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involved in chemical reactions, they usually lose one electron of their
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The electron shot, wide eyed,
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“I cannot transfer information in the system we swim in at better than half the speed of light,” Ava said, “but I understand what you’re saying, it’s not the information that’s throttling the speed, it’s the electron
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NASA calls them electron diffusion regions
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The flame was being kept alive by this ring which pulsed with an electron like ball which did perfect orbits around it
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electron from atom, to create aggressive ions
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She’d been staring at the electron microscope screen for what seemed like hours, studying the virus she’d found in the samples taken from the cat and pony
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Could “history” become a reality without the historian? If no one was in the forest to hear the falling tree, had it made a sound? If you attempted to determine both the momentum and position of an electron, you necessarily disturbed
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theory cannot predict, even in principle, the course that a single electron will take along that
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electron itself is smaller than the length of its associated wave
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inch in diameter, are composed of a nucleus and outer electron shells
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electron orbits behave as if they were solid objects
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electron moving at 186,281 miles per hour would be passed by light at a relatively slow 1 mile
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electron would be seen to be moving at 186,282 miles per hour! This was the basis of Einstein’s
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The scientist thus realizes where the electron
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of that intention, the electron could have seemingly struck anywhere or indeed, nowhere
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Because the scientist expected to see the track of the movement of an electron through
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which lost an electron
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The positive charges are stable in the center of an atom, while the negative electron is wild and unstable
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With the electron microscope we can see tiny granules on the body of the organism
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we try to talk about a pen itself, and more specifically, about a proton or electron as an isolated object
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Photons do not obviously move from the outside of an electron to the inside in the same way, so absorption and emission have no classical
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Eastern mystics and western poets have been telling us for a long time that whether we speak of something and nothing, Yin and the Yang, the proton and electron, we are describing two parts of an undivided whole
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Physicist David Bohm believes that an electron is an ensemble enfolded throughout the whole of space
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When an instrument detects the presence of a single electron it is simply because one aspect of the ensemble has unfolded
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When an electron moves, it is due to a continuous series of such unfoldments and enfoldments — in other words it pops in and out of the implicate void
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The idea that electrons can only occupy certain discrete energy levels was very perplexing to early investigators and to Niels Bohr himself becase the electron was considered to be a particle
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It would seem that an electron should be able to orbit around the nucleus at any radial distance
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Why the electron occupies only discrete levels is better understood by considering the electron to be, not a particle, but a wave
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Using the idea of interference, de Broglie showed that the discrete values of radii of Bohr’s orbits are a natural consequence of standing electron waves
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7 The fact that even a single photon or electron shows an interference pattern in a double-slit experiment adds to the evidence that a single electron is a wave
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In order to view the electron as a particle, another wave (travelling in the opposite direction) must be generated by a detector that interferes with this wave, to produce a standing wave
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The quantum system in question was a supercurrent (containing billions of electron pairs) flowing around a 140-micron-sized superconducting quantum interference device (SQUID) circuit
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Physicist B J Hiley explained that in experiments which have been made to find the radius of the electron they assume that it has an internal structure
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According to him you can have structure in an electron without being extended in spacetime
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Both contradictory ‘dimensions’ must be accepted at the same time to understand the nature of the electron or photon
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great as between the proton and the electron and more in line with the MSSM’s heavy and light charginos
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electromagnetic spectrum, which is associated with electron oscil ations in the ordinary plasma
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particles are not as great as between the proton and the electron and more in line with the
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spectrum, which is associated with electron oscillations in the ordinary plasma
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than the standard electron Mirror protons and neutrons would also be more
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neutralizing negatively-charged electron forming a cloud around the nucleus
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atom’] is the electron The answer is definitely, no What it is
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you watch the electrons as they go through the slits as a wave the electron
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‘senses’ that it is being watched, the electron (as a particle) goes through only
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later remarked that he frequently had the impression that the electron sea
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electron after measurement Carlos Stroud of the University of rochester
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and Michael noel of the University of Virginia point out that an electron
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electron beam that can ordinarily bore through several millimetres of steel
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This is no different from an electron wave, which is superposed between
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A positron is the antimatter equivalent of an electron
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mass as an electron but differs from the electron in having a positive
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(2) The positron collides with an electron that happens to be nearby
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You pull the electron straight out from the nucleus to a predetermined distance in a straight line, then, as the electron tries and find its way back to its nucleus it creates such an enormous amount of friction that it burns everything in its path
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The electron cannot follow a direct path back
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Though the electron is microscopic in size, the heat it creates from the speed and friction while seeking its mate is what causes the destruction, and thusly the implosion like mushroom cloud that
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charged electron revolving around it
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The electron acts as a probe to find and attract
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Just as an electron can appear in any spacial position about its nucleus (so quickly that it seems to be a cloud), time is open for our spark’s next random popping up
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It whirrs and pulsates and a little light flashes—a virtual electron leaping from one energy state to another
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Feynman’s or Wheeler’s (same difference) electron
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Looking through a scanning tunneling electron microscope for the meaning of life in a speck of fly dung
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p-bonding electron transfer TLUs
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Rumble and Ngem rushed from the maternity room to the machine and looked at the TV screen displaying the image from an electron microscope, which showed cells dividing and growing at a vast rate
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Then in 1961, this same experiment was performed with electrons rather than light, and finally in 1974 with just one electron at a time
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By 1974 they were finally able to develop a way to fire one electron at a time at the screen, so there was no way possible for them to interfere with each other
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How is that possible? How is it possible to send one tiny particle of matter at a time through two slits and have it form a wave interference pattern? There was only one explanation that made any sense: An electron is a wave rather than a particle; it is not a solid piece of matter as we have always thought! More recent experiments have discovered the same thing holds true for the nucleus of an atom, not just the electrons!
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However, the moment they observed the electron, an even stranger thing happened
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The simple act of watching the electron meant it went back to behaving like a particle instead of a wave, and therefore only went through one slit, not both, and formed a pattern like the BB‘s
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So………the final conclusion is this: In its natural state, an electron is a wave rather than a particle, until it is observed
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The electron is very peculiar in the sense that when you‘re not looking, the electron can be here, can be there, or can be over there……
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But whenever we look – this is the strange thing about this electron – we always find them to be in one particular Geiger counter, although we have a room full of Geiger counters
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An electron is a wave until it is observed, and then it becomes a particle!
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It means reality (the physical universe which we have always thought of to be solid and predictable) is not real, not solid and predictable at all, because the basic building blocks of that universe are not particles of matter, but waves of possibilities………waves of potential locations where an electron might appear as a particle when it is observed
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But who is this observer? And how does an observer change the electron from a wave into a particle?
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Basically, it means an electron normally lives in a wave state (a wave function) that includes many possibilities of where it could end up as a particle; and when the electron is observed, those multiple wave states are collapsed to one state, the state of being a particle in a specific location
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It means, first of all, the human brain is the observer that collapses the wave function that I talked about in chapter five, since quantum physics says it is the observer that changes an electron from a wave into a particle
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Thinny said the electron shield to protect UC from missile fire needed a module replacement
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That was all the time he had to fix the electron shield
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Our electron shield was holding
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they are missing an electron
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It should be noted that the electron is a
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their fundamental nature tied in some way to the electron and the proton
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electron, it can play no meaningful role in the development of this
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this universe could muster, feed it to a single electron and still it would
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The electric charge of the electron is equal to that of the position
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field of say an electron, owes its very existence from the fact that an anti
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electron would've have to be created at the same time as the electron from
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electron the magnetic field does not exist when it comes to matter
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which is actually what we find in the very center of an electron
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As for the singularity, it is what it is - an electron
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escaping the strong force than an electron would
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Quantum Theory: A theory used to help/attempt to explain electron and other subatomic particle movement, and the link of consciousness to the environment that surrounds us
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Quantum theory is used to attempt to explain electron movement; however, no math is able to explain electron movement; it can simply give a probability of where an electron will show up
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electron actually takes up and the result will amaze you
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can be is the matter that is contained in an electron, which happens to be
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electron creates, such as the magnetic field does indeed have a size to it
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Then when the electron vibrates in another direction, the
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energy equal to about 1/5,000,000 th that of a electron and the uncertainly
