Well. I was wrong. As always, it seems that all the decent ideas these days are already "taken".
Having said that..and a tad disappointed ...I come to the current literature about a related fascinating concept called as the Boltzmann brain
What is it ? (chapoed from wikipedia..what else ?)
A Boltzmann brain is a hypothesized self-aware entity which arises due to random fluctuations out of some future state of chaos. The idea is named for Ludwig Boltzmann, whose ideas led to the proposal of such entities. It is often referred to in the context of the "Boltzmann brain paradox" or "problem".
The second law of thermodynamics states that the entropy in the universe will always increase. We may think of the most likely state of the universe as one of high entropy, closer to uniform and without order.
So why is the observed entropy so low?
Boltzmann proposed that we and our observed low-entropy world are a random fluctuation in a higher-entropy universe.
Even in a near-equilibrium state, there will be stochastic fluctuations in the level of entropy. The most common fluctuations will be relatively small, resulting in only small amounts of organization, while larger fluctuations and their resulting greater levels of organization will be comparatively more rare. Large fluctuations would be almost inconceivably rare, but this can be explained by the enormous size of the universe and by the idea that if we are the results of a fluctuation, there is a "selection bias": We observe this very unlikely universe because the unlikely conditions are necessary for us to be here.
This leads to the Boltzmann brain concept:
If our current level of organization, having many self-aware entities, is a result of a random fluctuation, it is much less likely than a level of organization which is only just able to create a single self-aware entity.
For every universe with the level of organization we see, there should be an enormous number of lone Boltzmann brains floating around in unorganized environments. This refutes the observer argument above: the organization I see is vastly more than what is required to explain my consciousness, and therefore it is highly unlikely that I am the result of a stochastic fluctuation.
The Boltzmann brains paradox is that it is more likely that a brain randomly forms out of the chaos with false memories of its life than that the universe around us would have billions of self-aware brains.
The idea sounds absurd, but it is helping cosmologists grapple with models of the universe, and our place in it. Cosmology, indeed most of science, assumes that we humans are typical observers in the grand scheme of things. Ever since the 16th century, when Polish astronomer Nicolaus Copernicus argued that the Earth is just a rock orbiting the sun, we have been dethroned from a unique position in the cosmos. The laws of physics seem to be the same in our neighbourhood as in the rest of the visible universe. So the idea has been enshrined that unless we have reason to think otherwise, we should assume that we are typical. "This assumption is very essential to everything that we do," says Alex Vilenkin of Tufts University in Massachusetts. "If we don't assume that our observations are typical of observers, we wouldn't be able to conclude anything."
That's because if we aren't typical, then whatever we see is not representative of the universe at large.
So here's the problem: some well-established cosmological models predict that, trillions of years in the future, Boltzmann brains could vastly outnumber "ordinary observers" like us, who depend on aeons of evolution and life support. If that is true, then over the lifetime of the universe, they - not we - might be the typical ones. That's scary, because models suggest that their view of the cosmos would be strikingly different from ours.
Now researchers are trying to figure out just how common Boltzmann brains could be and whether there is a way to banish them, or at least stop them from outnumbering us. Indeed, the Boltzmann brains problem is forcing cosmologists to revisit their most crucial assumptions about the structure of the universe. Either they must explain how the cosmos can produce enough ordinary observers to stay ahead of the "pop-up" brains, or we may have to accept that our ideas are wrong and that the ultimate fate of the universe is coming sooner than we thought.
All in their heads
Boltzmann brains reared their ugly heads in the late 1990s, when astrophysicists discovered that the expansion of the universe is accelerating, rather than slowing down as most had expected. One possible explanation for this "dark energy" has been known for decades: empty space could hold inherent energy that has a repulsive effect, driving space to expand and forcing matter apart. This effect goes by different names - the cosmological constant, or vacuum energy. Why it exists is one of the biggest mysteries in physics.
Regardless of its origins, vacuum energy is active and always subtly fluctuating - occasionally enough to transform into particles and matter. A photon might pop up here, an atom over there. The bigger and more complex the object, the less likely it is to appear.
Wait long enough and a Boltzmann brain could pop up
What exactly might these things be? In theory, they could take on almost any form, but the larger and more complex they are, the less likely it is that they will appear, according to the laws of probability and quantum mechanics. They could be disembodied brains with eyeballs, floating in outer space. They could consist of a whole body, encased in a space suit and equipped with an oxygen tank. They could be human brains, animal brains or an intelligent alien species made of gas. What matters is that they qualify as conscious - by whatever definition researchers agree on.
They need not even be actual brains. If computers could become complex enough to be considered conscious, for instance, they would qualify too. Since computer chips pack large amounts of processing power into a tiny space, silicon-based Boltzmann brains could be much smaller than biological brains. If so, that might make conscious computers more likely to pop out of the vacuum than biological entities, meaning they could be the ones to dominate the universe
"It looks like a miracle," says theorist Andrei Linde of Stanford University in California. "Not entirely impossible, but just extremely improbable."
So if the universe can produce two kinds of observers - ordinary ones like us, and freakish Boltzmann brains - cosmologists have a problem. To preserve the assumption that we are typical, they need to show that their models of the universe do not allow Boltzmann brains to outnumber us.
Consider the theory of inflation, which most cosmologists regard as the best explanation of our universe. Developed in part by Linde and Vilenkin in the 1980s, inflation says that just after the big bang, our universe expanded enormously and rapidly, making it extremely "smooth" and homogeneous, but with just enough bumpiness early on to allow matter to clump together to form stars and galaxies.
Many cosmologists buy into the idea that inflation is continuing at various points in the universe - a theory known as eternal inflation. In this picture there is a vast backdrop of expanding space, out of which new "pocket universes" are continually budding off
To tame these infinities, researchers have been trying to figure out each type of observer's likelihood of existing. "What we're struggling with is the question of computing probabilities in such scenarios," says Raphael Bousso of the University of California, Berkeley. "You produce an infinite number of bubbles, and each of them is infinitely large, so you have to find a way of comparing infinities. Boltzmann brains are one of the constraints that help us figure out how to think about this kind of cosmology correctly."
The most radical solution comes from Don Page of the University of Alberta in Edmonton, Canada.
He argues that our universe must have a built-in self-destruct mechanism that will kill it off before Boltzmann brains can dominate.
Just as the vacuum energy has quantum fluctuations that can generate Boltzmann brains, the energy itself can jiggle and "decay" to a higher or lower level. In eternal inflation, this is how a pocket universe begins. The decay starts at a tiny point and releases an enormous amount of energy, creating a bubble that expands outward at nearly the speed of light. This bubble of fire would eradicate us, along with all structure in the cosmos. "It would be destroying the universe as we know it," Page says.
Such a decay would act like a cosmic reset button, preventing the universe from getting old enough to let Boltzmann brains take over. For this to work in our universe, says Page, it needs to happen within about 20 billion years from now. Wait any longer, he says, and our universe will be expanding so rapidly that such decay bubbles could never catch up: patches of the original universe would remain, forever spawning Boltzmann brains. Although it is nothing our grandchildren will need to worry about, this time frame is much shorter than most had expected.
Other researchers argue that taking a broader view can banish Boltzmann brains without requiring our universe to self-destruct at such a tender age. The multiverse, they claim, is evolving an infinite number of regular observers like us. The only problem is that an infinite number of Boltzmann brains are popping up too. However, not all infinities are equal. To see who is winning the race, physicists have begun counting up the observers. "This is where people start fighting," says Linde.
Picking pocketsLinde's approach looks across multiple pocket universes and counts the number of observers in a certain volume of space at any given moment.
In this picture, many universes can support creatures like us for a short period of time, but in the long run give rise to Boltzmann brains.
However, since new universes are always being created by eternal inflation, Linde says, when you add up all the observers at any given time, ordinary ones always outnumber Boltzmann brains because there is a continual supply of them. "If you use this measure," he says, "then this paradox with Boltzmann brains does not appear."
Vilenkin has his own solution, also based on eternal inflation, but using a different method of counting up the observers. He instead compares the likelihood of new pocket universes forming with the likelihood of Boltzmann brains popping up. According to his calculations, too, regular observers are always appearing faster than Boltzmann brains.
Other physicists are not convinced that anyone can yet justify the assumptions behind eternal inflation models clearly enough to make tallies across multiple universes, so they are wary of using these models to resolve the Boltzmann brain problem. Page, for one, argues that these solutions suffer from "the ambiguity of taking ratios of infinite numbers".
Bousso goes further. He says it is not possible, even in principle, to take an overview of the multiverse. In a universe like ours, there is only so much that any one observer can see. That's because observers can't travel any faster than the speed of light, and neither can any signals. Bousso recommends sticking with a local view rather than trying to calculate across multiple universes. "Let's make our theories describe any possible history, but not pretend that they all have to fit together into some God's-eye view," he says. Taking Bousso's approach seems to solve the Boltzmann brain problem but, like Page's proposal, only if the universe as we know it self-destructs .
In contrast to Page's work, Bousso looks at a much smaller area of space: the volume inside a given observer's horizon. Since this allows much less space for Boltzmann brains to pop up in, the universe could last much longer before self-destructing, though still decaying soon enough that Boltzmann brains won't dominate. "The only way that Boltzmann brains could win is if the vacuum lasts longer than it takes for a Boltzmann brain to appear," Bousso says. The time it would take to happen even once is "insanely long", he says. Even if the universe self-destructed after an incredibly long time - 10 to the power of 1020 years - that would still be soon enough to prevent Boltzmann brains from taking over.
So which approach is correct? And what does banishing Boltzmann brains ultimately tell us about the universe? There is no consensus yet, and experiments cannot test these proposals. Page says we're still "babes in the woods" when it comes to grappling with the multiverse. So far he has been content just to point out the potential problem.
However, Boltzmann brains could indicate which ways of calculating probabilities in the multiverse are right or wrong. Vilenkin says that any decent method should give the answer "that the regular observers win over freak observers". Linde has a similar outlook. "If we suggest some probability measure in inflationary cosmology and it leads to this Boltzmann brain problem," he says, "then this is another way to learn that we are doing something wrong."
Conversely, if a method for counting Boltzmann brains also provides insight into a different problem, that could be a sign that it's on the right track. Bousso and his colleagues have recently extended their approach of working within a given horizon to calculate the strength of vacuum energy a typical observer would measure. Previous methods for predicting this energy density gave results larger than the observed value by factors of 10, 1000 or even many billions. Bousso's result gets much closer to the measured value. "We didn't know what the answer would be," he says, "but it just led to an enormous improvement."
So cracking the conundrum of Boltzmann brains may do more than simply remove their threat, allowing cosmologists to continue assuming we are typical: it may also help us weed out models of the universe that fall short of explaining its strangeness. Then again, despite astronomical odds, there remains the unsettling possibility that we are all, in fact, Boltzmann brains... POP.
