Gorilla Alien Future Primate Particle Beam Molecular Reconstructer

The Particle Beam Molecular Reconstructor is an advanced form of transportation utilizing the gamma ray. The mass of any solid subject can be converted into microscopic sub particles and inserted through a Electro-magnetic ''shielded tube'' which rides inside of the gamma ray. Then the machines computer calculates the amount of energy needed to reach the coordinates. A preliminary sensor beam is sent to verify target and keep path clear. The sensor, the confirmation and the atom transfer all occur within a 100th of a second. Once the subject has reached its destination the gamma ray is turned off and Electro shield then reverses polarity, causing the compressed particles to reform to their original state. The voltage to run this process is so great, that element 115 is the only known (but still UN-duplicable) material, considered to power the P.B.M.R. Gamma rays are invisible to the human eye and have recently been detected streaming out of black holes which explains the UFO's recovered flight data. The alien's are harnessing the natural gamma rays to defy the crushing force of the black hole. It's hard to imagine how this procedure works on an entire ship but, the ET's clearly have the technology to Ride the Lightning.

Teleporting Larger Objects Becomes Real Possibility

AlienGlow1.bmp (164694 bytes)

The dream of teleporting atoms and molecules - and maybe even larger
objects - has become a real possibility for the first time. The
advance is thanks to physicists who have suggested a method that in
theory could be used to "entangle" absolutely any kind of particle.

Quantum entanglement is the bizarre property that allows two
particles to behave as one, no matter how far apart they are. If you
measure the state of one particle, you instantly determine the state
of the other. This could one day allow us to teleport objects by
transferring their properties instantly from one place to another.

Until now, physicists have only been able to entangle photons,
electrons and atoms, using different methods in each case.
For instance, atoms are entangled by forcing them to interact inside
an optical trap, while photons are made to interact with a crystal.

"These schemes are very specific," says Sougato Bose of the
University of Oxford. But Bose and Dipankar Home, of the Bose
Institute in Calcutta, have now demonstrated a single mechanism that
could be used to entangle any particles, even atoms or large
molecules.

To see how it works, consider the angular momentum or "spin" of an
electron. To entangle the spins of two electrons, you first need to
make sure they're identical in all respects but their spin. Then you
shoot the electrons simultaneously into a beam splitter.

This device "splits" each electron into a quantum state called a
superposition, which gives it an equal probability of traveling
down either of two paths. Only when you try to detect the electron
do you know which path it took. If you split two electrons
simultaneously, both paths could have one electron each (which will
happen half of the time) or either path could have both.

Bose and Home show mathematically that whenever one electron is
detected in each path, they will be entangled. While a similar effect
has been demonstrated before for photons, the photons used were
already entangled in another way, even before they reached the beam
splitter.

"One of the advances we have made is that these two particles could
be from completely independent sources," says Bose.

The technique should work for any objects - atoms, molecules and who
knows what else - as long as you can split the beam into a quantum
superposition.

Anton Zeilinger, a quantum physicist at the University of Vienna in
Austria, has already shown that this quantum state is possible with
buckyballs - football-shaped molecules of C60. Although entangling
such large objects is beyond our technical abilities at the moment,
this is the first technique that might one day make it possible.

Any scheme that expands the range of particles that can be entangled
is important, says Zeilinger. Entangling massive particles would mean
they could then be used for quantum cryptography, computing and even
teleportation.

"It would be fascinating," he says. "The possibility that you can
teleport not just quantum states of photons, but also of more massive
particles, that in itself is an interesting goal."

Source: Journal reference: Physical Review Letters
vol 88, article 05401

Teleportation is the name given by science fiction writers to the feat of making an object or person disintegrate in one place while a perfect replica appears somewhere else. How this is accomplished is usually not explained in detail, but the general idea seems to be that the original object is scanned in such a way as to extract all the information from it, then this information is transmitted to the receiving location and used to construct the replica, not necessarily from the actual material of the original, but perhaps from atoms of the same kinds, arranged in exactly the same pattern as the original. A AlienGlow1.bmp (164694 bytes)

teleportation machine would be like a fax machine, except that it would work on 3-dimensional objects as well as documents, it would produce an exact copy rather than an approximate facsimile, and it would destroy the original in the process of scanning it. A few science fiction writers consider teleporters that preserve the original, and the plot gets complicated when the original and teleported versions of the same person meet; but the more common kind of teleporter destroys the original, functioning as a super transportation device, not as a perfect replicator of souls and bodies.

Matter is composed of atoms. This is a consequence of the manner in which the electrons are distributed throughout space in the attractive field exerted by the nuclei. The nuclei act as point attractors immersed in a cloud of negative charge, the electron density

(r). The electron density describes the manner in which the electronic charge is distributed throughout real space. The electron density is a measurable property and it determines the appearance and form of matter. This is illustrated in the following figures. Figure 1 displays the spatial distribution of the electron density in the plane containing the two carbon and four hydrogen nuclei of the ethene molecule. The electron density is a maximum at the position of each nucleus and decays rapidly away from these positions. When this diagram is translated into three dimensions, the cloud of negative charge is seen to be most dense at nuclear positions and to become more diffuse as one moves away from these centres of attraction, as illustrated in Figure 2. The presence of local maxima at the positions of the nuclei is the general and also the dominant topological property of

(r). Figure 3 illustrates the same feature for the 110 plane of carbon nuclei in the diamond lattice.

Australia Has Teleportation Breakthrough
Scientists Teleport Laser Beam; Not Quite a 'Star Trek' Transporter...Yet

By Belinda Goldsmith
Reuters

CANBERRA (June 17) - In a world breakthrough out of the realms of Star Trek, scientists in Australia have successfully teleported a laser beam of light from one spot to another in a split second but warn: don't sell the car yet.

A team of physicists at the Australian National University announced on Monday they had successfully disembodied a laser beam in one location and rebuilt it in a different spot about one meter away in the blink of an eye.

Project leader Dr Ping Koy Lam said there was a close resemblance between what his team had achieved and the movement of people in the science fiction series Star Trek but reality was still light years off beaming human beings between locations.

"In theory there is nothing stopping us from doing it but the complexity of the problem is so huge that no one is thinking seriously about it at the moment," Lam told a news conference.

However Lam said science was not too far from being able to teleport solid matter from one location to another.

"My prediction is...it will probably be done by someone in the next three to five years, that is the teleportation of a single atom," said Lam, who has worked on teleporting since 1997.

But he said humans posed a near-impossible task as we are made up of zillions of atoms -- quantified by a one with 27 zeroes -- so forget Star Trek where the Starship Enterprise crew step into a transporter, vaporize, then re-assemble elsewhere.

The laser beam was destroyed during teleporting which is achieved using a process known as quantum entanglement.

However the breakthrough opens up enormous possibilities for future super-fast and super-secure communications systems, such as quantum computers over the next decade.

WORLD RACE

Physicists believe quantum computers could outperform classical computers with enormous memory and the ability to solve problems millions of times faster.

Teleportation became one of the hottest topics among physicists in quantum mechanics in the past decade, after the IBM lab in the United States provided theoretical underpinning for the work in 1993. Since then about 40 laboratories globally have been experimenting in this area.

Although teams in California and Denmark were the first to do preliminary work on teleportation, the ANU team of scientists from Australia, Germany, France, China and New Zealand was the first to achieve a successful trial with 100 percent reliability.

The idea is if quantum particles like electrons, ions, and atoms have the same properties, they are essentially the same.

So if the properties of quantum particles making up an object are reproduced in another particle group, there would be a precise duplication of the object, so only information about the particles' properties need be transmitted, not the particles.

The inability to pass the information reliably has been a major stumbling block in past "entanglement" experiments.

ANU team member Warwick Bowen said they first successfully teleported a laser beam on May 23 to their great surprise, and repeated the success time after time in following weeks using their small-car-sized transporter, ironing out certain glitches.

"Even in Star Trek they realize there are problems with teleportation," Bowen told the news conference.

"It is such a complicated experiment that nobody knows whether their particular set-up is going to work until you do it....and it turns out our system is very good."

06/17/02 03:19 ET

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Teleportation works - but not for Scotty

Tim Radford, science editor
Thursday June 17, 2004
The Guardian

Captain Kirk and Mr Spock are as far away as ever - but in separate experiments in Austria and in Colorado, scientists have once again demonstrated that teleportation works.

The two groups report in Nature today that using a bizarre phenomenon called quantum entanglement, they teleported information about quantum states between atoms without using any physical links. In effect, they did not beam up the Cheshire cat, just the Cheshire cat's smile. That is, they transmitted not the atom but its quantum state - its energy, motion, magnetic field and so on - to another atom.

Such experiments could pay off one day with the development of quantum computers, which would be able to tackle problems that right now defy the world's fastest supercomputers. A team at the US National Institute of Standards and Technology used laser beam manipulations to transfer quantum states from one beryllium atom to another. And a group at the University of Innsbruck describe the teleportation of a quantum state between two calcium atoms.

Both groups used ions - atoms with electrons dislodged - and both exploited the strange properties of the quantum world. At the sub-atomic scale matter behaves unexpectedly. Ions can be persuaded into a special state called superposition in which they can literally be in two places at once. They can be entangled with each other, so that their behaviour is linked in predicatble ways, as if they were connected by an invisible force. Einstein called this "spooky action at a distance".

Physicists have been playing with this kind of teleportation now for more than five years. The technique could be useful for transporting information in tomorrow's quantum computers, no bigger that a thimble but capable of solving problems that are too big for today's state of the art machines. But although researchers have repeatedly teleported quantum information, nobody has yet transferred a single atom.

And as for Star Trek-style teleportation, forget it: it would require exact information about every atom in each Federation officer's body. The stack of computer discs needed to store this quantity of data would reach at least a third of the way to the centre of the galaxy.

http://www.guardian.co.uk/uk_news/story/0,3604,1240489,00.html

Teleportation goes long distance

By Paul Rincon
BBC News Online science staff

Properties were teleported from one photon to another

Physicists have carried out successful teleportation with particles of light over a distance of 600m across the River Danube in Austria.

Long distance teleportation is crucial if dreams of superfast quantum computing are to be realised.

When physicists say "teleportation", they are describing the transfer of key properties from one particle to another without a physical link.

The team has published its findings in the academic journal Nature.

The really interesting question for us was whether we could do this outside a lab setting

Rupert Ursin, University of Vienna

Researchers from the University of Vienna and the Austrian Academy of Science used an 800m-long optical fibre fed through a public sewer system tunnel to connect labs on opposite sides of the River Danube.

The link establishes a channel between the labs, dubbed Alice and Bob. This enables the properties, or "quantum states", of light particles to be transferred between the sender (Alice) and the receiver (Bob).

In the computers of tomorrow, this information would form the qubits (the quantum form of the digital bits 1 and 0) of data processing through the machines.

The Austrian team encoded their qubits using a property of light particles, also called photons, known as polarisation. This property describes the direction in which they oscillate.

Quantum teleportation relies on an aspect of physics known as "entanglement", whereby the properties of two particles can be tied together even when they are far apart. Einstein called it "spooky action at a distance".

Speed of light

The Nature study used an experimental method in which Alice performs a joint measurement on one photon in the entangled pair and on an "input" photon.

As a result of this measurement, Bob transforms the quantum state of the other photon in the entangled pair into that of the input photon.

The researchers were able to teleport three distinct polarisation states between Alice and Bob via the fibre-optic cable through the tunnel.

The significance of this research was that it took place under "real world" conditions.

"The really interesting question for us was whether we could do this outside a lab setting, in the environment used for today's fibre-optic communications," co-author Rupert Ursin of the University of Vienna told BBC News Online.

"This is very important if you are talking about investing money in quantum communication."

Quantum teleportation could be harnessed for fast, powerful computers or communication networks.

In the underground sewer pipe tunnel, the fibre-optic link was exposed to temperature fluctuations and other environmental factors that could interfere with the process.

Nicolas Gisin of the University of Geneva, Switzerland, successfully teleported quantum bits, or qubits, between two labs over 2km of coiled cable. But the actual distance between the two labs was about 55m.

Mr Ursin said a next step towards worldwide quantum communication would be to attempt the teleportation of quantum states between particles using a satellite link.

"The first thing you will need to do is find out whether you can have entanglement over such long distances. But teleportation will be one of the next goals," he added.

The researchers were also able to double the efficiency of teleportation using linear optics.
http://news.bbc.co.uk/2/hi/science/nature/3576594.stm