Branching Out

I have been blogging here at Everything Rum since 2007.  My first posting was a Consciousness Riff.  I used to blog at Outside Walls, mostly on Kosovo, but closed that down a while ago.  In the Everything Rum space I've blogged on quantum physics, cosmology & space/time, biking, the state of the world, capitalism, the Articles of Confederation and sometimes on politics.   State Department cables (cleared through FOIA) and other related material from my time serving as a US diplomat can be found at Real Diplomacy.  Since 2009, I was writing on international issues at TransConflict. 

Now I am branching out.  I've tried Twitter and Facebook in the past but didn't stay with them.  I'm now returning to Twitter to connect and to accompany my expanded blogging here.  I'll be commenting as I see useful and perhaps will find others who if not in agreement at least have some reason to stop and reflect.  My first effort will follow shortly on the US and Russia.

Non-local spookiness

Einstein put forward his theory of general relativity 100 years ago. His prime insight concerned the reciprocal relationship between mass and spacetime. Mass (matter and energy) warps spacetime (our three observed physical dimensions plus time) and warped spacetime determines how objects move around mass. Mass in motion always moves in straight lines. However, in the presence of massive objects, those straight lines follow the curves of warped spacetime. Thus things fall.

Einstein also contributed to the elaboration of quantum mechanics. But quantum physics and relativity seem to be fundamentally different ways of understanding reality. The former reduces all we observe to a realm of particles and waves that remain intrinsically probabilistic. The latter places reality into a universal geometrical framework of space and time. Einstein was uncomfortable with quantum physics because of its probabilistic nature – “God does not play dice with the universe” – and because until observed, particles also exist as waves. A further issue for Einstein was the apparent implication of quantum physics known as entanglement.

Quantum entanglement occurs when two or more particles are generated or interact in such a way that they share the same wave function (quantum state). When that happens, no matter how far apart those particles may move away from each other – even to opposite ends of the universe – they remain entangled: measurement of one – collapsing its wave function – also determines the measurement of the other. This bothered Einstein – he termed it “spooky action at a distance” – because the two particles seem to communicate through space instantaneously and – more to the point – faster than the speed of light. For Einstein, the speed of light is a fundamental constant and nothing can go any faster. But experiment has consistently verified the phenomenon of quantum entanglement. Most recently a group of Dutch physicists gave what is widely seen as definitive proof that entanglement across distance is real and reveals that reality is in some way non-local.

Non-locality implies that entangled things exist in a relationship that is not determined by the local conditions that impinge upon those things. In other words, when one of the things is measured, the qualities of the far distant formerly entangled thing are not determined by where that thing is but by some deeper reality that is not local to the thing itself. Non-locality implies that there is some more fundamental level of reality that exists outside space and time.

We live in a universe in which time and space do exist. We travel through space (in any direction of three directions) and time (only forward). Things with mass travel travel no faster than the speed of light. At the speed of light, everything happens at the same instant because time does not pass. If we could be that massless surfer riding a photon created at the moment of the Big Bang, we would experience everything and everywhere that photon would ever be at the same instant.

We experience time as passing because we live in a world of matter and energy, which seems to give rise to spacetime. Our consciousness exists in time as our body exists in space. But non-locality points to a reality in which the universe exists without time or space as one object in which all time and space exist at once. We appear not to experience this deeper reality outside the realm of quantum experimentation (though it may make it possible someday to have quantum computing). But non-locality – as St. Thomas Aquinas might argue – points to consideration of First Cause and Ultimate Reality. That is spooky.

Decoherence, or If a Tree Falls In the Forest...?

One of the basic unsettled questions of quantum physics is why we don't see quantum superposition in everyday objects. At the quantum level – and before being “measured” – mass and energy exist simultaneously as both wave and particle. The classic examples are light and electrons. Photons exist as both wave and particle and manifest as either depending on how it is observed. Similarly, electrons do not exist, in reality, as tiny “planets” circling the nucleus in neat orbits but in clouds of probabilities that may be “found” as a particle in a particular “place” only when measured. Everything that exists at the quantum level – the realm of the very tiny – shares this dual nature as wave and particle. It can be more accurately described as a wave function.

If everything were to remain in quantum superposition in the macro-world we inhabit, Schrödinger's cat – and everyone else's – would be both alive and dead at the same time. We don't see in that way because superposition seems to breakdown when things get large. The wave function has collapsed and we see either waves or particles, i.e., individual, unconnected, single state things. Why?

The easiest answer might be that we don't see quantum superposition at the macro level because when we look at the world, we as conscious observers collapse the wave function. Light, sound, touch, smell, taste all enter our perceptual mechanisms and, interacting with brain and mind, are perceived. The world is there when we observe it because the act of observation collapses the wave functions around us even if nothing else did. But does this mean that if a tree falls in a forest with no one there to hear it, it doesn't make a sound?

One answer might be yes, the unobserved falling tree makes no sound. The basic reality of the universe may be thought of as one all-inclusive wave function in which everything is entangled. The universe is one big cloud of probabilities. Nothing exists per se until observed. But that verges on solipsism. So, science has considered a variety of other mechanisms for decoherence of quantum superposition – collapsing the wave function of anything tiny before it can get very big. It may happen simply because as things get bigger, they get more complex. They interfere with each other, fall out of phase, or vibrate at different frequencies. The latest theory posits that as mass slows down – dilates – time, even the gravity of earth would be enough to pull entangled particles into different time streams.

But at least some aspects of the macro-world do work through quantum effects. The efficiency of photosynthesis arises from quantum mechanical effects. Quantum mechanics may explain how birds use magnetic fields to navigate and our sense of smell. It may be that the cosmos is an entangled universal wave function that decoheres only at the boundary of individual acts of “observation.” But the observers would not simply be conscious human beings but any living thing interacting with its environment? Might the definition of life be that which breaks wave functions?

Gravity, Mass and Time II

I recently noted that mass, gravity and time may be essential features – givens – of our universe, that gravity is something that slows time and that at the speed of light, time stops. Actually time doesn't stop at the speed of light but becomes instantaneous. At that speed, everything happens at once. It's at an event horizon that time actually just stops passing. As whatever it is that is “falling” into a black hole passes the event horizon, the time that it may be experiencing cannot escape. Beyond that, at the singularity, anything/everything disappears from this universe (leaving aside the mechanism by which black holes “evaporate” over time). The mass and energy falling into the singularity is converted into the very warping of space that is the black hole.

How long does it take to fall from the event horizon into the singularity? Has time there stopped or has it become instantaneous? Apparently, if you could survive passing through the event horizon, you would still experience your own personal time. The length of time you'd experience would be very short but it would pass. As under general relativity there is no absolute standard of time, that would be all that counts for you. Indeed, time may be thought of as something entirely a matter of perspective. As I would be falling through the event horizon experiencing my own usual passage of time – it would not slow down or stop – it would appear to be doing so only to an outside observer experiencing his own usual passage of time.

Our human sense of the passage of time may be an entirely arbitrary experience defined by our nature as biological mechanisms (with mass) operating according to physical laws as elaborated by the evolution of life on our particular planet. One defining process may be the rate at which ribosomes add amino acids to the protein it is building (called translation). In all life on earth this process proceeds at the same speed of 10-20 additions per second. A “second” is a human unit of time but not an entirely arbitrary one as at the most fundamental level it is related to two apparent givens: the ability of our consciousness to hold just 2-3 seconds as our now and the existence of a basic unit – the Planck time – of 5.39x10 to the -44^th seconds. Or perhaps we might simply say that our human, species experience of time is one heart beat. That, however, might speed up a bit as we crossed the horizon.

Light tricks: The Delayed Choice Experiment

Physical Review A reports a recent "experimental observation of simultaneous wave and particle behavior in a narrowband single-photon wave packet."  This is also covered in a more accessible form in Science News.  The experiment is a variation on the delayed choice model that submits a photon to being observed (measured) after it has already been through a double beam splitter setup.  This essentially is a way of forcing the photon to behave first as a particle (by passing it through a beam splitter) and then after having made that "choice" having it behave like a wave again, as predicted by quantum physics.  The recent experiment takes this one step further by first stretching out a single photon so that it takes a small but measurable period of time to pass through the second beam splitter.  With the splitter in place, the photon acts like a wave.  With it removed while the photon is still passing through it, the photon manifests as a particle.  The very same photon during one single act of observation -- in two parts -- is both particle and wave.  This does not violate quantum physics but, as a scientist quoted by Science News suggests:  "‘Wave’ and ‘particle’ are just words.  In quantum physics, those words are imprecise at best."

This beautifully done experiment offers a window into the nature of not only light but the universe.  As noted before, at the speed of light, time does not exist.  Therefore, every photon is everywhere it will ever be at the same instant. The speed of light measures the degree of departure of our existence as mass affected by gravity from that cosmic external moment in which light exists.  When we measure light we seek to capture in time that which exists without time.  Wave and particle are the way we perceive its timeless nature as we move at our own pace through time and space.

What does the Turing Test test?

Saw the movie Ex Machina. The outside shots, filmed in Valldalen, Norway, are are simply gorgeous. Good flick and provoked some ruminating (avoiding plot details).

There seems no a priori reason to suppose that machine intelligence cannot reach the point of passing the Turing test. A complex enough programed machine able to “learn” from extracting patterns from massive data and using them to interact with humans should be able to “exhibit intelligent behavior equivalent to, or indistinguishable from, that of a human.” One can imagine such a machine as pictured in the movie.

But what does the Turing test really test. An “artificial intelligence” might be able to interpret and respond to the full range of human behavior and simulate the same. It might be able to “read” a conscious human better than an actual human might by picking up on subtle physical manifestations (as stored in its memory). With a large enough data base behind it and a multitude of “learned” behaviors it might convince a human that it was indeed intelligent and even self-aware. But would it be? Would the ability to simulate human behavior completely enough to appear human actually be human or entail consciousness? If programed with a sub-routine causing it to seek to persist (i.e., resist termination), would it be a self seeking self-preservation? Would programing allowing it to read human emotions and respond “appropriately” with simulated emotion mean it actually felt such emotions?

Would a machine intelligence able to simulate human behavior and emotions actually be able to love, hate, feel empathy and act with an awareness of itself and, perhaps more importantly, of an Other? Or might there still be something missing?

Smoked a cigar on my favorite bench while considering all this and watched some ants going about their business. Ants are extremely complex biological machines acting and reacting within their environment with purpose and an overall drive to self-perpetuate (both as individuals and as a collective). They may be conscious even if not self aware. Or is a certain basic self-awareness something that goes with being alive? Would even a very complex machine ever be alive even if very “intelligent?”

My guess is that machine intelligence – even if very complex and advanced and equipped with a self-referential sub-program allowing algorithmic analysis of itself – would not be conscious or alive. Thus not capable of emotion and therefore what we might call coldly rational. Is this why Bill Gates, Stephen Hawking and others are concerned about AI?

Gravity, Mass and Time

Recently finished physicist Kip Thorne's The Science of Interstellar about his work to make the movie as scientifically grounded as possible. While written for the interested layperson, some of it was hard to follow. But it provided a lot of food for ruminating about the deep connections between gravity, mass, time and the speed of light.

At the speed of light, time stops. Anything with mass that reached the speed of light also achieves infinite mass. (This is one good reason to believe that nothing with mass can go that fast. Anything of infinite mass would need a great deal of thrust to keep going, indeed, an infinite amount.) Photons have no mass and thus they gain no mass. Anything – some ghost without a machine – traveling with that photon at 186,000 MPS would also be timeless and thus everywhere that photon will ever be all at once.

Time also stops with an infinite mass that is not going anywhere, at a black hole. Gravity slows time. At the event horizon of a black hole, spacetime is so warped that nothing can escape upwards – not time, not space, not matter, not light – but falls down into the black hole until it reaches the singularity at the “bottom.” While the black hole may have a certain mass – the mass left over from the collapse of the star that formed it – the singularity itself has the equivalent of infinite mass. Anyone watching a friend drop into a black hole would never see him or her actually fall all the way past the event horizon. From the outside, the friend would be seen moving ever slower. At some point, a second to the falling friend might be, for example, a billion years to the outside observer.

Not just black holes slow time. Anything with mass does, including earth. Einstein's theory of relativity predicts this. And indeed, time on the GPS satellites (orbiting over 16 thousand miles up) run some 45,900 nano seconds slower per day than clocks on earth. The stronger the gravity, the slower time goes compared to places of less gravity.

Mass warps spacetime and achieves that effect through gravity. We don't understand where gravity comes from and it does not fit into the Standard Theory of quantum physics. Relativity seems to describe the effects of gravity but neither meshes with the Standard Theory nor explains from whence gravity comes. String theory has been the Standard Model's framework to incorporate relativity as quantum gravity. To do so, it would require extra dimensions beyond the four we observe (three space and time). But recent experiments have found no supporting evidence for the simplest forms of such theories.

It may be that mass, gravity, and time are just givens. Gravity is something that slows time. At the speed of light, time stops. Our experience of time – our consciousness – seems related to the speed of light. Mass keeps us from exceeding the speed of light. Random?