My Gift To You - Breakthrough To Success

I have a gift for you, two tickets to Christopher Howards incredible Breakthrough to Success, a worldwide success in itself this event will help you to transform your life in any area you choose: health, motivation, financial, relationships… A 3 day event designed to create new pathways of success in any area in your life, I have tickets to give away only because I have done some training with this organisation.

Who Must Attend Breakthrough to Success?

• If you know that you are capable of much more than you are currently exhibiting in life
• If you are unwilling to settle for anything less than your unlimited potential
• If you feel lost or uncertain about the direction you are headed and are committed to making a change
• If you want to accelerate your success and learn the tools that guarantee maximum empowerment

You Will Learn To …

• Release Negative Emotions
• Consciously Navigate the Future
• Take Charge of your Destiny
• Release False Associations & Limiting Thoughts such as …
  “I have low self-esteem …
  “I can’t have a great relationship …”
  “It’s hard to make $$$ …”
• Break through the Limitations of the Past
• Identify Your Critical Success Factors in all Areas of Life
• Role Model and Integrate Excellence for Outstanding Results
• Accelerate Your Success and Gain Propulsion Toward Your Dreams

Please click on the links provided to access your tickets as my gift to you.

Tickets to Breakthrough to Success Australia/NZ

Sydney March 28 - 30, 2008

Auckland April 4 - 6, 2008

Perth April 11 - 13, 2008

Brisbane April 18 - 20, 2008

Melbourne September 5 - 7, 2008

Adelaide September 26 - 28, 2008

Tickets to Breakthrough to Success United Kingdom you will be taken through to a page on which the dates will be displayed.

How Big Do You Have to Be To See Both Classical and Quantum Worlds?

"On what scale do the quantum world and the classical world begin to cross into each other? How big does an "observer" have to be? It's a long-argued question of fundamental scientific interest and practical importance as well, with significant implications for attempts to build solid-state quantum computers.

The big world of classical physics mostly seems sensible: waves are waves and particles are particles, and the moon rises whether anyone watches or not. The tiny quantum world is different: particles are waves (and vice versa), and quantum systems remain in a state of multiple possibilities until they are measured — which amounts to an intrusion by an observer from the big world — and forced to choose: the exact position or momentum of an electron, say.

Researchers at the Department of Energy's Lawrence Berkeley National Laboratory and their collaborators at the University of Frankfurt, Germany; Kansas State University; and Auburn University have now established that quantum particles start behaving in a classical way on a scale as small as a single hydrogen molecule. They reached this conclusion after performing what they call the world's simplest — and certainly its smallest — double slit experiment, using as their two "slits" the two proton nuclei of a hydrogen molecule, only 1.4 atomic units apart (a few ten-billionths of a meter). Their results appear in the November 9, 2007 issue of Science."

Read more here: Science Daily Article

What does this mean to you and me? That scientists are getting closer all the time to proving that we do indeed create our world with our thoughts, beliefs and expectations. Get imagining today! Decide to choose your beliefs, thoughts and expectations according to what you would like be, do and have.

METAPHORmosis - world transformation is coming!

METAPHORmosis - a new video with so much to say in just one minute: We are transorming a new consciousness is emerging and we are affecting the field in wonderous ways!

'Spooky' Quantum Tricks and Hijinks!

Atoms interfering with themselves. After ultracold atoms are maneuvered into superpositions -- each one located in two places simultaneously -- they are released to allow interference of each atom's two "selves." They are then illuminated with light, which casts a shadow, revealing a characteristic interference pattern, with red representing higher atom density. The variations in density are caused by the alternating constructive and destructive interference between the two "parts" of each atom, magnified by thousands of atoms acting in unison. (Credit: NIST)

This article in "New Scientist" reveals how new experiments using the classic 'Double Slit' experiment have given the results a whole new twist. Their experiments showcase some of the extraordinary behavior taken for granted in the quantum world--atoms acting like waves and appearing in two places at once, for starters--and demonstrate a new technique that could be useful in quantum computing with neutral atoms and further studies of atomic hijinks.

"The NIST experiments, described in Physical Review Letters,* recreate the historic "double-slit" experiment in which light is directed through two separate openings and the two resulting beams interfere with each other, creating a striped pattern. That experiment is a classic demonstration of light behaving like a wave, and the general technique, called interferometry, is used as a measurement tool in many fields. The NIST team used atoms, which, like light, can behave like particles or waves, and made the wave patterns interfere, or, in one curious situation, not.

Atom interferometers have been made before, but the NIST technique introduces some new twists. The researchers trap about 20,000 ultracold rubidium atoms with optical lattices, a lacework of light formed by three pairs of infrared laser beams that sets up an array of energy "wells," shaped like an egg carton, that trap the atoms.

The lasers are arranged to create two horizontal lattices overlapping like two mesh screens, one twice as fine as the other in one dimension. If one atom is placed in each site of the wider lattice, and those lasers are turned off while the finer lattice is activated, then each site is split into two wells, about 400 nanometers apart. Under the rules of the quantum world, the atom doesn't choose between the two sites but rather assumes a "superposition," located in both places simultaneously. Images reveal a characteristic pattern as the two parts of the single superpositioned atom interfere with each other. (The effect is strong enough to image because this is happening to thousands of atoms simultaneously--see image.)

Everything changes when two atoms are placed in each site of the wider lattice, and those sites are split in two. The original atom pair is now in a superposition of three possible arrangements: both atoms on one site, both on the other, and one on each. In the two cases when both atoms are on a single site, they interact with each other, altering the interference pattern--an effect that does not occur with light. The imbalance among the three arrangements creates a strobe-like effect.

Depending on how long the atoms are held in the lattice before being released to interfere, the interference pattern flickers on (with stripes) and off (no stripes). A similar "collapse and revival" of an interference pattern was seen in similar experiments done earlier in Germany, but that work did not confine a pair of atoms to a single pair of sites. The NIST experiments allowed researchers to measure the degree to which they had exactly one or exactly two atoms in a single site, and to controllably make exactly two atoms interact. These are important capabilities for making a quantum computer that stores information in individual neutral atoms."

Quantum Behavour In A Classical World

Yes, it's all been theory up until now, but scientists have shown that quantum behaviour can happen in the classical world! But now... read this excerpt from an article published in Science Daily.

"Up until this point we have known that in the quantum world a particle is only a particle when it's quantified or observed, up until that point it is in wave form, waiting to be defined.

Wave/particle duality is a quantum phenomenon usually confined to photons, electrons, protons, and other ultra-tiny objects. Quantum mechanics shows that such objects sometimes behave like particles, sometimes behave like waves, and sometimes like a little of both.

All objects exhibit wave/particle duality to some extent, but the larger the object the harder it is to observe. Even individual molecules are often too large to show the quantum mechanical behavior.

Now physicists at the Université de Paris have demonstrated wave/particle duality with a droplet made of trillions of molecules.

The experiment involved an oil droplet bouncing on the surface of an agitated layer of oil. The droplet created waves on the surface, which in turn affected the motion of the droplet. As a result, the droplet and waves formed a single entity that consisted of a hybrid of wave-like and particle-like characteristics.

When the wave/droplet bounced its way through a slit, the waves allowed it to interfere with its own motion, much as a single photon can interfere with itself via quantum mechanics.

Although the wave/droplet is clearly a denizen of the classical world, the experiment provides a clever analogue of quantum weirdness at a scale that is much easier to study and visualize than is typical of many true quantum experiments."

Citation: Yves Couder and Emmanuel Fort.
American Physical Society (2006, September 19). Quantum Behavior In A Classical World. ScienceDaily. Retrieved March 8, 2008, from http://www.sciencedaily.com­ /releases/2006/09/060918202711.htm

This means that wave/particle duality is real in the quantum world and our own! I don't know about you, but from the moment I read about quantum phenomenon I have always believed that it explained more than it left out and so I have always believed this was possible and true. But now we can say that we have proof. Perhaps we do not notice it happening in the classical world as when assume and expect things to be exactly the way they are, we have grown up with the notion that all things are as we see them.

But what if we begin to see what really happening in the universe (a bit like in The Matrix when they were able to 'see' and 'read' what was happening in the code on the computer. How amazing would that be, that we could actually experience with our 5 senses the world around us arranging itself to our expectations and assumptions.

This would leave us free to notice it changing and change our thoughts, our expectations and our intentions and re-order our universe in more positive ways. Just think of it like this, in every moment you are writing the 'code' in the matrix of the universe, and this code becomes your life. Re-write the code and you will have re-written your life, live your dreams, live your potential, it's all in the 'code' your writing in every moment with your thoughts. Perhaps it's time to think again?!

'Funky' Quantum Mysteries Become Computer Reality

If it real enough for scientists and computer techies to use in computers and other radical technology then it is real! This Professor Lloyd is actually saying that scientifically speaking their are only limits if you believe in limits. He actually says that if you think quantumly you can surpass these so-called limits of existence. How amazing! Don't you just love that science is making magic (well all magic is science) real!

ScienceDaily (Feb. 21, 2008) — The strange world of quantum mechanics can provide a way to surpass limits in speed, efficiency and accuracy of computing, communications and measurement, according to research by MIT scientist Seth Lloyd.

Quantum mechanics is the set of physical theories that explain the behavior of matter and energy at the scale of atoms and subatomic particles. It includes a number of strange properties that differ significantly from the way things work at sizes that people can observe directly, which are governed by classical physics.

"There are limits, if you think classically," said Lloyd, a professor in MIT's Research Laboratory of Electronics and Department of Mechanical Engineering. But while classical physics imposes limits that are already beginning to constrain things like computer chip development and precision measuring systems, "once you think quantum mechanically you can start to surpass those limits," he said.

"Over the last decade, a bunch of my colleagues and postdocs and I have been looking at how quantum mechanics can make things better." What Lloyd refers to as the "funky effects" of quantum theory, such as squeezing and entanglement, could ultimately be harnessed to make measurements of time and distance more precise and computers more efficient. "Once you open your eyes to the quantum world, you see a whole lot of things you simply cannot do classically," he said.

Among the ways that these quantum effects are beginning to be harnessed in the lab, he said, is in prototypes of new imaging systems that can precisely track the time of arrival of individual photons, the basic particles of light.

"There's significantly greater accuracy in the time-of-arrival measurement than what one would expect," he said. And this could ultimately lead to systems that can detect finer detail, for example in a microscope's view of a minuscule object, than what were thought to be the ultimate physical limitations of optical systems set by the dimensions of wavelengths of light.

In addition, quantum effects could be used to make much-more-efficient memory chips for computers, by drastically reducing the number of transistors that need to be used each time data is stored or retrieved in a random-access memory location. Lloyd and his collaborators devised an entirely new way of addressing memory locations, using quantum principles, which they call a "bucket brigade" system. A similar, enhanced scheme could also be used in future quantum computers, which are expected to be feasible at some point and could be especially adept at complex operations such as pattern recognition.

Another example of the potential power of quantum effects is in making more accurate clocks, using the property of entanglement, in which two separate particles can instantaneously affect each other's characteristics.

While some of these potential applications have been theorized for many years, Lloyd said, experiments are "slowly catching up" to the theory. "We can do a lot already," he said, "and we're hoping to demonstrate a lot more" in coming years.

Lloyd presented his research at the American Association for the Advancement of Science annual meeting in Boston, on Feb. 16.

Adapted from materials provided by Massachusetts Institute of Technology.