THE NEW PHYSICS: THE UBIQUITOUS ASYMMETRY

The New Physics: The Ubiquitous Asymmetry

Physics and the Mind

20^th century science, in particular Relativity and Quantum theories, presents us with a world that is hardly the one we intuitively know. The reason is simple: Quantum and Relativity theories deal with the problems of the immensely large or the immensely small. Our brains were built to solve a different class of problems. They were built to deal with midsize, colored objects that move slowly in a three-dimensional space over a span of less than a century.

The vast majority of theories of mind still assume that the world is a Newtonian world of objects, of continuous time, of absolute reality and of force-mediated causality. What that means is very simple: most theories of mind are based on a Physics that has been proven wrong. Newton's Physics does work in many cases, but today we know that it does not work in other cases. We don't know whether mind belongs to the set of cases for which Newton's Physics is a valid approximation of reality, or whether mind belongs to the set of cases for which Newton's Physics yields wrong predictions. Any theory of mind that is based on Newton's Physics is a gamble.

For example, psychologists often like to separate the senses and feelings based on the intuitive fact that the senses gives us a photograph of the world, whereas pleasure and pain are the outcome of an interpretation of the world. When I see an object, I am transferring a piece of reality as it is inside my mind. When I feel pleasure, I am interpreting something and generating a feeling. This separation makes sense only if one assumes that objects do exist. Unfortunately, modern Physics has changed our perception of reality. What exists is a chaos of elementary particles, that our eyes "interpret" as object. A chair is no more real than a feeling of pain. They are both created by my mind. Actually, what exists is truly waves of probabilities, that somehow our brain reduces to objects.

Modern Physics is not necessarily right (although Newton is necessarily wrong on several issues, otherwise Hiroshima would still be standing). But many theories of mind rely on a Physics that, de facto, is either Newton's or is a Physics that has not been invented yet.

The Classical World: Utopia

Since we started with the assumption that our Physics is inadequate to explain at least one natural phenomenon, consciousness, and therefore cannot be "right" (or, at least, complete), it is worth taking a quick look at what Physics has to say about the universe that our consciousness inhabits.

Our view of the world we live in has undergone a dramatic change over the course of this century. Quantum Theory and Relativity Theory have changed the very essence of Physics, painting in front of us a completely different picture of how things happen and why they happen.

Let’s first recapitulate the key concepts of classical Physics. Galileo laid them down in the Sixteenth century. First of all, a body in free motion does not need any force to continue moving. Second, if a force is applied, then what will change is the acceleration, not the velocity (velocity will change as a consequence of acceleration changing). Third, all bodies fall with the same acceleration. A century later, Newton expressed these findings in the elegant form of differential calculus and immersed them in the elegant setting of Euclid's geometry. Three fundamental laws explain all of nature (at least, all that was known of nature at the time). The first one states that the acceleration of a body due to a force is inversely proportional to the body’s "inertial" mass. The second one states that the gravitational attraction that a body is subject to is proportional to its "gravitational" mass. The third one indirectly states the conservation of energy: to every action there is always an equal reaction.

They are mostly rehashing of Galileo’s ideas, but they state the exact mathematical relationships and assign numerical values to constants. They lent themselves to formal calculations because they were based on calculus and on geometry, both formal systems that allowed for exact deduction. By applying Newton’s laws, one can derive the dynamic equation that mathematically describes the motion of a system: given the position and velocity at one time, the equations can determine the position and velocity at any later time. Newton’s world was a deterministic machine, whose state at any time was a direct consequence of its state at a previous time. Two conservation laws were particularly effective in constraining the motion of systems: the conservation of momentum (momentum being velocity times mass) and the conservation of energy. No physical event can alter the overall value of, say, the energy: energy can change form, but ultimately it will always be there in the same amount.

In 1833 the Irish mathematician William Hamilton, building on the 1788 work of the Italian mathematician Luigi Lagrange (the trajectory of an object can be derived by finding the path which minimizes the "action", such action being basically the difference between the kinetic energy and the potential energy), realized something that Newton had only implied: that velocity, as well as position, determines the state of a system. He also realized that the key quantity is the overall energy of the system. By combining these intuitions, Hamilton redefined Newton’s dynamic equation with two equations that derived from just one quantity (the Hamiltonian function, a measure of the total energy of the system), that replaced acceleration (a second-order derivative) with the first-order derivative of velocity, and that were symmetrical (once velocity was replaced by momentum). The bottom line was that position and velocity played the same role and therefore the state of the system could be viewed as described by six coordinates, the three coordinates of position plus the three coordinates of momentum. At every point in time one could compute the set of six coordinates and the sequence of such sets would be the history of the system in the world. One could then visualize the evolution of the system in a six-dimensional space, the "phase" space.

In the 19th century two phenomena posed increasing problems for the Newtonian picture: gases and electromagnetism. Gases had been studied as collections of particles, but, a gas being made of many minuscule particles in very fast motion and in continuous interaction, this model soon revealed to be a gross approximation. The classical approach was quickly abandoned in favor of a stochastic approach, whereby what matters is the average behavior of a particle and all quantities that matter (from temperature to heat) are statistical quantities.

In the meantime, evidence was accumulating that electric bodies radiated invisible waves of energy through space, thereby creating electromagnetic fields that could interact with each other, and that light itself was but a particular case of an electromagnetic field. In the 1860s the British physicist James Maxwell expressed the properties of electromagnetic fields in a set of equations. These equations resemble the Hamiltonian equations in that they deal with first-order derivatives of the electric and magnetic intensities. Given the distribution of electric and magnetic charges at a time, Maxwell’s equations can determine the distribution at any later time. The difference is that electric and magnetic intensities refer to waves, whereas position and momentum refer to particles. The number of coordinates needed to determine a wave is infinite, not six... As a by-product of his equations, Maxwell also discovered that light is an electromagnetic wave.

By then, it was already clear that Science was faced with a dilemma, one which was bound to become the theme of the rest of the century: there are electromagnetic forces that hold together particles in objects and there are gravitational forces that hold together objects in the universe, and these two forces are both inverse square forces (the intensity of the force is inversely proportional to the square of the distance), but the two quantities they act upon (electric charge and mass) behave in a completely different way, thereby leading to two completely different descriptions of the universe.

Another catch hidden in all of these equations was that the beautiful and imposing architecture of Physics could not distinguish the past from the future, something that is obvious to all of us. All of Physics' equations were symmetrical in time. There is nothing in Newton's laws, in Hamilton's laws, in Maxwell's laws or even in Einstein's laws that can discriminate past from future. Physics was reversible in time, something that goes against our perception of the absolute and (alas) irrevocable flow of time.

The Removal of Consciousness

In the process, something else had also happened, something of momentous importance, even though its consequences would not be appreciated for a few centuries. Rene` Descartes had introduced the "experimental method": science has to be based on experiments and proofs. Descartes started out by defining the domain of science. He distinguished between matter and mind, and decided that science had to occupy itself with matter. Therefore the schism was born that would influence the development of human knowledge for the next three centuries: science is the study of nature, and our consciousness does not belong to nature. Galileo improved Descartes' method by fostering the mathematical study of nature. Newton built on Galileo's foundations. Physics, in other words, had been forced to renounce consciousness and developed a sophisticated system of knowledge construction and verification that did not care about, and therefore did not apply to, consciousness. Scientists spoke of "nature" as if it included only inanimate, unconscious objects. No wonder that they ended up building a science that explains all known inanimate, unconscious phenomena, but not consciousness.

The Austrian physicist Erwin Schroedinger, one of the founders of Quantum Physics, identified two fundamental tenets of classical science: object and subject can be separated (i.e., the subject can look at the object as if it were a completely disconnected entity); and the subject is capable of knowing the object (i.e., the subject can look at the object in a way that creates a connection, one leading to knowledge). There is a subtle inconsistency in these two tenets: one denies any connection between subject and object, while the other one states an obvious connection between them.

Entropy: The Curse of Irreversibility

The single biggest change in scientific thinking may have nothing to do with Relativity and Quantum theories: it may well be the discovery that some processes are not symmetric in time. Before the discovery of the second law of Thermodynamics, all laws were symmetric in time, and change could always be bi-directional. Any formula had an equal sign that meant one can switch the two sides at will. We could always replay the history of the universe backwards. Entropy changed all that.

Entropy was "discovered" around 1850 by the German physicist Rudolf Clausius in the process of revising the laws proposed by the French engineer Sadi Carnot, that would become the foundations of Thermodynamics. The first law of Thermodynamics is basically the law of conservation of energy: energy can never be created or destroyed, it can only be transformed. The second law states that any transformation has an energetic cost: this "cost" of transforming energy Clausius called "entropy" (which is numerically obtained by dividing heat by temperature). Natural processes generate entropy. Entropy explains why heat flows spontaneously from hot to cold bodies, but the opposite never occurs: "useful" energy can be lost in entropy, not viceversa. There can never be an isolated process that results in a transfer of energy from a cold body to a hotter body: it is just a feature of our universe.

The first law talks about the quantity of energy, while the second law talks about the quality of such energy. Energy is always conserved, but something happens to it that causes it to "deteriorate". Entropy measures the amount of energy that has deteriorated (is not available anymore for further work).

Clausius summarized the situation like this: the energy of the universe is constant, the entropy of the universe is increasing.

In the 1870s, the German physicist Ludwig von Boltzmann tried to deduce entropy from the motion of gas particles, i.e. from dynamic laws that are reversible in nature. Basically, Boltzmann tried to prove that entropy (and therefore irreversibility) is an illusion, that matter at microscopic level is fundamentally reversible. Convinced that bodies are made of a large number of elementary particles, Boltzmann used statistics and probability theory to summarize their behavior, since it would be impossible to describe each particle’s motion and their innumerable interactions. He noticed that many different configurations (microstates) of those particles could lead to the same external appearance (macrostate) of the system as a whole.

Boltzmann ended up with a statistical definition of entropy to characterize the fact that many different microscopic states of a system result in the same macroscopic state: the entropy of a macrostate is the logarithm of the number of its microstates. It is not very intuitive how this definition of entropy relates to the original one, but it does.

Boltzmann’s definition emphasized that entropy turns out to be also a measure of "disorder" in a system: an ordered system has fewer microstates corresponding to a given macrostate.

The second law of Thermodynamics is an inequality: it states that entropy can never decrease. Indirectly, this law states that transformation processes cannot be run backward, cannot be "undone". Young people can age, but old people cannot rejuvenate. Buildings do not improve over the years: they decay. Scrambled eggs cannot be unscrambled and dissolved sugar cubes cannot be recomposed. The universe must evolve in the direction of higher and higher entropy. Some things are irreversible.

Newton’s equations are symmetric in time, which means that theoretically the same process can run backwards. It is the second law of Thermodynamics makes it impossible to go back in time, that introduces an "arrow" of time.

The universe as a whole is proceeding towards its unavoidable fate: the "heat death", i.e. the state of maximum entropy, in which no heat flow is possible, which means that temperature is constant everywhere, which means that there is no energy available to produce more heat, which means that all energy in the universe is in the form of heat. (An escape from the heat death would be if the energy in the universe were infinite).

Scientists were (and still are) puzzled by the fact that irreversibility (the law of entropy) had been deduced from reversibility (basically, Newton's laws). Mechanical phenomena tend to be reversible in time, whereas thermodynamic phenomena tend to be irreversible in time. Since a thermodynamic phenomenon is made of many mechanical phenomena, the paradox is how can an irreversible process arise from many reversible processes? It is weird that irreversibility should arise from the behavior of molecules which, if taken individually, obey physical laws that are reversible. We can keep track of the motion of each single particle in a gas, and then undo it. But we cannot undo the macroscopic consequence of the motion of thousands of such particles in a gas.

If one filmed the behavior of each particle of a gas as the gas moves from non-equilibrium to equilibrium, and then played back the film backwards, the film would be perfectly consistent with the laws of Mechanics. In practice, though, systems never spontaneously move from equilibrium to non-equilibrium: the film is perfectly feasible, but in practice it is never made.

The only reason one could find was probabilistic, not mechanical: the probability of low-entropy macrostates is smaller, by definition, than the probability of high-entropy macrostates, so the universe tends to proceed towards higher entropy. Thus the second law seems to express the tendency of systems to transition from less probable states (states that can be realized by few microstates) to more probable states (states that can be realized by many microstates). Basically, there are more ways to be disorderly than to be orderly.

And one can rephrase the same idea in terms of equilibrium: since equilibrium states are states that correspond to the maximum number of microstates, it is unlikely that a system moves to a state of non-equilibrium, likely that it moves to a state of equilibrium.

The trick is that Boltzmann assumed that a gas (a discrete set of interacting molecules) can be considered as a continuum of points and, on top of that, that the particles can be considered independent of each other: if these arbitrary assumptions are dropped, no rigorous proof for the irreversibility of natural processes exists. The French mathematician Jules Henri Poincare', for example, proved just about the opposite: that every closed system must eventually revert in time to its initial state (the "recurrence theorem"). Thus everything that can happen "will" happen, and will happen infinite times. Poincare' proved eternal recurrence where Thermodynamics had just proved eternal doom.

Entropy is a measure of disorder, and information is found in disorder (the more microstates the more information, ergo the more disorder the more information), so ultimately entropy is also a measure of information.

Later, several scientists interpreted entropy as a measure of ignorance about the microscopic state of a system, for example as a measure of the amount of information needed to specify it. Murray Gell-mann summarized these arguments when he gave his explanation for the drift of the universe towards disorder. The reason that nature prefers disorder over order is that there are many more states of disorder than of order, therefore it is more probable that the system ends up in a state of disorder. In other words, the probability of disorder is much higher than the probability of spontaneous order, and that's why disorder happens more often than disorder.

It took the Belgian (but Russian-born) physicist and Nobel-prize winner Ilya Prigogine, in the 1970s, to provide a more credible explanation for the origin of irreversibility. He observed some inherent time asymmetry in chaotic processes at the microscopic level, which would cause entropy at the macroscopic level. He reached the intriguing conclusion that irreversibility originates from randomness which is inherent in nature.

Equilibrium states are also states of minimum information (a few parameters are enough to identify the state, e.g. one temperature value for the whole gas at a uniform temperature). Information is negative entropy and this equivalence would play a key role in applying entropy beyond Physics.

Note that Boltzmann’s reformulation of the second law was probabilistic: it explained the entropy of the system as a property about a population of particles, not just one particle. The second law does not claim that every single particle is subject to it, but that closed systems (made of many particles) are subject to it. An individual particle may well be violating the second law for a few microseconds, but the millions of particles that make up a system will obey it (just like one person might win at the roulette once, but that episode does not change the statistical law that people lose money at the roulette). In 2002 Australian researchers, in fact, showed that microscopic systems may spontaneously become more orderly for short periods of time.

An Accelerated World

Science has been long obsessed with acceleration. Galileo and Newton went down into history for managing to express that simple concept of acceleration. After them Physics assumed that an object is defined by its position, its velocity (i.e., the rate at which its position changes) and its acceleration (i.e., the rate at which its velocity changes). The question is: why stop there? Why don't we need the "rate an object changes its acceleration" and so forth? Position is a space coordinate. Velocity is the first derivative with respect to time of a space coordinate. Acceleration is the second derivative with respect to time of a space coordinate. Why do we only need two orders of derivative to identify an object, and not three or four or twenty-one?

Because the main force we have to deal with is gravity, and it only causes acceleration. We don't know any force that causes a change in acceleration, therefore we are not interested in higher orders of derivatives. To be precise, forces are defined as things that cause acceleration, and only acceleration (as in Newton's famous equation "F=ma"). We don't even have a word for things that would cause a third derivative with respect to time of a space coordinate.

As a matter of fact, Newton explained acceleration by introducing gravity. In a sense Newton found more than just a law of Physics, he explained a millenary obsession: the reason mankind had been so interested in acceleration is that there is a force called gravity that drives the whole world. If gravity did not exist, we would probably never have bothered to study acceleration. Car manufacturers would just tell customers how long it takes for their car to reach such and such a speed. Acceleration would not even have a name.

Relativity: The Primacy of Light

The Special Theory of Relativity was born (in 1905) out of Albert Einstein’s belief that the laws of nature must be uniform, whether they describe the motion of bodies or the motion of electrons. Therefore, Newton’s equations for the dynamics of bodies and Maxwell’s equations for the dynamics of electromagnetic waves had to be unified in one set of equations. In addition, they must be the same in all frames of reference that are "inertial", i.e. whose relative speed is constant. Galileo had shown this to be true for Newton's mechanics, and Einstein wanted it to be true for Maxwell's electromagnetism as well. In order to do that, one must modify Newton’s equations, as the Dutch physicist Hendrik Lorentz had already pointed out in 1892. The implications of this unification are momentous.

Relativity conceives all motions as "relative" to something. Newton's absolute motion, as the Moravian physicist Ernst Mach had pointed out over and over, is an oxymoron. Motion is always measured relative to something. Best case, one can single out a privileged frame of reference by using the stars as a meta-frame of reference. But even this privileged frame of reference (the "inertial" one) is still measured relative to something, i.e. to the stars. There is no frame of reference that is at rest, there is no "absolute" frame of reference. While this is what gave Relativity its name, much more "relativity" was hidden in the theory.

In Relativity, space and time are simply different dimensions of the same space-time continuum (as stated in 1908 by the Russian mathematician Hermann Minkowski). Einstein had shown that the length of an object and the duration of an event are relative to the observer. This is equivalent to calculating a trajectory in a four-dimensional spacetime that is absolute. The spacetime is the same for all reference frames and what changes is the component of time and space that is visible from your perspective.

All quantities are redefined in space-time and must have four dimensions. For example, energy is no longer a simple (mono-dimensional) value, and momentum is no longer a three-dimensional quantity: energy and momentum are one space-time quantity which has four dimensions. Which part of this quantity is energy and which part is momentum depends on the observer: different observers see different things depending on their state of motion, because, based on their state of motion, a four-dimensional quantity gets divided in different ways into an energy component and a momentum component. All quantities are decomposed into a time component and a space component, but how that occurs depends on the observer’s state of motion.

This phenomenon is similar to looking at a building from one perspective or another: what we perceive as depth, width or height, depends on where we are looking from. An observer situated somewhere else will have a different perspective and measure different depth, width and height. The same idea holds in space-time, except that now time is also one of the quantities that change with "perspective" and the motion of the observer (rather than her position) determines what the "perspective" is. This accounts for bizarre distortions of space and time: as speed increases, lengths contract and time slows down (the first to propose that lengths must contract was, in 1889, the Irish physicist George Fitzgerald, but he was thinking of a physical contraction of the object, and Lorentz endorsed it because it gave Maxwell's equations a particularly elegant form, whether the observer was at rest or in motion). This phenomenon is negligible at slow speeds, but becomes very visible at speeds close to the speed of light.

An observer who travels away from a clock-tower at the speed of light, would always observe the same time, as if the clock's hands never moved and time was still. If the observer traveled at a speed slightly less than the speed of light, the observe would see the hands of the clock moving very slowly over the years as the light would take a long time to travel that distance. On the other hand an observer who travels very slowly away from the same clock-tower (all of us on human-made vehicles), would observe the clock's hands moving. Therefore time depends on the speed of the observer relative to the clock (or viceversa). A moment of time is slower at higher speed. Time intervals are dilated by higher speeds.

A further implication is that "now" becomes a meaningless concept: one observer's "now" is not another observer's "now". Two events may be simultaneous for one observer, while they may occur at different times for another observer: again, their perspective in space-time determines what they see. The traditional law of causality is an illusion. Two events that follow each other from an observer's point of view may be simultaneous from the point of view of another observer who is moving at a different speed.

The present is a concept that depends on the observer. Each observer has a different set of contemporary events that constitute its present.

Even the very concept of the flow of time is questionable. There appears to be a fixed space-time, and the past determines the future. Actually, there seems to be no difference between past and future: again, it is just a matter of perspective.

Time and space complement each other: as one dilates, the other one contracts. The traditional law of causality had ceased to exist, but a new sort of causality was introduced because any warping of space corresponded to a warping of time.

Mass and energy are not exempted from "relativity". The mass and the energy of an object increase as the object speeds up. This principle violates the traditional principle of conservation, which held that nothing can be destroyed or created, but Einstein proved that mass and energy can transform into each other according to his famous formula (a particle at rest has an energy equal to its mass times the speed of light squared), and a very tiny piece of matter can release huge amounts of energy. Scientists were already familiar with a phenomenon in which mass seemed to disappear and correspondingly energy seemed to appear: radioactivity, discovered in 1896. But Einstein's conclusion that all matter is energy was far more reaching.

Light has a privileged status in Relativity Theory. The reason is that the speed of light is always the same, no matter what. If one runs at the same speed of a train, one sees the train as standing still. On the contrary, if one could run at the speed of light, one would still see light moving at the speed of light. Most of Relativity's bizarre properties are actually consequences of this postulate. Einstein had to adopt the Lorentz transformations of coordinates, which leave the speed of light constant in all frames of reference, regardless of the speed it is moving at, but in order to achieve this result must postulate that moving bodies contract and moving clocks slow down by an amount that depends on their speed.

If all this sounds unrealistic, remember that according to traditional Physics the bomb dropped on Hiroshima should have simply bounced, whereas according to Einstein’s Relativity it had to explode and generate a lot of energy. That bomb remains the most remarkable proof of Einstein’s Relativity. Nothing in Quantum Theory can match this kind of proof.

Life On A World Line

The speed of light is finite and one of Relativity’s fundamental principles is that nothing can travel faster than light. As a consequence, an object located in a specific point at a specific time will never be able to reach space-time areas of the universe that would require traveling faster than the light.

The "light cone" of a space-time point is the set of all points that can be reached by all possible light rays passing through that point. Because the speed of light is finite, that four-dimensional region has the shape of a cone (if the axis for time is perpendicular to the axes for the three spatial dimensions). The light cone represents the potential future of the point: these are all the points that can be reached in the future traveling at the speed of light or slower. By projecting the cone backwards, one gets the light cone for the past. The actual past of the point is contained in the past light cone and the actual future of the point is contained in the future light cone. What is outside the two cones is unreachable to that point. And, viceversa, no event located outside the light cone can influence the future of that point. The "event horizon" of an observer is a space-time surface that divides space-time into regions which can communicate with the observer and regions which cannot.

The "world line" is the spatiotemporal path that an object is actually traveling through space-time. That line is always contained inside the light cone.

Besides the traditional quantity of time, Relativity Theory introduces another type of time. "Proper" time is the space-time distance between two points on a world line, because that distance turns out to be the time experienced by an observer traveling along that world line.

Relativity erased the concept of an absolute Time, but in doing so it established an even stronger type of determinism. It feels like our lives are rigidly determined and our task in this universe is simply to cruise on our world line. There is no provision in Relativity for free will.

General Relativity: Gravity Talks

Newton explained how gravity works, but not what it is.

Einstein’s Relativity Theory is ultimately about the nature of gravitation, which is the force holding together the universe. Relativity explains gravitation in terms of curved space-time, i.e. in terms of geometry.

The fundamental principle of this theory (the "principle of equivalence") is actually quite simple: any referential frame in free fall is equivalent to an inertial reference frame. That is because if you are in a free fall, you cannot perceive your own weight, i.e. gravity (gravity is canceled in a frame of reference which is free falling, just like the speed of an object is canceled in a frame of reference which is moving at the same speed). The laws of Special Relativity still apply.

Einstein's principle of equivalence simply expresses the fact that gravitation and acceleration are equivalent. If you can't see what is going on, and all you can measure is the 9.8 m/sec² acceleration of an object that you let fall, you can't decide whether you are standing still, and subject to Earth’s gravity, or you are accelerating in empty space. All you observe is an acceleration of 9.8. If you are still, that's the acceleration you expect for any falling object. If you are in a rocket that is accelerating upwards at 9.8, that's the acceleration you expect for any falling object. Unless you can see, you cannot know which one it is. The effect is the same. Therefore, Einstein concluded, you can treat them as one: gravity and acceleration are equivalent.

Since gravitation is natural motion, Einstein’s idea was to regard free falls as natural motions, i.e. as straight lines in spacetime. The only way to achieve this was to assume that the effect of a gravitational field is to produce a curvature of space-time: the straight line becomes a "geodesic", the shortest route between two points on a warped surface (if the surface is flat, then the geodesic is a straight line). Bodies not subject to forces other than a gravitational field move along geodesics of space-time.

The curvature of space-time is measured by a "curvature tensor" originally introduced in 1854 by the German mathematician Bernhardt Riemann. The Riemann geometry comprises the classical Euclidean geometry as a special case, but it is much more general.

Minkowsky's four-dimensional spacetime is characterized by a "metrics". A metrics is a 4x4 matrix, each row and column representing one of the dimensions. The metrics for Newton's spacetime has zeros everywhere except in the diagonal of the matrix. The diagonal has values 1,1,1 and -1. This means that Pitagora's theorem still works, and time is an added dimension. The zeros in the other positions of the matrix specify that the space is flat. When the ones and the zeros change, their values specify a curvature for spacetime. Euclidean geometry works only with the flat-space metrics. Riemann's geometry works with any combination of values, i.e. with any degree and type of curvature.

A specific consequence of Riemann's geometry is that "force" becomes an effect of the geometry of space. A "force" is simply the manifestation of a distortion in the geometry of space. Wherever there is a distortion, a moving object feels a "force" affecting its motion. Riemann's geometry is based on the notion of a "metric (or curvature) tensor", that expresses the curvature of space. On a two-dimensional surface each point is described by three numbers. In a four-dimensional world, it takes ten numbers at each point. This is the metric tensor. Euclid's geometry corresponds to one of the infinite possible metric tensors (the one that represents zero curvature).

Not only space and time are relative, but space-time is warped.

With his 1915 field equations, Einstein made the connection with the physical world: he related the curvature of space-time caused by an object to the energy and momentum of the object (precisely, the curvature tensor to the "energy-momentum tensor"). Einstein therefore introduced two innovative ideas: the first is that we should consider space and time together (three spatial dimensions and one time dimension), not as separate; the second is that what causes the warps in this space-time (i.e., what alters the metric from Euclid's geometry) is mass. A mass does not voluntarily cause gravitational effects: a mass first deforms space-time and that warping will affect the motion of other objects that will therefore be indirectly feeling the "gravitational force" of that mass.

The mass also has an effect on the "time" part of space-time: clocks in stronger gravitational fields (bigger warp) slow down compared with clocks in weaker gravitational fields (smaller warp).

Summarizing: the dynamics of matter is determined by the geometry of space-time, and that geometry is in turn determined by the distribution of matter. Space-time acts like an intermediary device that relays the existence of matter to other matter.

General Relativity can in fact be understood as a theory of dynamically evolving relationships (as Julian Barbour did).

Incidentally, this implies that mass-less things are also affected by gravitation. This includes light itself: a light beam is bent by a gravitational field. Light beams follow geodesics, which may be bent by a space-time warp.

Special Relativity asked the laws of nature be the same in all inertial frames; which implied that they had to be invariant with respect to the Lorentz transformations. As a consequence, Einstein had to accept that clocks slow down and bodies contract. With General Relativity he wanted laws of nature to be the same in all frames, inertial or not (his field equations basically removed the need for inertial frames). This implies that the laws of nature must be "covariant" (basically must have the same form) with respect to a generic transformation of coordinates. That turned out to imply a further erosion of the concept of Time: it turned out that clocks slow down just for being near a gravitational field.

While apparent paradoxes (such as the twins paradox) have been widely publicized, Relativity Theory has been amazingly accurate in its predictions and so far no serious blow has been dealt to its foundations. While ordinary people may be reluctant to think of curved spaces and time dilatations, all these phenomena have been corroborated over and over by countless experiments.

Twins

The paradox of the twins (devised by Einstein in person) is due to the fact that... everything is relative. If a twin leaves the Earth, travels to another planet with a speed close to the speed of light, and comes back to the Earth, this twin will be younger than the one that stayed on Earth. The reason is that clocks slow down as speed increases (time dilation).

However, according to Relativity, one can also run the experiment the other way around: from the point of view of the twin that departs the Earth, it is the Earth that travels away and then comes back. In this case, the twin to travel at high speed, and therefore who is younger, is the twin who stayed on the Earth. Thus the second twin is younger if measured from the first twin, but the first twin is younger if measured from the second twin: these measurements cannot be both true at the same time. Depending on which reference frame you use, you get two contradictory results.

Einstein solved the paradox by pointing out that the two situations are not symmetric. The twin who leaves the Earth has to apply an acceleration to get out of the Earth; then decelerate, turn and accelerate again to return to the Earth. All of this violates the principle of Relativity: the twin that departed the Earth has done something absolute.

Even if one assumes that the twin does not accelerate and decelerate, the fact remains that it changes direction. In a sense, there are three (not just two) inertial frames: the twin that stays on Earth, the twin that travels away from the Earth, and the twin that travels towards the Earth. Thus the elapsed time for the first twin is calculated by adding up two motions referred to the same frame (the Earth), whereas the elapsed time for the second twin must be calculated by adding up two motions referred to two different frames (the one moving away from the Earth and the one moving towards the Earth). Thus there is an absolute difference between the first twin measuring the second twin and the second twin measuring the first twin. The twin to be younger is the one leaving the Earth.

That said, it is important to remember that this "being younger" has nothing to do with bodily aging: it is only referred to time measured by clocks.

You can in fact dream up several "paradoxes" based on the same idea of going back and forth. Imagine, for example, that I cut a 1 cm circular hole from a sheet of paper. Now I move the sheet of paper far away, and move the circular piece high up in the air. Then I move the sheet of paper at very high speed towards the point where it will meet the circular piece that I am letting fall at some instant to perfectly hit the hole. From the point of view of the circular piece, the sheet of paper is traveling at a very high speed, therefore it is shrinking, and, in particular, the hole in the middle is shrinking: therefore the circular piece will no longer be able to go through the hole. From the point of view of the sheet of paper, it is the circular piece that is traveling at very high speed, and thus shrinking: therefore the circular piece will easily pass through the hole. Imagine if instead of paper, you used spaceships: depending on which reference frame you use, the spaceships collide or they smoothly pass each other. This is not just a detail.

The solution of this second paradox is similar to the first one: we have done something at the very beginning, i.e. moving the sheet of paper far away. No matter how slowly we did that, we caused a change in its size relative to the circular hole (and viceversa). Thus, when we start moving the sheet of paper in the opposite direction, we cannot use its original size to compute the shrinking. When the sheet of paper and the circular piece meet, they are again the exact same size that they were at the beginning of the experiment.

Relativistic Cosmology

Einstein’s equations described more than just the interaction between two bodies (like Newton’s gravitational equations did): they described the very story of the universe. One could play that film backwards or forward, and derive how the universe used to be or what it will be like.

Einstein briefly toyed with the idea of a "cosmological constant". He was not happy to discover that his equations predicted a universe in continuous turmoil (and most likely doomed to collapse under the effect of gravitation), so he introduced a constant in his equations to counterbalance gravitation (basically, a sort of "anti-gravity")and make the universe static. When Edwin Hubble showed that the universe was expanding, Einstein realized that the turmoil was real and decided that there was no need for his cosmological constant.

Density of mass plays a crucial role in Einstein’s equations: the denser the mass, the bigger the warp it causes to space-time, the stronger the gravitational effect felt by nearby matter. Thus collapsing stars are particularly relevant objects in Einstein’s universe. In 1967, the first "pulsar" was observed: a rapidly-spinning collapsed star.

Shortly after Einstein published his gravitational field equation, in 1916 the German physicist Karl Schwarzschild found a solution that determines the gravitational field for any object, given its mass and its size. That solution goes to infinity for a specific ratio between mass and size: basically, if the object is dense enough (lots of mass in a tiny size), the gravitational attraction it generates is infinite. Nothing, not even light, can escape this object, which was therefore named "black hole" (by John Wheeler). And everything that gets near it is doomed to fall into it, and be trapped in it forever.

Quantum Theory: The Wave

Quantum Theory was the logical consequence of two discoveries. In 1900 the German physicist Max Planck solved the mystery of radiation emitted by heated objects (that Newton’s physics failed to explain): he realized that atoms can emit energy only in discrete amounts. Nature seemed to forbid exchanges of energy in between those discrete values.

In 1913 the Danish physicist Niels Bohr solved another mystery, the structure of the atom: electrons turn around the nucleus and are permitted to occupy only some orbits. (or, better, the angular momentum of an electron occurs only in integer multiples of a constant, which happens to be proportional to Planck’s constant). Again, Nature seemed to forbid existence in between orbits. The electron "jumps" from one orbit to another orbit without ever being in the space in between the two orbits (as if it stopped existing in the old orbit and was suddenly created again in the next orbit).

In 1925 George Uhlenbeck and Samuel Goudsmit discovered that each electron "spins" with an angular momentum of one half Planck constant. The "spin" does not vary: the electron always rotates with the same "spin". It would turn out that every particle has its own spin, and the spin for any kind of particle is always the same.

The fundamental assumption of Quantum Theory is that any field of force manifests itself in the form of discrete particles (or "quanta"). Forces are manifestations of exchanges of discrete amounts of energy. For example, electromagnetic waves carry an energy which is an integer multiple of a fundamental constant, the "Planck constant".

A way to solve the apparent paradox of Bohr’s electrons was discovered by the French physicist Louis DeBroglie in 1923 (after Einstein had made the same assumption regarding light): if an electron is viewed as a wave spreading over many orbits, the electron does not need to "jump" from one orbit to another. The electron "is" in all orbits at the same time, to some degree. DeBroglie proved that the equation for a standing wave matched the behavior of the electron. That equation expressed a relationship between quantities of matter (e.g., speed) and quantities of waves (e.g., wavelength). Thus he concluded that waves and particles are dual aspects of the same phenomena: every particle behaves like a wave. One can talk of energy and mass (quantities previously associated only to matter), or one can talk of frequency and wavelength (quantities previously associated only to waves). The two descriptions are equivalent, or, better, one complements the other. It didn’t take long to observe "interference patterns" (typical of waves) among streams of electrons, and therefore confirm DeBroglie’s theory. Einstein’s Relativity had shown that energy and matter were dual aspects of the same substance. DeBroglie showed that particles and waves were dual aspects of the same phenomenon.

The character of this relationship was defined in 1925 by Werner Heisenberg in Germany and Erwin Schroedinger in Austria. Both devised equations that replaced the equations of Newton's physics, but both equations had unpleasant consequences: Heisenberg's equations implied that the result of a physical experiment depends on the order in which the calculations were performed, and Schroedinger's equations implied that each particle could only really be considered a wave. Schroedinger wanted to remove the discrete jumps and restore the continuum of classical Physics. His equation, after all, simply replaces Newton's (or, better, Hamilton's) equations and predicts the state of the system at a later time given the current state; except that his "system" is not a confined object but a wave. He thought of the wave as describing the location of the object (i.e., the object being spread out in space). However, experiments showed that the object (e.g., the electron) was a very confined object (just like in classical Physics) while Schroedinger's equation described it as a wave spread out in space. In 1926 Max Born realized the implications of the wave-particle duality: the wave associated to a particle turns out to be a "wave of probabilities", that accounts for the alternative possibilities that open up for the future of a particle. In other words, the wave summarizes the possible values for the electron’s attributes (e.g., position, energy, spin) and how those values may evolve over time (the square of the wave’s amplitude represents the probability of finding a given value for an attribute when measuring that attribute). In particular, Schroedinger’s wave is not a representation of where the object is spread out but of all the places where the object could possibly be, each to a certain degree of probability.

The state of a particle is described by this "wave function" which summarizes (and superposes) all the alternatives and their probabilities. The wave function contains all the information there is about the particle (or, in general, about a system). It contains the answers to all the questions that can be asked about the particle.

The reason this is a "wave" of probabilities and not just a set of probabilities is that Schroedinger’s equation that describes it is the equation of an electromagnetic wave.

Schroedinger's equation describes how this wave function evolves in time, and is therefore the quantum equivalent of Hamilton's equations. The Schroedinger equation fixes, deterministically, the temporal development of the state of the universe. But at every point in time the wave function describes a set of possibilities, not just one actuality. The particle’s current state is actually to be thought of as a "superposition" of all those alternatives that are made possible by its wavelike behavior. A particle's current state is, therefore, a number of states: one can view the particle as being in all of those states at the same time. This is a direct consequence of a particle not being just a particle but being also a wave.

As Born phrased it, the motion of particles follows the law of probabilities, but the probability itself follows the law of causality.

In 1927 Bohr stated the ultimate paradox of the wave-particle duality: everything is both particle and wave, but one must choose whether to measure one or the other aspect of nature, and then stick to it. If you try to mix the two, you run into contradictions.

The Planck Constant

Of course, one explanation begs for another one: introducing the Planck constant helps explain phenomena that Newton could not explain, but the mystery now is the Planck constant itself: what is it, what does it represent? Newton’s physics (as well as Einstein’s physics) assumed that the most fundamental units of the universe were the point and the instant. Quantum Theory introduces a fundamental unit that is bigger than a point and an instant, and seems to be as arbitrarily finite as Newton’s points were infinitesimally small. Unlike Newton’s points and instants, that have no size, the Planck constant has a size: a length, height and width of 10^-33 centimeters and a time interval of 10^-43 seconds.

Einstein had warped space and time, but Quantum Theory did worse: it turned them into grids. (One could even argue that the very notion of measuring a distance such as "10^-33 centimeters" depends on Newton’s concept of space, and thus we don’t quite know what we mean when we say that Planck’s length is "10^-33 centimeters").

Enter Uncertainty

In classical Physics, a quantity (such as the position or the mass) is both an attribute of the state of the system and an observable (a quantity that can be measured by an observer). Quantum Theory makes a sharp distinction between states and observables. If the system is in a given state, an observable can assume a range of values (so called "eigenvalues"), each one with a given probability. The evolution over time of a system can be viewed as due (according to Heisenberg) to time evolution of the observables or (according to Schroedinger) to time evolution of the states.

An observer can measure at the same time only observables that are compatible. If the observables are not compatible, they stand in a relation of mutual indeterminacy: the more accurate a measurement of the one, the less accurate the measurement of the other. Position and momentum are, for example, incompatible. This is a direct consequence of the wave-particle dualism: only one of the two natures is "visible" at each time. One can choose which one to observe (whether the particle, that has a position, or the wave, that has a momentum), but cannot observe both aspects at the same time.

Precisely, Heisenberg’s famous "uncertainty principle" states that there is a limit to the precision with which we can measure, at the same time, the momentum and the position of a particle. If one measures the momentum, then it cannot measure the position, and viceversa. This is actually a direct consequence of Einstein's equation that related the wavelength and the momentum (or the frequency and the energy) of a light wave: if coordinates (wavelength) and momentum are related, they are no longer independent quantities. Einstein never believed in this principle, but he was indirectly the one who discovered it.

The wave function contains the answers to all the questions that can be asked about a system, but not all those questions can be asked simultaneously. If they are asked simultaneously, the replies will not be precise.

The degree of uncertainty is proportional to the Planck constant. This implies that there is a limit to how small a physical system can be, because, below a quantity proportional to the Planck constant and called "Planck length", the physical laws of Quantum Theory stop working altogether. The Planck scale (10^–33cm, i.e. the shortest possible length, and 10^–43sec, i.e. the time it takes for a light beam to cross the Planck length, i.e. the shortest possible time tick) is the scale at which space-time is no longer a continuum but becomes a grid of events separated by the Planck distance. What happens within a single cell of the grid, is beyond the comprehension of Physics. As the USA physicist John Wheeler suggested in the 1950s, even the very notions of space and time stop making sense in this "quantum foam".

Note that Heisenberg does not forbid precise measurements of "compatible observables", for example of position, charge and spin. It only applies to "incompatible observables", which are couples: position/momentum, energy/time, electric field/magnetic field, angle/angular momentum, etc.

One cannot measure exactly both the position and the momentum (speed) of a particle at the same time. A consequence of Heisenberg's principle is that no particle can be completely at rest. If a particle were at rest, then both its position and its speed would be measured exactly (both being zero), a fact that would contradict Heisenberg. Even if the particle has absolutely no energy, there would still be some random form of motion (the "zero-point motion").

By the same token, one cannot measure the electrical and the magnetic field simultaneously with absolute precision. The more accurate one measurement is, the less accurate the other one is. Even if one removed all the energy from the vacuum, there would still be some random fluctuations of the electrical and/or magnetic fields, the "quantum vacuum fluctuations".

The uncertainty predicted by Quantum Theory (and verified by countless experiments in countless laboratories) has been sometimes interpreted as a consequence of the fact that, at the microscopic level, one cannot pretend that a measurement is "objective" at all: a measurement is an interaction between two systems, which, like all interactions, affects both. But that is not quite where Heisenberg’s calculations came from. They originate, as everything else, from Planck’s constant.

Zero-Point Energy

As a consequence of quantum uncertainty, Planck and Heisenberg proved that at that scale, the vacuum of empty space is actually "full" of all sorts of subtle events.

In 1948 the Dutch physicist Hendrick Casimir even showed how this all-pervading zero-point energy could be measured (thus it is now known as "Casimir force").

This was the culmination of the eccentricities of Quantum Theory: that the vacuum was not empty.

(The first experimental confirmation of zero-point energy had to wait until the 1990s).

Thus Quantum Theory predicts that the universe exists on a grid of spacetime values, and that there is something within the elements of this grid, something that does not quite belong to the universe (or, at least, does not belong to Quantum Physics) but has nonetheless an energy that can interact with the universe (be measured by people living on the grid of our universe).

Mass

Galileo "discovered" inertia: bodies that are at rest tend to remain at rest, and bodies that are moving tend to continue moving at the same speed in the same direction, unless a force is applied. Newton turned Galileo’s inertia into a quantitative property of matter: mass. Newton showed that mass was the object of forces, and the effect of forces on mass was to accelerate it. Forces and accelerations were visible entities. Mass was an invisible property of matter.

Newton’s mass was three things in one: it was resistance to acceleration, it was the ability of attracting other masses, and it was the propensity to be attracted by other masses. Einstein introduced "rest" mass, an aspect of energy, expressed by the equation E=mc². Einstein also showed that things that possess "mass" cannot travel faster than the speed of light, a speed that is reserved for things that do not possess mass (such as the photon).

Quantum Mechanics showed that "mass" is indeed a property of every elementary particle, but introduced another oddity: while there is an anti-particle for every particle (electrical charge can be positive or negative), both a particle and its anti-particle have the same (positive) mass. Mass is only positive, never negative. (In 1957 British physicist Hermann Bondi showed that the encounter between a mass and its anti-mass would result in infinite acceleration, with no need for a source of energy: the negative mass would be attracted to the positive mass, while the positive mass would be repelled by the negative mass. Thus the two masses would experience equal accelerations in the same direction, in violation of Newton's third law, and continue to accelerate forever, the negative mass chasing the positive mass and the positive mass fleeing from the negative mass with constant acceleration).

Neither Relativity nor Quantum Theory explained what "mass" is (where it comes from) and what causes its odd properties. They both took it for granted that Nature is that way. It was the odd behavior of "mass" that allowed physicists to create an elegant world. But the elegance was mostly based on an abstract, arbitrary, "catch all" definition.

The World And The Mind

Relativity Theory and Quantum Theory said something important about the mind. They were as much about mind as they were about matter, only in a more subtle way.

Relativity Theory was not only about reality being "relative" to something. It was (first and foremost) about reality being beyond the reach of our senses.

Einstein's underlying principle is that we don't always see the universe as it is. Newton's underlying principle was that we see the universe as it is. Newton's Physics is a description of how our mind perceives the universe. There are bodies, there is absolute time, etc.

Einstein's Physics is a "guess" about what the universe really is, even if our mind cannot perceive it. Einstein's Physics implied that there may be aspects of the universe that our mind cannot perceive, and that we can guess only by analyzing the aspects that we can perceive.

Quantum Theory was not only about reality being "quantized". It was also about reality being beyond the reach of our mind. The single most distressing finding of Quantum Theory is that reality as we know it only occurs when somebody observes it. The electron is in a certain place only when somebody actually looks at it, otherwise the electron is, simultaneously, in several different places.

We can analyze this finding with either of two stances. According to the first one, our mind has no limitations. It can perfectly perceive nature as it is. It observes only one value because that is what nature does: the multiple choices for a quantity's value collapse to just one value when that quantity is observed by an observer.

According to the second one, our mind has limitations. The quantum collapse from many values to just one value is due to a limitation of our mind. Our mind cannot perceive nature as it is. It can only perceive one value for each quantity.

The electron is in many places, but our mind cannot perceive a thing being in many places at the same time, so it "collapses" the electron into only one specific place at a time. This is just an effect due to the limitation of our mind. We are forced to "sample" reality because we can't handle all of it. After all, that's what all our senses do. They are bombarded all the time with data from the environment, and they only pick up some of those data. We don't perceive every single detail of what is going on around us, we are forced to be selective. The mind turns out to be a sense that also has limited capacity, although the limitation is of a different kind. Each item of reality (a position, a speed, etc) "has" many values. The reason we observe only one value is that our mind can't handle a universe in which quantities have more than one value.

The conceptual revolution caused by Quantum Theory was somewhat deeper than the one caused by Relativity Theory. Reconciling Newton and Einstein is relatively easy: Newton's theory was not false, it was just a special case of Einstein's theory, the one in which the spacetime is Euclidean. Reconciling Newton and Quantum Theory is, on the other hand, impossible: Newton's theory is just false. It seems to work because insist to assume that such things as big objects truly exist.

A theory of mind that does not take into account Relativity is a legitimate approximation, just like a theory of the Earth that does not take into account Relativity is a legitimate approximation. But no theory of mind can ignore Quantum Theory.

The Power of Constants

At this point we can note that all the revolutionary and controversial results of these new theories arose from the values of two constants. Quantum Mechanics was a direct consequence of Planck's constant: were that constant zero, there would be no uncertainty. Relativity Theory was a direct consequence of the speed of light being constant in all frames of reference: were the speed of light infinite, there would be no time dilatation and contraction of length.

These two constants were determined, indirectly, by studying two minor phenomena that were still unsolved at the end of the century: the ether and the black body radiation.

The presence of the ether could not be detected by measuring the speed of light through it; so Einstein assumed that the speed of light is always the same.

The black body does not radiate light with all possible values of energy but only with some values of energy, those that are integer multiples of a certain unit of energy; so Planck assumed that energy exchanges must only occur in discrete packets.

These two universal constants alone revealed a whole new picture of our universe.

Quantum Reality: Fuzzy or Incomplete?

Many conflicting interpretations of Quantum Theory were offered from the beginning.

Niels Bohr claimed that only phenomena (what appears to our senses, whether an object or the measurement of an instrument) are real, in the human sense of the word: particles that cannot be seen belong to a different kind of reality, which, circularly, cannot be perceived by humans; and the wave function is therefore not a real thing. Reality is unknowable because it is inherently indeterminate, and we humans do not live in a world of indeterminate things, we live in a world of phenomena (where "phenomena" presumably includes also houses and trees, the effect of those elementary processes).

Werner Heisenberg, the man who discovered in 1925 the first complete theory of the quantum, believed that the world "is" made of possibility waves and not particles: particles are not real, they are merely "potentialities", something in between ideas and actualities. Our world, what we call "reality", is a sequence of collapses of wave of possibilities. The quantum world and our world are bridged by the "measurement". Reality arises from quantum discontinuities (or "quantum jumps"): classical evolution of the Schroedinger equation builds up "propensities", then quantum discontinuities (the collapse of the wave function) select one of those propensities. Every time this happens, reality changes. Therefore reality "is" the sequence of such quantum discontinuities. What turns the unknowable world of particles into human-perceivable "phenomena" is the observation: the moment we observe something, we create a phenomenon. As John Wheeler put it, "no phenomenon is a real phenomenon until it is an observed phenomenon". The universe had to wait for a conscious observer before it started existing for real. Furthermore, Heisenberg interpreted this reality as "knowledge": the quantum state is a mathematical description of the state of the observer's knowledge rather than a description of the objective state of the physical system observed.

The British physicist Paul Dirac, the man who in 1928 merged Quantum Physics and Special Relativity in Quantum Field Theory, pointed out that Quantum Physics is about our knowledge of a system. It does not describe reality but our knowledge of reality. A wave function represents our knowledge of a system before an experiment and the reduced wave function our more precise knowledge after the measurement.

The Indivisible Universe

Albert Einstein was so unhappy with the uncertainty principle that he accepted Quantum Mechanics only as an incomplete description of the universe. He thought that Quantum Mechanics had neglected some "hidden variables". Once those hidden variables were found, we would have a complete theory without Quantum Theory’s oddities but with all of Quantum Theory’s results.

Quantum Theory is a practical tool to calculate probabilities for sets of particles, but no prescription is provided for calculating quantities of individual particles. Einstein thought that there is an underlying reality where determinism rules and the behavior of the individual particle can be predicted. It is just that Quantum Mechanics is incomplete and has not found out that underlying reality yet.

Einstein was particularly unhappy about the "nonlocality" of Quantum Physics, which he thought constituted a paradox. "Nonlocality" means "action at a distance". In Quantum Physics one can prove that, if they were once part of the same state, two particles will be always connected: once we measure the position of the first one, we instantaneously determine the position of the other one, even if, in the meantime, it has traveled to the other end of the universe. Since no information can travel faster than light, it is impossible for the second particle to react instantaneously to a measurement that occurs so far from it. The only possible explanation for this "paradox" was, to Einstein, that the second particle must have properties which are not described by Quantum Mechanics.

Einstein thought that Quantum Physics provides a fuzzy picture of a sharp reality, whereas for Bohr it provides a compete picture of a fuzzy reality.

Einstein was proven wrong in 1964 by the Irish physicist John Bell ("On the Problem of Hidden Variables in Quantum Mechanics", published only two years later), whose theorem basically ruled out "local hidden variables", precisely the type that Einstein invoked. Bell's conclusion is that, on the contrary, there are objective, non-local connections in the universe. In other words, two particles, once they have interacted, will keep interacting forever (their wave functions get entangled forever). Einstein believed in the law of locality, i.e. that two objects can interact only if they touch each other or if their interaction is mediated by some other object; but Bell proved that the "wave" is enough to provide interaction. Two measurements can be related instantaneously even if they are located in regions too far apart for a light signal to travel between them. Non-locality, or inseparability, is a fact of nature. Objects are not only affected by forces. They are also affected by what happens to other objects.

(More precisely, Bell showed how to test whether a world of properties that are not due to observation and of separated objects is possible. In 1972 John Clauser carried out an actual experiment to perform the test, and its result proved Einstein wrong: either properties are due to observation, or objects are forever connected, or both. Our world cannot possibly have both an observer-independent reality and entanglement-free objects. To be fair to Einstein, Bell assumed that induction is a valid logical method to prove theorems. And, as Nick Herbert has noted, Bell's theorem is metaphysical, not physical, and ultimately relies on the metaphysical assumption that the world behaves in a classical deterministic manner).

This shattered another belief of classical Physics. Newton believed that objects interact through forces that somehow have to travel from one to the other. A cannonball has to travel from the cannon to the walls before the walls explode; and nothing else in the universe is affected. The sun attracts the earth into an orbit, but it doesn't have any effect on the other stars. These are "local" interactions. Einstein added that forces can only travel as fast as light. Therefore, the impact of a force o an object is delayed by the time it takes for the force to reach that object at a speed which cannot exceed the speed of light. "Locality" became a distance: there is only so much in the universe that can exert a force on me, because only so much of the universe can send its force to me during my lifetime. If I live 80 years, an event that occurs more than 80 light-years away from here will never cause any disturbance on my life. Bell proved that this is not the case, because Quantum Theory prescribes the existence of a non-local "force": once two waves have interacted, they are forever entangled.

Note that Heisenberg's "knowledge interpretation" never had a problem with non-locality: obviously, a change in the observer's knowledge does change the observer's knowledge about the entire system, regardless of how "extended" in space the system is. For example, if I observed the two particles at the beginning, when they were in the same place, and noticed that one is black and the other one is white, and later I observe the white one, I will "know" that the other one is black even if the other one is light-years away from me.

Ontological interpretation

The USA physicist David Bohm believed in an "undivided whole" even before John Bell's theorem. His idea was that the whole universe is entangled in one gigantic wave.

One of Quantum Theory's most direct consequences is indeterminism: one cannot know at the same time the value of both the position and the momentum of a particle. One only knows a probability for each of the possible values, and the whole set of probabilities constitute the "wave" associated with the particle. Only when one does observe the particle, does one particular value occur; only then does the wave of probabilities "collapse" to one specific value.

Bohm’s "ontological" interpretation of Quantum Theory ("A Suggested Interpretation of the Quantum Theory in Terms of Hidden Variables", 1952) almost resurrected determinism at the quantum level. Bohm’s bold assumption was that the quantum "wave" is a real wave, due to a real potential.

Bohm assumed that the wave function does not represent just a set of probabilities: it represents an actual field. A particle is always accompanied by such a field. This field is a real field and acts upon particles the same way a classical potential does. (Bohm resurrected an interpretation of Quantum Theory that DeBroglie had abandoned, the theory of an ordinary wave guiding an ordinary particle).

The beauty of this assumption is that, with the introduction of this additional potential, something momentous happens to the equations of Quantum Mechanics: position and momentum of a particle are no longer incompatible, they can be measured precisely at the same time, and Heisenberg’s principle is defeated.

The behavior of the particle in Bohm’s theory is determined by the particle's position and momentum, by whatever force is acting on it, and by the quantum potential.

For Bohm, particles do exist and are always accompanied by a field. An electron is neither a particle nor a wave (field), it is a particle plus a wave (that cannot be separated). But Bohm's wave is not Born's wave: Born's wave is only a function of probabilities that helps compute the particle's position, whereas Bohm's wave is a real wave that guides the particle (therefore also referred to as the "pilot-wave").

Everything is both a particle and a wave, and is acted upon by both a classical potential and a quantum potential (the "pilot wave"). Basically, the wave-function provides an additional potential that, once inserted in the traditional Hamiltonian of classical Physics, yields a well-determined trajectory for each particle (but since the initial position cannot be known, we still can't predict the path of a particle, only notice that there exists a well-determined path prescribed by nature).

Bohm had found an interpretation of Quantum Theory in terms of particles with well-defined position and momentum. What Bohm had done with his assumption was, basically, to add some "hidden variables" (the quantum potential) to the equations, precisely what Einstein had suggested to restore determinism in Physics. (Bohm, incidentally, was dismissed equally by Bohr, who did not believe in hidden variables, and by Einstein, who believed in hidden variables).

The Pilot-Wave

To explain the function of the quantum potential, Bohm introduced the notion of "active in-formation" ("information" as in "give form", for example to a particle's movement). A particle is moved by whatever energy it has (for example, because a force is acting on it) but its movement is guided by the "in-formation" in the quantum field (in the "pilot-wave").

In Physics, a potential describes a field in terms of how, at each point in space, the particle located at that point will be affected by that field. In Newton's physics the effect of the classical potential on a particle is proportional to the magnitude of the field.

Bohm thought that his quantum field, in particular, had to reflect whatever is going on in the environment, including the measuring apparatus. Therefore, the quantum potential depends only on the form, and not on the magnitude, of the quantum field. The "strength" of the quantum potential does not depend on the intensity of the wave but only on the form of the wave. Even a very weak quantum potential can affect the particle. Even a very distant event can affect the particle.

The previous interpretations of Quantum Theory were trying to reconcile the traditional, classical concept of "measurement" (somebody who watches a particle through a microscope) with a quantum concept of "system". Bohm dispensed with the classical notion of "measurement": one cannot separate the measuring instrument from the measured quantity, as they interact all the time. It is misleading to call this act "measurement". It is an interaction, just like any other interaction, and, as Heisenberg's principle states, the consequence of this interaction is not a measurement at all.

Implicate Order

The field that Bohm introduced in the equations to fix Heisenberg’s indeterminism represents a "sub-quantum" reality.

Bohm's quantum potential does not act within the four-dimensional geometry of spacetime; it acts beyond it. In a sense, it defines a common pool of information, a way to connect everything together, just like dancers can use the music to move together in harmony.

Bohm thought that this field must be fluctuating rapidly and what Quantum Theory observes is merely an average over time (just like Newton's physics reads a value for quantities that are actually due to the Brownian motion of many particles). Quantum physics deals with mean values of an underlying reality just like Newton's physics deals with mean values of thermodynamic quantities.

At this "sub-quantum" level, quantum effects all but disappear: a particle’s position and momentum are well-determined. The mystery of the collapse of the wave function, of the discontinuity in the transition from the quantum world to the classical world, occurs only at the quantum level, whereas Bohm believes there is a deeper level at which the apparent discontinuity of the collapse disappears.

After all, the study of "elementary" particles has shown that even elementary particles can be destroyed and created, which means that they are not the ultimate components of the universe, that there must be an underlying reality, or, in Bohm's terms, an underlying "flux". Bohm thought that the basic problem lied in an obsolete notion of "order".

Thus, Bohm distinguished between the "explicate" order (the world of isolated spacetime thing-events that our senses experience) and the "implicate" order (all thing-events are part of a whole, the "holomovement"). The explicate order emerges from the holomovement. The holomovement contains all instances of explicate order as potentialities.

Cartesian order (the "grid" of space-time events) is appropriate for Newtonian physics in which the universe is divided in separate objects, but inadequate for Quantum and Relativity theories to reflect their idiosyncrasies and in particular the undivided wholeness of the universe that Bohm has been focusing on.

Bohm's solution was to contrast the "explicate order" that we perceive and that Physics describes (the Cartesian order of isolated space-time thing-events) with the "implicate order", which is an underlying, hidden layer of relationships. The explicate order is but a manifestation of the implicate order. Space and time, for example, are "forms" of the explicate order that are derived from the implicate order.

The implicate order is similar to the order within a hologram: the implicate order of a hologram gives rise to the explicate order of an image, but the implicate order is not simply a one-to-one representation of the image. In fact, each region of the hologram contains a representation of the entire image. The implicate order and the explicate order are fundamentally different. The main difference is that in the explicate order each point is separate from the others. In the intricate order, the whole universe is "enfolded" in everything, and everything is enfolded in the whole. In the explicate order "things" become (relatively) independent.

In the implicate order, all thing-events are part of a whole, the "holomovement". The explicate order emerges from the holomovement. The holomovement contains all instances of explicate order as potentialities.

Bohm suggested that the implicate order could be defined by the quantum potential, the field consisting of an infinite number of pilot waves. The overlapping of the waves generates the explicate order of particles and forces, and ultimately space and time.

Since Bohm’s quantum field is affected by all particles (the pilot-wave that guides all particles is affected by all particles), nonlocality is a feature of reality: a particle can depend strongly on distant features of the environment.

Bohm's universe is one indivisible whole.

Everything in the universe is entangled in everything else, and ultimately in the whole. It does not make sense to analyze particles of subsets of the world as independent and separate parts.

Beyond Locality

Einstein's objection did not die there and is still very much alive, if nothing else because, ultimately, it can be read as an objection to the role that the observer plays in Quantum Theory.

The USA physicist Alwyn Scott resuscitated Einstein's hypothesis. Scott argued in favor of an interpretation of Quantum Theory as an approximation to a not yet discovered non-linear theory. The new theory must be non-linear because it is the only way to remove Heisenberg's uncertainty principle, which descends from the linearity of Schroedinger's equation.

Again inspired by Einstein, the Australian philosopher Huw Price thinks that backward causation (that future can influence the past), or advanced action, is a legitimate option. Price believes that our theories are time-asymmetric because we are conditioned by folk concepts of causality. Physical theories are built starting with the assumption that the future cannot influence the past, and therefore it is no surprise that they prescribe that the future cannot influence the past. If we remove our preconceptions about causality, then we can redraw Quantum Physics. Then it turns out that Einstein was right with his hypothesis of hidden variables, and that Quantum Physics provides an incomplete description of the universe. A complete Quantum Physics will not assign any critical role to the observer.

In the 1980s the USA physicist John Cramer traveled the opposite route with his "transactional interpretation" of Quantum Theory, which aims at sending back the observer to the laboratory and removing her from the formalism. Cramer builds on "absorber theory" developed in the 1940s by John Wheeler and Richard Feynman. They described a radiation process as a "transaction" in which the emitter of the radiation and the absorber of the radiation exchange waves: the emitter sends a "retarded" wave to the absorber, and simultaneously the absorber sends an "advanced" wave to the emitter. Advanced waves are canceled and therefore cannot be detected. An observer perceives only that a retarded wave has traveled from the emitter to the absorber.

"Advanced" waves are solutions of a wave equation which contain only the second time derivative. Advanced waves have "eigenvalues" of negative energy and frequency, and they propagate in the negative time direction. Advanced waves are basically the time-reversed counterparts of normal (or retarded) waves. Both "advanced" and "retarded" waves are valid orthogonal solutions of the electromagnetic wave equation, but in conventional electrodynamics the advanced solutions are usually ignored as unnatural, because they violate the law of causality, and only "retarded" solutions are retained. Wheeler and Feynman proposed that the time symmetry in the wave equation reflects a property of nature, that both types of waves actually occur.

In the Wheeler-Feynman absorber theory, any emission process makes advanced waves on an equal basis with ordinary "retarded" waves.

Cramer has extended the idea and claims that any quantum event is a "handshake" executed through an exchange of advanced and retarded waves. The exchange of a quantum of energy between a present emitter and a future absorber occurs through a Wheeler-Feynman exchange of advanced and retarded waves. The emitter sends an "offer" wave to the absorber (forward in time). The absorber then returns a "confirmation" wave to the emitter (backwards in time). The transaction is then completed with an "handshake" across space-time, which leads to the transfer of energy from emitter to absorber.

The transaction is explicitly non-local because the future is affecting the past. Einstein's paradox is solved without resorting to a knowledge-based interpretation.

The Discontinuity Of Time

One of Newton's postulates was that "time flows equably".

The biggest problem with Quantum Theory is how the observed world (the world we know, made of well-defined objects) emerges from the quantum world (a world of mere possibilities and uncertainties, thanks to Heisenberg’s principle).

The Hungarian mathematician John Von Neumann (the same one who virtually invented the computer) distinguished between processes of the first and second kinds that occur when one is analyzing the evolution of a system with Quantum Theory. First-kind processes occur in isolated systems, on which no measurements can be carried out, and they closely resemble classical, deterministic evolution of a physical system. Second-kind processes occur when a measurement is carried out and they are non-deterministic (or at least probabilistic): when an observable is measured, the state of the system suddenly jumps to an unpredictable state (or "eigenstate") associated with the measured eigenvalue of the observable. Unlike classical Physics, in which the new state can be determined from the prior state of the system, Quantum Theory can only specify the probabilities of moving into any of the observable’s eigenstates. In quantum lingo, a measurement causes a "collapse of the wave function", after which the observable assumes a specific value. A continuous process of the first kind gives rise to a discontinuous process of the second kind.

Isolated systems obey to the Schroedinger equation, observed systems obey to Heisenberg's quantum jumps. Quantum Theory therefore implies that something turns a process of the first kind into a process of the second kind when it is observed.

The problem is that Quantum Theory does not prescribe or describe when and how this happens. The flow of time is mysteriously altered by measurements: a system evolves in a smooth and deterministic fashion until a measurement is performed, then it jumps more or less randomly into an eigenstate of the measured observable, from where it resumes its smooth evolution until the next measurement. Time seems to behave in an awkwardly capricious way.

As Bohr pointed out, a measurement also introduces irreversibility in nature: collapse cannot be undone. Once we measured a quantity, at that point in time a discontinuity is introduced in the evolution of the wave function. If, after a while, we proceeded backwards in time, we would reach the same point from the future with a wave function which could collapse in any of the legal ways, only one of which is the one that originated the future we are coming from. It is very unlikely that we would retrace the same past.

Thus there is another "arrow of time" (besides entropy) that explains why time only flows in one direction.

The Measurement Problem

According to Quantum Theory, our universe needs both kinds of processes. Von Neumann tried to figure out how they interact and realized that the answer lies in the "measurement" of the system.

Reality seems to proceed on two parallel tracks. The Schroedinger equation determines (in a deterministic manner) the evolution of the state of the system, but that state is a set of possible states each with its own probability of happening. So long as nobody observes the system, the Schroedinger equation predicts future probabilities of the system. Then Heisenberg's principle causes that wave function to "collapse" whenever the system is observed. The collapse causes the system to choose only one of the possible states. Once the observer has observed the system, only a part of the wave survives and evolves according to the Schroedinger equation. At this point the Schroedinger equation can calculate a new set of possible states. And so forth. The two views are both necessary to explain the evolution of the universe. They are not alternative views of the universe. One complements the other.

Note that the observer does more than just observe something: the observer also decides "what" to observe. That decision has an effect on the state of the system, because it forces the system to choose among all the possible states. Nature's role is really only to choose one of those possible states, and Quantum Theory can only presume that this is done randomly.

Von Neumann pointed out that measurement of a system consists in a process of interactions between the instrument and the system, whereby the states of the instrument become dependent on the states of the system. There is a chain of interactions that leads from the system to the observer’s consciousness. For example, a part of the instrument is linked to the system, another part of the instrument is linked to the previous part, and so forth until the interaction reaches the observer’s eye, then an interaction occurs between the eye and the brain and finally the chain arrives to the observer’s consciousness. Eventually, states of the observer’s consciousness are made dependent on states of the system, and the observer "knows" what the value of the observable is. Somewhere along this process the collapse has occurred, otherwise the end result of the chain would be that the observer’s consciousness would exhibit the same probabilistic behavior of the observable: if the observer reads one specific value on the instrument, it means that the wave of possibilities has collapsed (has chosen just that one specific value) somewhere between the system and the observer’s consciousness. At which point? What exactly causes the "collapse"? The instrument? The lense? The electrons inside the instrument? The observer's retina? The observer's nervous system? The observer's consciousness?

What constitutes a valid observer? Does it have to be big? Does it have to be in the brain? Does it have to be conscious? Does it have to be human?

Von Neumann showed mathematically that Quantum Theory is indifferent: it makes no difference to the statistical predictions of Quantum Theory where exactly this happens and what causes it. But humans are curious and would like to find out.

In a sense, Von Neumann was trying to reconcile "objective being" and "subjective knowing". In classical Physics they are one and the same, but in Quantum Physics they are different, and it is not completely clear how subjective knowing relates to objective being.

Later, the Hungarian physicist Eugene Wigner introduced another step in Von Neumann’s thought experiment: what if a friend is part of the chain that leads to the observation? If a friend measures the position of a particle and then relates to me the result, for me the wave "collapses" only when he tells me the result of her experiment. But the wave has already collapsed for her when he carried out the measurement. Did the wave collapse also for me at the same time? If not, do our waves collapse to the same value? Or does each of us live in an independent universe?

Von Neumann’s interpretation was in turn interpreted as implying that the observer somehow "creates" reality. Copernicus shocked the human race by telling us that we are not at the center of the world; Quantum Physics is telling us that we (our very consciousness) is at the center of the world. We are gods who create our own universe.

The Brain as a Measurement Device

Quantum Theory is really about waves of possibilities. A particle is described by a wave function as being in many possible places at the same time. When the particle is observed, its wave function "collapses" with definite attributes, including the location it occupies, but such attributes cannot be foreseen until they actually collapse. In other words, the observer can only observe a quantum system after having interfered with it.

Von Neumann highlighted an inconsistency in the standard interpretation of Quantum Theory: the objects to be observed are treated as quantum objects (or waves), while the objects that observe (the instruments) are classical objects, with a shape, a position and no wave. The "measurer" is a natural object as much as the "measured", but we grant it immunity from Quantum Theory. Von Neumann objected to dividing the world into two parts that behaved differently. Quantum Theory unequivocally states that everything is a quantum system, no matter how small or big it is. On the other hand, if everything is a quantum system regulated by a wave of possibilities, what makes it collapse? Von Neumann was led again to postulate that something "different" from a quantum system has the power to cause such a collapse, and that something had to be human consciousness. Nothing in the world is real unless perceived by a mind, as the British philosopher Berkeley had argued centuries before Von Neumann.

What if we built an instrument which is smaller than the system to be observed? What would be a quantum system: the smaller or the bigger, the measurer or the measured?

The range of uncertainty of a particle is measured by Max Planck's constant. Because Planck's constant is so small, big objects have a well-defined position and shape and everything. The features of small objects such as particles are instead highly uncertain. Therefore, large objects are granted an immunity from quantum laws that is based only on their size.

Consciousness Creates Reality

John Wheeler believes that the collapse can be caused by anything that (aware or unaware) makes a "record" of the observation. An observer is anything in Nature that causes the observation to become public and irreversible. An observer could be a crystal.

Recently, Roger Penrose, inspired by work done initiated by Frenkel Karolyhazy in the 1960s, has invoked gravity to justify that special immunity: in the case of large objects, the space-time curvature affects the system's wave function, causing it to collapse spontaneously into one of the possibilities. Precisely, Penrose believes that different space-time curvatures cannot overlap, because each curvature implies a metric and only one metric can be the metric of the universe at a certain point at a certain time. If two systems engage in some interaction, Nature must choose which metrics prevails. Therefore, he concludes, the coupling of a field with a gravitational field of some strength must cause the wave function of the system to collapse. This kind of self-collapse is called "objective" reduction to distinguish it from the traditional reduction of Quantum Theory which is caused by environmental interaction (such as a measurement). Self-collapse occurs to everything, but the mass of the system determines how quickly it occurs: large bodies self-collapse very quickly, elementary particles would not for millions or even billions of years. That is why the collapse of wave functions for elementary particles in practice occurs only when caused by environmental interaction.

In practice, the collapse of the wave, which is the fundamental way in which Quantum Theory can relate to our perceptions, is still a puzzle, a mathematical accident that still has no definite explanation.

It is not clear to anybody whether this "collapse" corresponds to an actual change in the state of the particle, or whether it just represents a change in the observer's amount of knowledge or what. It is not even clear if "observation" is the only operation that can cause the collapse. And whether it has to be "human" (as in "conscious") observation: does a cat collapse the wave of a particle? Does a rock?

What attributes must an object possess to collapse a wave? Is it something that only humans have? If not, what is the smallest object that can collapse a wave? Can another particle collapse the wave of a particle? (In which case the problem wouldn't exist because each particle's wave would be collapsed by the surrounding particles).

What is the measuring apparatus in Quantum Physics? Is it the platform that supports the experiment? Is it the pushing of a button? Is it a lens in the microscope? Is it the light beam that reaches the eye of the observer? Is it the eye of the observer? Is it the visual process in the mind?

It is also a mystery how Nature knows which of the two systems is the measurement system and which one is the measured system: the one that collapses is the measured one, but the two systems are just systems, and it is not clear how Nature can discriminate the measuring one from the measured one and let only the latter collapse.

If a wave collapses (i.e., a particle assumes well-defined attributes) only when observed by a conscious being, then Quantum Theory seems to specify a privileged role for the mind: the mind enters the world through the gap in Heisenberg's uncertainty principle. Indeed, the mind "must" exist for the universe to exist, otherwise nobody would be there to observe it and therefore the world would only be possibilities that never turn into actualities. Reality is just the content of consciousness, as the Hungarian physicist Eugene Wigner pointed out in 1961. Of course, mind must therefore be an entity that lies outside the realm of Quantum Theory and of Physics in general. The mind must be something special that does not truly belong to "this" world.

Wigner pointed out that to every action there is a reaction: why shouldn’t there be a reaction to a conscious observation of a physical phenomenon? If a phenomenon exerts an influence on my consciousness when I observe it, then my consciousness must exert an influence on the phenomenon. Otherwise the fundamental tenet that to every action there is a reaction is no longer true.

Wigner observed that Schroedinger’s equation is linear, but would stop being linear if its object were the very consciousness that collapses the wave. Therefore, Schroedinger’s equation (which is linear) would result in a non-linear algorithm that may justify the mind’s privileged status.

If the collapse occurs only when observed by a conscious being, if the collapse occurs at the border between mind and matter, as Wigner believes, then the evolution of the universe changed after the appearance of human beings (there was no collapse anywhere before mind appeared).

Undeterred by this objection, the USA physicist John Wheeler believes that ours is a "participatory" universe, one in which consciousness participates in creating reality. The observer and the phenomenon are engaged in a creative act that yields reality. Consciousness does not create reality. Consciousness' role is extremely limited: it can't even choose which of the possibilities contained in the wave function will become reality. It can only "precipitate" reality out of many possibilities. Which possibility becomes reality is up to nature. Nonetheless, Wigner and Wheeler believe that consciousness is crucial to creating reality: as limited as its contribution is, without it there would be no reality, only possibilities. Wheeler even speculated that the rise of consciousness retroactively determined the history of the universe because it collapsed the mother of all waves that had never been collapsed before, thereby fixing every single event in the previous life of the universe.

Quantum theoretical effects could be considered negligible if they only affected particles. Unfortunately, Erwin Schroedinger, with his famous cat experiment, established that Heisenberg's uncertainty affects big objects too. Basically, Schroedinger devised a situation in which a quantum phenomenon causes the cat to die or stay alive. Since any quantum phenomenon is uncertain, the cat's life is also uncertain: until we look at the cat, the cat is neither alive nor dead, but simply a wave of possibilities itself. (A popular objection to Schroedinger’s argument is that the cat can never be in a superimposed state because every big object, by definition, is never isolated, it is always entangled with the rest of its surroundings, and therefore it is "collapsed" all the time).

Inventing Reality

In the 1940s Richard Feynman offered another interpretation of Quantum Theory: he assumed that all possible states allowed by a wave function exist at any moment. In other words, he took Schroedinger’s equation to the letter. The state that is revealed by measurement is merely the state which represents the "path of least action" for the particle relative to the observer. But the particle is in every place allowed by its wave function. An observation does not reveal reality: an observation is an interaction between the observer and the observed system, and the observation simply reveals that: the interaction between the observer and the observed system. In a sense, the observer "invents" the particle. The particle per se does not exist (or, better, it is merely a field). What exist is a range of values, or, better, a set of ranges of values, which our observations translate into values for attributes of a particle.

The Multiverse: The Quest for Certainty

The traditional (or "Copenhagen") interpretation of Quantum Mechanics seems to be trapped in its unwavering faith in uncertainty. Others have looked for ways out of uncertainty.

One possibility is to deny that the wave function collapses at all. Instead of admitting a random choice of one of many possibilities for the future, one can subscribe to all of the possibilities at the same time. In other words, the probabilistic nature of Quantum Mechanics allows the universe to unfold in an infinite number of ways.

Hugh Everett's "many-universes" interpretation of Quantum Mechanics, originally put forward in 1957, states, basically, that if something physically can happen, it does: in some universe. Everett interpreted quantum "possibilities" as actualities. A particle "is" in many places at the same time: those places are in different universes. Physical reality consists of a collection of universes: the "multiverse". We exist in one copy for each universe and observe all possible outcomes of a situation. It is not only the universe that splits in many universes, it is also the observer that splits in many observers. For a particle there is no wave of possibilities: each possibility is an actuality in one universe. (Alternatively, one can say that there is one observer for each possible outcome of a measurement).

Each measurement splits the universe in many universes (or, as Michael Lockwood puts it, each measurement splits the observer). Biographies form a branching structure, and one which depends on how often they are observed.

No reduction/collapse occurs. The wave function evolves in a deterministic way, just like in Newton's physics.

Naturally, the observer perceives exactly what I am perceiving: a flow of smooth changes.

There is an alternative way to present Everett's ideas. Everett basically accepts that the Schroedinger equation is all there is. The world is described by that equation. We have to take it literally. The particle is in all the states that the equation prescribes. The trick is that the state of the observer is as superposed as that of the observed system. Therefore the observer sees all of the possible states of the observed system. This way the world does not split, but the mind of the observer does. Each mind observes only one state of the many that are possible according to the Schroedinger equation. Therefore each mind perceives a separate world, that is a subset of the world described by the Schroedinger equation. In a sense, each mind views the world from a subjective perspective. The objective state of the world is the one described by the equation, and it corresponds to the superposition of all the states observed by all the minds of the observer.

The British physicist Stephen Hawking is even trying to write down the wave function of the universe, which will actually describe an infinite set of possible universes. Basically, he looks at the universe as if it were one big particle. Just like the wave function of a particle describes an infinite set of possible particles, the wave function of the universe actually describes an infinite set of possible universes.

In Everett's multiverse, Quantum Theory is deterministic and the role of the observer is vastly reduced (we really don't need an observer anymore, since the wave collapses in every single universe, albeit in different ways). Quantum Theory looks more like classical theory, except for the multiplication of universes.

The Immanent Manyverse

Because of the apparent approximation of any quantum theory description of a phenomenon, the Israeli physicist David Deutsch also thinks that our universe cannot possibly constitute the whole of reality, it can only be part of a "multiverse" of parallel universes. But Deutsch's multiverse is not a mere collection of parallel universes, with a single flow of time. He highlights the contradiction of assuming an external, superior time in which all spacetimes flow. This would still be a classical view of the world. Deutsch's manyverse is instead a collection of moments. There is no such a thing as the "flow of time". Each "moment" is a universe of the manyverse. Each moment exists forever, it does not flow from a previous moment to a following one. Time does not flow because time is simply a collection of universes. We exist in multiple versions, in universes called "moments".

Each version of us is indirectly aware of the others because the various universes are linked together by the same physical laws, and causality provides a convenient ordering. But causality is not deterministic in the classical way: it is more like predicting than like causing. If we analyze the pieces of a jigsaw puzzle, we can predict where some of the missing pieces fall. But it would be misleading to say that our analysis of the puzzle "caused" those pieces to be where they are, although it is true that their position is "determined" by the other pieces being where they are.

Furthermore, Deutsch claims that Quantum Theory is not enough to understand reality. He does not adhere to the dominant philosophical stance, that to understand a system is to understand its parts and to have a theory of that system is to have a set of predictions of its future behavior. Deutsch thinks that the predictions are merely the tools to verify if the theory is correct, but what really matters is the "explanation" that the theory provides. Scientific knowledge consists of explanations, not of facts or of predictions of facts. And, contrary to the dominant "reductionist" approach, an explanation that reduces large-scale events to the movement of the smallest possible constituents of matter is not an explanation. As he puts it, why is a specific atom of copper on the nose of the statue of Churchill? Not because the dynamic equations of the universe predict this and that, and not because of the story of that particle, but because Churchill was a famous person, and famous people are rewarded with statues, and statues are built of bronze, and bronze is made of copper.

Scientists who adhere to the reductionist stance believe that the rules governing elementary particles (the base of the reductionist hierarchy) explain everything but they do not provide the kind of answer that we would call "explanation".

So we need four strands of science to understand reality: a theory of matter (quantum theory), a theory of evolution, a theory of knowledge (epistemology), and a theory of computation. The combined theory provides the "explanations" that Deutsch is interested in.

Einselection: Darwinian Collapse

One man who has been studying the problem of how classical Physics emerges from Quantum Physics (how objects that behave deterministically emerge from particles that behave probabilistically, how coherent states of Quantum Mechanics become classical ones) is the Polish-born Wojciech Zurek. He does not believe that consciousness has anything to do with it: it is rather the environment that determines the emergence of reality.

Since 1991, experiments have been performed to show the progressive evolution of a system from quantum to classical behavior. The goal is to observe the progressive collapse of the wave function, the progressive disappearance of quantum weirdness, and the progressive emergence of reality from probability.

Zurek ("Reduction of the Wave Packet", 1984) proposed a different twist to the debate on the "collapse of the wave". It doesn't necessarily take an observer. Zurek thinks that the environment destroys quantum "coherence" (superposition). The environment includes anything that may interact with the quantum system, from a single photon to a microscope. The environment causes "decoherence" (the choice of one or some of the possible outcomes) and decoherence causes selection (or "einselection") of which possibilities will become reality. The "best fit" states turn out to be the classical states. Systems collapse to classical states because classical states are the ones that best "fit" the environment.

The environment causes the collapse of the wave just like an observer. Decoherence occurs to any system that interacts with other systems. Large objects are classical and not quantum objects because they are inherently "decohered" by being a collection of interacting parts. Small objects are isolated to some extent and therefore exhibit quantum behavior.

In the USA, James Anglin, a close associate of Zurek, is studying the evolution of "open quantum systems" far from equilibrium, which resemble Prigogine's studies on open classical systems.

This line of research is, indirectly, establishing intriguing similarities between the emergence of classical systems from quantum systems and the emergence of living systems from non-living systems.

Consistent Histories

The "consistent histories formulation" of Quantum Theory originated with the USA physicist Robert Griffiths ("Consistent Histories and the Interpretation of Quantum Mechanics", 1984).

The history of a system is a sequence of quantum events (i.e., wave functions). Quantum Theory, according to this interpretation, is simply a tool to calculate the probability of a history.

This only applies to "consistent histories", later renamed "decoherent histories" by Murray Gell-Mann and James Hartle ("Alternative Decohering Histories in Quantum Mechanics", 1990), i.e. to sequences of "questions" about the system that are compatible.

In a sense, this is a theory of which sets of "classical" questions can be consistently asked of a quantum system. Questions that are fundamentally inconsistent are meaningless if asked at the same time.

Histories can be used to calculate the usual probabilities for quantum systems (e.g., a particle) to be measured by a measuring device, but they can also be used to assign probabilities in the absence of any measurement (e.g., to describe a system in outer space).

Another advantage of this approach is that, philosophically speaking, the "collapse" of the wave becomes merely a mathematical procedure for calculating probabilistic correlations rather than an actual physical phenomenon, thus eliminating the special role of the conscious observer.

At any point in time, there can be a whole set of consistent histories for a given system, each corresponding to a particular set of consistent questions.

Thus, quantum uncertainty is still there. In a sense, this is a mirror interpretation of Everett's multi-verse interpretation: many histories for one world, instead of one history of many worlds.

According to Lee Smolin, there is only one universe for everybody, but each observer only has a partial view of it, and therefore produces a different mathematical description of it, and therefore a different quantum theory. This is a relativistic view that recognizes the subjectivity of the observation: each observer sees a different world, or "context", and describes it with a different quantum theory. The catch is that they must all be consistent, i.e. different observers must get the same answer to the same question.

Fotini Markopoulou ("An Insider's Guide To Quantum Causal Histories", 2000) proposed that the "context" is nothing but the past of the observer. The past of an observer at a given time (a relativistic concept) determines the quantum history of the world for that observer (a quantum concept).

Thus Lee Smolin argued that "the universe is made of processes, not things".

Qubits

In the 1990s another interpretation of quantum mechanics has been put forth by the Austrian physicist Anton Zeilinger.

He set out to find a fundamental principle that would explain the three odd features of the quantum world:

quantization (all fundamental physical quantities come in discrete amounts),

randomness (we can only know the probability of an event) and

entanglement (everything is connected, no matter how far objects are).

He proposed a very simple principle: each elementary system, called "qubit" (e.g., the spin of the electron), carries one and only one bit of information; two systems carry two and only two bits of information; and so forth.

After all, our physical description of the world is represented by propositions, and each proposition can be true or false, i.e. each elementary system carries one and only one bit of information.

The consequences of this principle are simple to derive:

I can't know two things about an electron, but only one at the time (uncertainty), everything has to be quantized because the unit of information is the bit (yes/no, or one/zero);

Two systems carry exactly two bits of information, which means that they are entangled forever (if one changes, the other one has to change too in order to still yield two bits of information).

Schroedinger's equation can be derived as the description of motion in a three-dimensional information space.

Zeilinger's interpretation is therefore that only information truly exists and that quantum mechanics is simply a theory of how information behaves in this world.

Information Loss

In the 1990s the Dutch physicist Gerard’t Hooft proposed that Quantum Physics is Classical Physics after an information loss. This is yet another variation on Einstein’s "hidden variables" theory. Hooft noticed that classical variables can take any value, whereas quantum variables can take only some values. Thus, de facto, a classical system gives rise to a quantum system when it loses information. He thinks that this information loss can be due to some "dissipative forces". We know that different starting conditions can lead to the same results because of dissipative forces in the macro-world. For example, if you throw two coins from the top of a skyscraper at different speeds, air friction will cause them to reach the ground at the same speed. The observer will conclude that nature only allows some discrete values for the speed of the coins, when in fact it is air friction that caused them to land at the same speed. Nature is classical at its most fundamental level, but quantum at the level of the laboratory because of "dissipation".

Interpretations of Classical Physics

The fact that Quantum Physics lends itself to many contradicting interpretations has been widely publicized from the very beginning. Less publicized is the fact that Newton’s Physics is no less open to interpretations.

Newton’s greatest invention was the concept of "mass". Ask ten scientists what "mass" is and you will get ten different answers. Mass is at least three things in Newton’s Physics: a measure of resistance to acceleration, a measure of how much an object attracts other objects, and a measure of how much an object is attracted by other objects (laziness, allure and weakness). Whichever of the three you choose, where does it come from? Why do objects have this exoteric quantity of "mass"?

Another fundamental tenet of Newton’s Physics (that actually comes from Galileo) is the notion that objects tend to move in a straight line at constant speed. Aristotle thought that objects tend to stop if they are not pushed. Galileo realized that objects (such as arrows) keep moving even when no force is pushing them. Thus it made sense to assume that objects want to keep moving indefinitely. (Friction and gravity cause them to slow down or bend). This works. But: why do objects have a preference for traveling in a straight line at constant speed? Where does this property come from? Again, this is open to interpretation.

In concluding, it is not surprising at all there are several different interpretations of what Quantum Physics means: there are still, three centuries later, different interpretations of what Newton’s Physics means.

The Interpretation of the Human Brain

Over its first century of existence, Quantum Physics has been the subject of countless "interpretations". Its implications (that reality is created by the observer, that everything is connected all the time, that the universe is run by randomness) sound "odd" and therefore require that someone "interprets" them for the human mind.

However, one could look at the problem from the opposite viewpoint: what is it in the human brain that makes Quantum Physics look so odd? Maybe there is nothing to interpret in Quantum Physics, but there is something to interpret in the human brain. Maybe another brain would not find Quantum Physics so odd, and it would in fact see the world exactly the way Quantum Physics presents it (with objects in multiple positions at the same time and with everything in the universe connected all the time). The human brain has a "cognitive closure". Just like any other brain, there are things that our brain just cannot do. We cannot see or hear frequencies that other animals can see and hear. There is probably an infinite number of things that our brain just cannot do, because it was not designed for them. Maybe understanding Quantum Physics is one of the many things that our brain just cannot do.

The Physics of Elementary Particles: Close Encounters with Matter

Quantum Theory redrew our picture of nature and started a race to discover the ultimate constituents of matter. This program culminated in formulation of the theories of Quantum Electrodynamics (virtually invented by the British physicist Paul Dirac in 1928 when he published his equation for the electron in an electromagnetic field, which combined Quantum Mechanics and Special Relativity) and Quantum Chromodynamics (virtually invented by the USA physicist Murray Gell-Mann in 1963 when he hypothesized the breakdown of the nucleus into quarks).

It follows from Dirac’s equation that for every particle there is a corresponding anti-particle which has the same mass and opposite electric charge, and, generally speaking, behaves like the particle moving backwards in space and time.

Forces are mediated by discrete packets of energy, commonly represented as virtual particles or "quanta". The quantum of the electromagnetic field (e.g., of light) is the photon: any electromagnetic phenomenon involves the exchange of a number of photons between the particles taking part in it. Photons exchange energy in units of the Planck constant, a very small value, but nonetheless a discrete value.

Other forces are defined by other quanta: the weak force by the W particle, gravitation by the graviton and the nuclear force by gluons.

Particles can, first of all, be divided according to a principle first formulated (in 1925) by the Austrian physicist Wolfgang Pauli: some particles (the "fermions", named after the Italian physicist Enrico Fermi) never occupy the same state at the same time, whereas other particles (the "bosons", named after the Indian physicist Satyendra Bose) do. The wave functions of two fermions can never completely overlap, whereas the wave functions of two bosons can completely overlap (the bosons basically lose their identity and become one).

(Technically, "boson" is the general name for any particle with an angular momentum, or spin, of an integer number, whereas "fermion" is the general name for any particle with a odd half quantum unit of spin).

It turns out (not too surprisingly) that fermions (such as electrons, protons, neutrons) make up the matter of the universe, while bosons (photons, gravitons, gluons) are the virtual particles that glue the fermions together. Bosons therefore represent the forces that act on fermions. They are the quanta of interaction. An interaction is always implemented via the exchange of bosons between fermions.

(There exist particles that are bosons but do not represent interactions, the so called "mesons", first hypothesized by the Japanese physicist Hideki Yukawa in 1935). Mesons decay very rapidly. No stable meson is known).

Three forces that act on elementary particles have been identified: the electromagnetic, the "weak" and the "strong" forces. Correspondingly, there are bosons that are weak (W and Z particles), strong (the gluons) and electromagnetic (the photon).

Fermions can be classified in several ways. First of all, the neutron and the proton (the particles that made up the nuclei of atoms) are not elementary: they ar