How Time Travel Works?

Introduction to how time travel works?

From millennium-skipping Victorians to phone booth-hopping teenagers, the term time travel often summons our most fantastic visions of what it means to move through the fourth dimension. But of course you don't need a time machine or a fancy wormhole to jaunt through the years.

As you've probably noticed, we're all constantly engaged in the act of time travel. At its most basic level, time is the rate of change in the universe -- and like it or not, we are constantly undergoing change. We age, the planets move around the sun, and things fall apart.

We measure the passage of time in seconds, minutes, hours and years, but this doesn't mean time flows at a constant rate. Just as the water in a river rushes or slows depending on the size of the channel, time flows at different rates in different places. In other words, time is relative.

But what causes this fluctuation along our one-way trek from the cradle to the grave? It all comes down to the relationship between time and space. Human beings frolic about in the three spatial dimensions of length, width and depth. Time joins the party as that most crucial fourth dimension. Time can't exist without space, and space can't exist without time. The two exist as one: the space-time continuum. Any event that occurs in the universe has to involve both space and time.

In this article, we'll look at the real-life, everyday methods of time travel in our universe, as well as some of the more far-fetched methods of dancing through the fourth dimension.

Time Travel Into the Future

If you want to advance through the years a little faster than the next person, you'll need to exploit space-time. Global positioning satellites pull this off every day, accruing an extra third-of-a-billionth of a second daily. Time passes faster in orbit, because satellites are farther away from the mass of the Earth. Down here on the surface, the planet's mass drags on time and slows it down in small measures.

We call this effect gravitational time dilation. According to Einstein's theory of general relativity, gravity is a curve in space-time and astronomers regularly observe this phenomenon when they study light moving near a sufficiently massive object. Particularly large suns, for instance, can cause an otherwise straight beam of light to curve in what we call the gravitational lensing effect.

What does this have to do with time? Remember: Any event that occurs in the universe has to involve both space and time. Gravity doesn't just pull on space; it also pulls on time.  

You wouldn't be able to notice minute changes in the flow of time, but a sufficiently massive object would make a huge difference -- say, like the supermassive black hole Sagittarius A at the center of our galaxy. Here, the mass of 4 million suns exists as a single, infinitely dense point, known as a singularity [source: NASA]. Circle this black hole for a while (without falling in) and you'd experience time at half the Earth rate. In other words, you'd round out a five-year journey to discover an entire decade had passed on Earth [source: Davies].

Speed also plays a role in the rate at which we experience time. Time passes more slowly the closer you approach the unbreakable cosmic speed limit we call the speed of light. For instance, the hands of a clock in a speeding train move more slowly than those of a stationary clock. A human passenger wouldn't feel the difference, but at the end of the trip the speeding clock would be slowed by billionths of a second. If such a train could attain 99.999 percent of light speed, only one year would pass onboard for every 223 years back at the train station [source: Davies].

In effect, this hypothetical commuter would have traveled into the future. But what about the past? Could the fastest starship imaginable turn back the clock?

Time Travel Into the Past

We've established that time travel into the future happens all the time. Scientists have proven it in experiments, and the idea is a fundamental aspect of Einstein's theory of relativity. You'll make it to the future; it's just a question of how fast the trip will be. But what about travel into the past? A glance into the night sky should supply an answer.

The Milky Way galaxy is roughly 100,000 light-years wide, so light from its more distant stars can take thousands upon thousands of years to reach Earth. Glimpse that light, and you're essentially looking back in time. When astronomers measure the cosmic microwave background radiation, they stare back more than 10 billion years into a primordial cosmic age. But can we do better than this?

There's nothing in Einstein's theory that precludes time travel into the past, but the very premise of pushing a button and going back to yesterday violates the law of causality, or cause and effect. One event happens in our universe, and it leads to yet another in an endless one-way string of events. In every instance, the cause occurs before the effect. Just try to imagine a different reality, say, in which a murder victim dies of his or her gunshot wound before being shot. It violates reality as we know it; thus, many scientists dismiss time travel into the past as an impossibility.

Some scientists have proposed the idea of using faster-than-light travel to journey back in time. After all, if time slows as an object approaches the speed of light, then might exceeding that speed cause time to flow backward? Of course, as an object nears the speed of light, its relativistic mass increases until, at the speed of light, it becomes infinite. Accelerating an infinite mass any faster than that is impossible. Warp speed technology could theoretically cheat the universal speed limit by propelling a bubble of space-time across the universe, but even this would come with colossal, far-future energy costs.

But what if time travel into the past and future depends less on speculative space propulsion technology and more on existing cosmic phenomena? Set a course for the black hole.

Black Holes and Kerr Rings

Circle a black hole long enough, and gravitational time dilation will take you into the future. But what would happen if you flew right into the maw of this cosmic titan? Most scientists agree the black hole would probably crush you, but one unique variety of black hole might not: the Kerr black hole or Kerr ring.

In 1963, New Zealand mathematician Roy Kerr proposed the first realistic theory for a rotating black hole. The concept hinges on neutron stars, which are massive collapsed stars the size of Manhattan but with the mass of Earth's sun [source: Kaku]. Kerr postulated that if dying stars collapsed into a rotating ring of neutron stars, their centrifugal force would prevent them from turning into a singularity. Since the black hole wouldn't have a singularity, Kerr believed it would be safe to enter without fear of the infinite gravitational force at its center.

If Kerr black holes exist, scientists speculate that we might pass through them and exit through a white hole. Think of this as the exhaust end of a black hole. Instead of pulling everything into its gravitational force, the white hole would push everything out and away from it -- perhaps into another time or even another universe.

Kerr black holes are purely theoretical, but if they do exist they offer the adventurous time traveler a one-way trip into the past or future. And while a tremendously advanced civilization might develop a means of calibrating such a method of time travel, there's no telling where or when a "wild" Kerr black hole might leave you.

Wormholes

Theoretical Kerr black holes aren't the only possible cosmic shortcut to the past or future. As made popular by everything from "Star Trek: Deep Space Nine" to "Donnie Darko," there's also the equally theoretical Einstein-Rosen bridge to consider. But of course you know this better as a wormhole.

Einstein's general theory ofrelativity allows for the existence of wormholes since it states that any mass curves space-time. To understand this curvature, think about two people holding a bedsheet up and stretching it tight. If one person were to place a baseball on the bedsheet, the weight of the baseball would roll to the middle of the sheet and cause the sheet to curve at that point. Now, if a marble were placed on the edge of the same bedsheet it would travel toward the baseball because of the curve.

In this simplified example, space is depicted as a two-dimensional plane rather than a four-dimensional one. Imagine that this sheet is folded over, leaving a space between the top and bottom. Placing the baseball on the top side will cause a curvature to form. If an equal mass were placed on the bottom part of the sheet at a point that corresponds with the location of the baseball on the top, the second mass would eventually meet with the baseball. This is similar to how wormholes might develop.

In space, masses that place pressure on different parts of the universe could combine eventually to create a kind of tunnel. This tunnel would, in theory, join two separate times and allow passage between them. Of course, it's also possible that some unforeseen physical or quantum property prevents such a wormhole from occurring. And even if they do exist, they may be incredibly unstable.

According to astrophysicist Stephen Hawking, wormholes may exist in quantum foam, the smallest environment in the universe. Here, tiny tunnels constantly blink in and out of existence, momentarily linking separate places and time like an ever-changing game of "Chutes and Ladders."

Wormholes such as these might prove too small and too brief for human time travel, but might we one day learn to capture, stabilize and enlarge them? Certainly, says Hawking, provided you're prepared for some feedback. If we were to artificially prolong the life of a tunnel through folded space-time, a radiation feedback loop might occur, destroying the time tunnel in the same way audio feedback can wreck a speaker.

Cosmic String

We've blown through black holes and wormholes, but there's yet another possible means of time traveling via theoretic cosmic phenomena. For this scheme, we turn to physicist J. Richard Gott, who introduced the idea of cosmic string back in 1991. As the name suggests, these are string like objects that some scientists believe were formed in the early universe.

These strings may weave throughout the entire universe, thinner than an atom and under immense pressure. Naturally, this means they'd pack quite a gravitational pull on anything that passes near them, enabling objects attached to a cosmic string to travel at incredible speeds and benefit from time dilation. By pulling two cosmic strings close together or stretching one string close to a black hole, it might be possible to warp space-time enough to create what's called a closed timelike curve.

Using the gravity produced by the two cosmic strings (or the string and black hole), a spaceship theoretically could propel itself into the past. To do this, it would loop around the cosmic strings.

Quantum strings are highly speculative, however. Gott himself said that in order to travel back in time even one year, it would take a loop of string that contained half the mass-energy of an entire galaxy. In other words, you'd have to split half the atoms in the galaxy to power your time machine. And, as with any time machine, you couldn't go back farther than the point at which the time machine was created.

Oh yes, and then there are the time paradoxes.

Time Travel Paradox

As we mentioned before, the concept of traveling into the past becomes a bit murky the second causality rears its head. Cause comes before effect, at least in this universe, which manages to muck up even the best-laid time traveling plans.

For starters, if you traveled back in time 200 years, you'd emerge in a time before you were born. Think about that for a second. In the flow of time, the effect (you) would exist before the cause (your birth).

To better understand what we're dealing with here, consider the famousgrandfather paradox. You're a time-traveling assassin, and your target just happens to be your own grandfather. So you pop through the nearest wormhole and walk up to a spry 18-year-old version of your father's father. You raise your laser blaster, but just what happens when you pull the trigger?

Think about it. You haven't been born yet. Neither has your father. If you kill your own grandfather in the past, he'll never have a son. That son will never have you, and you'll never happen to take that job as a time-traveling assassin. You wouldn't exist to pull the trigger, thus negating the entire string of events. We call this aninconsistent causal loop.

On the other hand, we have to consider the idea of a consistent causal loop. While equally thought-provoking, this theoretical model of time travel is paradox free. According to physicist Paul Davies, such a loop might play out like this: A math professor travels into the future and steals a groundbreaking math theorem. The professor then gives the theorem to a promising student. Then, that promising student grows up to be the very person from whom the professor stole the theorem to begin with.

Then there's the post-selected model of time travel, which involves distorted probability close to any paradoxical situation [source: Sanders]. What does this mean? Well, put yourself in the shoes of the time-traveling assassin again. This time travel model would make your grandfather virtually death proof. You can pull the trigger, but the laser will malfunction. Perhaps a bird will poop at just the right moment, but some quantum fluctuation will occur to prevent a paradoxical situation from taking place.

But then there's another possibility: The future or past you travel into might just be a parallel universe. Think of it as a separate sandbox: You can build or destroy all the castles you want in it, but it doesn't affect your home sandbox in the slightest. So if the past you travel into exists in a separate timeline, killing your grandfather in cold blood is no big whoop. Of course, this might mean that every time jaunt would land you in a new parallel universe and you might never return to your original sandbox.

Brain Wave Entrainment

Brainwave Patterns

The brain is made up of approximately 100 billion nerve cells called neurons which communicate with each other twenty-four hours a day using electrical signals. The combination of millions of these neurons sending electrical signals at once produces an enormous of electrical activity in the brain and these electrical discharges can be detected by using EEG technology (Electroencephalography). EEG records this electrical activity as ‘Brain Wave Patterns’ – because of its “wave” and cyclic-like nature.

The presence of these electrical discharges indicates the different states, particular your mental state at a certain time. However, these patterns are not random; they are closely correlated with your emotions, your thoughts, your state of being, and every function of the various systems of your body. In short, the entire quality of your life has something to do with these patterns. It also means that what you do to yourself can influences your brain wave patterns. It’s like a meter that displays the state of your consciousness.

Brainwave patterns can be categorized into four main groups according to the frequency (Hz) range that they are in.

Brainwave Range

• Beta (13 Hz – 30 Hz) – The normal state of wakeful consciousness; the state you are now while reading this report. High level of Beta is associated with alertness but it could also be linked to anxiety, uneasiness, stress and panic. At the higher end of beta, at around 38 Hz – 70 Hz, the brain will fall into the Gamma.
• Alpha (8 Hz – 12 Hz) – This is a state of relaxation and self relief. Hypnosis, autosuggestion is done at this level.This state is also known as ‘Accelerated Learning State’ because the brain seems more to be receptive and open to new information, particular suggestion.You normally experience alpha just after you awake and before falling into sleep. It’s the door to the unconscious.
• Theta (3 Hz – 8 Hz) – A deep state of relaxation. Dreams (REM Sleep) and deep meditations are often associated with theta. Access to the unconscious mind.
• Delta (0.5 Hz – 3 Hz) – Dreamless or Non-REM sleep. A state of trance and loss of body awareness. Maintaining awareness during theta could enable one to access to the unconscious and super-conscious mind (exp. people like Yogis and Zen monks who have practiced meditation for decades and attained higher consciousness).

We spend some amount of time in each brain state everyday; it is part of life cycle and most likely the state changes according to the activity that we are engaged in. Either it goes up or down.

If you have glanced through the list above carefully, you would have noticed that each brain state plays a different role in maintaining life’s vitality such as relaxation and self-relief, accelerated learning, accessing the unconscious and etc.

Now here’s the ULTIMATE question: what if there’s a possibility that we can train or induce our brain to go into the different brain states at will (anytime) and utilize the power of the brain state possesses?

For example; by inducing your brain into alpha, you can reprogram your subconscious with new beliefs that serve you and drop those that limit you. And in case that if you are not aware, the biggest obstruction that most people face in ‘self-development’ is having to change the past limiting beliefs. They either do not know how to do it or not knowing that beliefs are held in the subconscious, and again, which could be done in alpha; the path that connects the conscious to the subconscious.

Besides, by tapping into the power of the various state of consciousness, you could easily replicate the mind of a genius; think about Einstein’s or Mozart’s.

…the answer lies in Brain Wave Entrainment

Brainwave Entrainment

‘Entrainment’ is actually a physics term that coined by Christian Huygens in 1665 to describe the phenomena of cyclical energies recalibrating to fall into rhythm with one another. Christian observed that when two different bodies that vibrate at different rates are brought together, they would tend to lock into phase and vibrate in harmony.

For example, if a tuning fork which produces a frequency of 350 Hz is struck and then brought into the vicinity of another 350 Hz tuning fork, the second fork will begin to vibrate as well. Here, the first fork is said to have entrained the second fork.

Entrainment has demonstrated that even very subtle cyclical energies have a substantive impart on their neighboring cyclical energies. It is not a force like gravity but instead, a phenomenon; a conservation of energy that enable two cycles to work more efficiently.

After numerous of extensive researches and experiments, scientists and neurologists have found that this same phenomenon could also be applied in training the brain, (by using exactly the same principle that Christian Huygens discovered).

Brainwave entrainment is defined as any practice with the purpose of causing the brainwave frequency to fall into the same beats of the external periodic stimulus, which is having a frequency corresponding to the intended brain-state (for example, to induce sleep or relaxation).

How It Works

First, stimulus is introduced to the brain, whether through the ears, eyes or other senses. Such stimulus will make the brain responds by emitting an electrical charge, known as ‘Cortical Evoked Response’. This electrical responses travel throughout the brain to become what an individual sees and hears. The strength of this cortical evoked response depends on the type and effectiveness of the stimulus, which is very important in gaining a significant result particular for the purpose of entraining the brain.

When the brain is consistently exposed to periodic stimulus, such as flashes of light or drumbeats and/or chanting, the brain will tend to tune or entrain its electric cycle to match the external stimulus (as described in ‘Entrainment’).

The tendency of the brain to tune in to and match the external stimulus frequency is known as‘Frequency Following Response’ or ‘FFR’ and this phenomenon can be used to effectively alter the brain wave patterns.