you. And at the dog resting at your feet. You are not merely made of the same things. You are the same thing. One thing. Unbroken. One enormous something that has extended its uncountable arms and appendages into all the apparent objects, atoms, restless oceans, and twinkling stars in the cosmos. Bohm cautions that this does not mean the universe is a giant undifferentiated mass. Things can be part of an undivided whole and still possess their own unique qualities. To illustrate what he means he points to the little eddies and whirlpools that often form in a river. At a glance such eddies appear to be separate things and possess many individual characteristics such as size, rate, and direction of rotation, et cetera. But careful scrutiny reveals that it is impossible to determine where any given whirlpool ends and the river begins. Thus, Bohm is not suggesting that the differences between "things" is meaningless. He merely wants us to be aware constantly that dividing various aspects of the holomovement into "things" is always an abstraction, a way of making those aspects stand out in our perception by our way of thinking. In attempts to correct this, instead of calling different aspects of the holomovement "things, " he prefers to call them "relatively independent subtotalities. "10 Indeed, Bohm believes that our almost universal tendency to fragment the world and ignore the dynamic interconnectedness of all things is responsible for many of our problems, not only in science but in our lives and our society as well. For instance, we believe we can extract the valuable parts of the earth without affecting the whole. We believe it is possible to treat parts of our body and not be concerned with the whole. We believe we can deal with various problems in our society, such as crime, poverty, and drug addiction, without addressing the problems in our society as a whole, and so on. In his writings Bohm argues passionately that our current way of fragmenting the world into parts not only doesn't work, but may even lead to our extinction.

In conclusion, I return to Einstein. If we find a planet in the Alpha Centauri system, its image, captured by a camera travelling at a fifth of light speed, will be slightly distorted due to the effects of special relativity. It would be the first time a spacecraft has flown fast enough to see such effects. In fact, Einstein’s theory is central to the whole mission. Without it we would have neither lasers nor the ability to perform the calculations necessary for guidance, imaging and data transmission over twenty-five trillion miles at a fifth of light speed. We can see a pathway between that sixteen-year-old boy dreaming of riding on a light beam and our own dream, which we are planning to turn into a reality, of riding our own light beam to the stars. We are standing at the threshold of a new era. Human colonisation on other planets is no longer science fiction. It can be science fact. The human race has existed as a separate species for about two million years. Civilisation began about 10,000 years ago, and the rate of development has been steadily increasing. If humanity is to continue for another million years, our future lies in boldly going where no one else has gone before. I hope for the best. I have to. We have no other option.

Germany had been united in empire for only eight years when Einstein was born in Ulm on March 14, 1879. He grew up in Munich. He was slow to speak, but he was not, as legend has it, slow in his studies; he consistently earned the highest or next-highest marks in mathematics and Latin in school and Gymnasium. At four or five the “miracle” of a compass his father showed him excited him so much, he remembered, that he “trembled and grew cold.” It seemed to him then that “there had to be something behind objects that lay deeply hidden.”624 He would look for the something which objects hid, though his particular genius was to discover that there was nothing behind them to hide; that objects, as matter and as energy, were all; that even space and time were not the invisible matrices of the material world but its attributes. “If you will not take the answer too seriously,” he told a clamorous crowd of reporters in New York in 1921 who asked him for a short explanation of relativity, “and consider it only as a kind of joke, then I can explain it as follows. It was formerly believed that if all material things disappeared out of the universe, time and space would be left. According to the relativity theory, however, time and space disappear together with the things.

A century ago, Albert Einstein revolutionised our understanding of space, time, energy and matter. We are still finding awesome confirmations of his predictions, like the gravitational waves observed in 2016 by the LIGO experiment. When I think about ingenuity, Einstein springs to mind. Where did his ingenious ideas come from? A blend of qualities, perhaps: intuition, originality, brilliance. Einstein had the ability to look beyond the surface to reveal the underlying structure. He was undaunted by common sense, the idea that things must be the way they seemed. He had the courage to pursue ideas that seemed absurd to others. And this set him free to be ingenious, a genius of his time and every other. A key element for Einstein was imagination. Many of his discoveries came from his ability to reimagine the universe through thought experiments. At the age of sixteen, when he visualised riding on a beam of light, he realised that from this vantage light would appear as a frozen wave. That image ultimately led to the theory of special relativity. One hundred years later, physicists know far more about the universe than Einstein did. Now we have greater tools for discovery, such as particle accelerators, supercomputers, space telescopes and experiments such as the LIGO lab’s work on gravitational waves. Yet imagination remains our most powerful attribute. With it, we can roam anywhere in space and time. We can witness nature’s most exotic phenomena while driving in a car, snoozing in bed or pretending to listen to someone boring at a party.

Music of the Grid: A Poem in Two Equations _________________________ The masses of particles sound the frequencies with which space vibrates, when played. This Music of the Grid betters the old mystic mainstay, "Music of the Spheres," both in fantasy and in realism. LET US COMBINE Einstein's second law m=E/C^2 (1) with another fundamental equation, the Planck-Einstein-Schrodinger formula E = hv The Planck-Einstein-Schrodinger formula relates the energy E of a quantum-mechanical state to the frequency v at which its wave function vibrates. Here h is Planck's constant. Planck introduced it in his revolutionary hypothesis (1899) that launched quantum theory: that atoms emit or absorb light of frequency v only in packets of energy E = hv. Einstein went a big step further with his photon hypothesis (1905): that light of frequency v is always organized into packets with energy E = hv. Finally Schrodinger made it the basis of his basic equation for wave functions-the Schrodinger equation (1926). This gave birth to the modern, universal interpretation: the wave function of any state with energy E vibrates at a frequency v given by v = E/h. By combining Einstein with Schrodinger we arrive at a marvelous bit of poetry: (*) v = mc^2/h (*) The ancients had a concept called "Music of the Spheres" that inspired many scientists (notably Johannes Kepler) and even more mystics. Because periodic motion (vibration) of musical instruments causes their sustained tones, the idea goes, the periodic motions of the planets, as they fulfill their orbits, must be accompanied by a sort of music. Though picturesque and soundscape-esque, this inspiring anticipation of multimedia never became a very precise or fruitful scientific idea. It was never more than a vague metaphor, so it remains shrouded in equation marks: "Music of the Spheres." Our equation (*) is a more fantastic yet more realistic embodiment of the same inspiration. Rather than plucking a string, blowing through a reed, banging on a drumhead, or clanging a gong, we play the instrument that is empty space by plunking down different combinations of quarks, gluons, electrons, photons,... (that is, the Bits that represent these Its) and let them settle until they reach equilibrium with the spontaneous activity of Grid. Neither planets nor any material constructions compromise the pure ideality of our instrument. It settles into one of its possible vibratory motions, with different frequencies v, depending on how we do the plunking, and with what. These vibrations represent particles of different mass m, according to (*). The masses of particles sound the Music of the Grid.

What matters is not how much we remember, but how we remember. As I see it, intelligence is closely related to creativity, to noticing something new, to making unexpected connections between disparate facts. Isaac Newton’s genius consisted of realizing that what makes an apple fall from a tree is the same force that keeps the moon in its orbit around the earth: gravity. Centuries later, in his general theory of relativity, Albert Einstein uncovered another astounding relationship when he noted that the effect of the force of gravity is indistinguishable from the acceleration of a spaceship in outer space or the tug we feel in an elevator when it starts to move. Attempting to memorize facts by rote does nothing more than distract our attention from what really matters, the deeper understanding required to establish meaning and notice connections—that which constitutes the basis of intelligence. The method of loci does nothing to help us understand the things we memorize; it is just a formula for memorization that, in fact, competes against comprehension. As we saw in the previous chapter, Shereshevskii was able to memorize a list effortlessly using the method of loci, but was incapable of grasping its content enough to pick out the liquids from the list or, on another occasion, to realize that he had memorized a sequence of consecutive numbers. Using the method of loci to store these lists left Shereshevskii no room to make any of the categorizations that we perform unconsciously (person, animal, liquid, etc.) or to find basic patterns in a list of numbers. To be creative and intelligent, we must go beyond merely remembering and undertake completely different processes: we must assimilate concepts and derive meaning. Focusing on memorization techniques limits our ability to understand, classify, contextualize, and associate. Like memorization, these processes also help to secure memories, but in a more useful and elaborate way; these are precisely the processes that should be developed and encouraged by the educational system.

Bohr is really doing what the Stoic allegorists did to close the gap between their world and Homer's, or what St. Augustine did when he explained, against the evidence, the concord of the canonical scriptures. The dissonances as well as the harmonies have to be made concordant by means of some ultimate complementarity. Later biblical scholarship has sought different explanations, and more sophisticated concords; but the motive is the same, however the methods may differ. An epoch, as Einstein remarked, is the instruments of its research. Stoic physics, biblical typology, Copenhagen quantum theory, are all different, but all use concord-fictions and assert complementarities. Such fictions meet a need. They seem to do what Bacon said poetry could: 'give some show of satisfaction to the mind, wherein the nature of things doth seem to deny it.' Literary fictions ( Bacon's 'poetry') do likewise. One consequence is that they change, for the same reason that patristic allegory is not the same thing, though it may be essentially the same kind of thing, as the physicists' Principle of Complementarity. The show of satisfaction will only serve when there seems to be a degree of real compliance with reality as we, from time to time, imagine it. Thus we might imagine a constant value for the irreconcileable observations of the reason and the imagination, the one immersed in chronos, the other in kairos; but the proportions vary indeterminably. Or, when we find 'what will suffice,' the element of what I have called the paradigmatic will vary. We measure and order time with our fictions; but time seems, in reality, to be ever more diverse and less and less subject to any uniform system of measurement. Thus we think of the past in very different timescales, according to what we are doing; the time of the art-historian is different from that of the geologist, that of the football coach from the anthropologist's. There is a time of clocks, a time of radioactive carbon, a time even of linguistic change, as in lexicostatics. None of these is the same as the 'structural' or 'family' time of sociology. George Kubler in his book The Shape of Time distinguished between 'absolute' and 'systematic' age, a hierarchy of durations from that of the coral reef to that of the solar year. Our ways of filling the interval between the tick and tock must grow more difficult and more selfcritical, as well as more various; the need we continue to feel is a need of concord, and we supply it by increasingly varied concord-fictions. They change as the reality from which we, in the middest, seek a show of satisfaction, changes; because 'times change.' The fictions by which we seek to find 'what will suffice' change also. They change because we no longer live in a world with an historical tick which will certainly be consummated by a definitive tock. And among all the other changing fictions, literary fictions take their place. They find out about the changing world on our behalf; they arrange our complementarities. They do this, for some of us, perhaps better than history, perhaps better than theology, largely because they are consciously false; but the way to understand their development is to see how they are related to those other fictional systems. It is not that we are connoisseurs of chaos, but that we are surrounded by it, and equipped for coexistence with it only by our fictive powers. This may, in the absence of a supreme fiction-or the possibility of it, be a hard fate; which is why the poet of that fiction is compelled to say From this the poem springs: that we live in a place That is not our own, and much more, nor ourselves And hard it is, in spite of blazoned days.

(a) A writer always wears glasses and never combs his hair. Half the time he feels angry about everything and the other half depressed. He spends most of his life in bars, arguing with other dishevelled, bespectacled writers. He says very ‘deep’ things. He always has amazing ideas for the plot of his next novel, and hates the one he has just published. (b) A writer has a duty and an obligation never to be understood by his own generation; convinced, as he is, that he has been born into an age of mediocrity, he believes that being understood would mean losing his chance of ever being considered a genius. A writer revises and rewrites each sentence many times. The vocabulary of the average man is made up of 3,000 words; a real writer never uses any of these, because there are another 189,000 in the dictionary, and he is not the average man. (c) Only other writers can understand what a writer is trying to say. Even so, he secretly hates all other writers, because they are always jockeying for the same vacancies left by the history of literature over the centuries. And so the writer and his peers compete for the prize of ‘most complicated book’: the one who wins will be the one who has succeeded in being the most difficult to read. (d) A writer understands about things with alarming names, like semiotics, epistemology, neoconcretism. When he wants to shock someone, he says things like: ‘Einstein is a fool’, or ‘Tolstoy was the clown of the bourgeoisie.’ Everyone is scandalized, but they nevertheless go and tell other people that the theory of relativity is bunk, and that Tolstoy was a defender of the Russian aristocracy. (e) When trying to seduce a woman, a writer says: ‘I’m a writer’, and scribbles a poem on a napkin. It always works. (f) Given his vast culture, a writer can always get work as a literary critic. In that role, he can show his generosity by writing about his friends’ books. Half of any such reviews are made up of quotations from foreign authors and the other half of analyses of sentences, always using expressions such as ‘the epistemological cut’, or ‘an integrated bi-dimensional vision of life’. Anyone reading the review will say: ‘What a cultivated person’, but he won’t buy the book because he’ll be afraid he might not know how to continue reading when the epistemological cut appears. (g) When invited to say what he is reading at the moment, a writer always mentions a book no one has ever heard of. (h) There is only one book that arouses the unanimous admiration of the writer and his peers: Ulysses by James Joyce. No writer will ever speak ill of this book, but when someone asks him what it’s about, he can’t quite explain, making one doubt that he has actually read it.