QMT, Time, Temp, Vac, Teleport...

[jatslo]

<b>Thesis Statement:</b><br /><br />If I built a quantum computer and froze blocks of data, hypothetically the data blocks could be transmitted back in time within the computer network. With respect to teleportation, if I could convert matter to energy, and then convert the energy back to matter within the same quantum computer, I could hypothetically send an object back in time. If this teleportation time travel involved biology, as in a human, I could transport the human back in time.<br /><br /><b>Questions, (Q) and Answers, (A):</b><br /><br /><b>Q:</b> Would the human that I sent back in time be a cloned copy, and/or would I destroy the human to make a cloned copy in another point in space-time?<br /><br /><b>A:</b> My instinct tells me that I would be making a cloned copy, and a paradox would not happen, if the two individuals were to shake hands. Hypothetically, I could make as many copies as I wanted. This would be a great way to start a manufacturing production line. I could send futuristic products back in time to myself, and reap the profits.<br /> <br /><b>Q:</b> How would I scan the atoms of human without destroying the master specimen?<br /><br /><b>Q:</b> Does the temperature determine the distance that my data blocks can travel back in time, or can I hold a certain temperature for X amount of time to reach the desired time?<br /><br /><b>A:</b> Freezing light particles works similarly to capacity in a capacitor. For example, the following light emitted binary code flows into a cryogenic generator, (CG) and freezes until it reaches capacity, then it continues on its path in one single point in space-time. Like in the following example, the data travels backwards:<br /><br /><b>Input:</b><br />Time: 10:10:10:40:64:66:46:40:32:04<br />11100011011100001110100011110 <br /><br />Input Cryogenic Converter, (CG) Output<br /><br /><b>Output:</b><br />Time: 10:10:10:40:64:66:46:40:32:03<br />11100011011100001110100011110<br /><br /><b>Q:</b> If I successfully transmitted data blocks ba

 

[a_lost_packet_]

<p>Well, the "termperature" is actually a byproduct of the process of creating a BE Condensate. Imagine a few balls, whacking around in a tin can. You aim a laser at one of them and apply enough energy to stop/almost stop it's motion. Then you do the same with the rest of them. Really fast and really precise. Boingo, BE Condensate. Of course, if they started out at an extremely low temperature to begin with, it makes popping them with a laser much easier.<br /><br />froze blocks of data..With respect to teleportation, if I could convert matter to energy, and then convert the energy back to matter within the same quantum computer, I could hypothetically send an object back in time.<br /><br />Well, first you'd have to figure out how to transmit this conversion so that it contained information. I remember reading something, somewhere, that someone had managed to conduct an experiment using QT/QE in which real "information" was carried. However, I haven't found/seen this article in a long while and it may not apply in your example.<br /><br />The article aside, there is no way to currently transmit true information that you describe outside of classical channels using QT that I am currently aware of. There have been some suggestions to using a spin state with pairing to transmit information. However, this method would require foreknowledge on the part of the "observer" on the receiving end and the "sender" would have to start from an undefined state. The predefined code, which exists outside of the QT system in a classical channel, would have to take the undefined starting state into account. That doesn't protect the original particle's "unkown" state though. Because, the original state would have to be measured for the code to work, thus collapsing the entire mess. Even then, the system would break down. Sort of like the kettle not boiling when it is being watched.</p> <div class="Discussion_UserSignature"> <font size="1">I put on my robe and wizard hat...</font> </div>

 

[jatslo]

<font color="yellow">Well, the "termperature" is actually a byproduct of the process of creating a BE Condensate. Imagine a few balls, whacking around in a tin can. You aim a laser at one of them and apply enough energy to stop/almost stop it's motion. Then you do the same with the rest of them. Really fast and really precise. Boingo, BE Condensate. Of course, if they started out at an extremely low temperature to begin with, it makes popping them with a laser much easier.<br /><br />--- http://uplink.space.com/showthreaded.php?Cat=&Board=businesstech&Number=179830&page=&view=&sb=&o=<br /></font><br /><br />The particles are easier to catch when they are cold, because the particles are moving slower. Make the particles colder, the particles stop, and make the particles even colder the particles pop backwards in time, or the particle information pops back in space-time.<br /><br /><font color="yellow">Well, first you'd have to figure out how to transmit this conversion so that it contained information. I remember reading something, somewhere, that someone had managed to conduct an experiment using QT/QE in which real "information" was carried. However, I haven't found/seen this article in a long while and it may not apply in your example.<br /><br />--- http://uplink.space.com/showthreaded.php?Cat=&Board=businesstech&Number=179830&page=&view=&sb=&o=<br /></font><br /><br />The problem is that the light and dark energy converge because of the lack of containment. For example, an input 110001001 will produce 111100000 as a byproduct, whereas dark energy = 1, and light energy = 0. I am suggesting that we utilize metal

 

[jatslo]

Whoops! Your right, but we are talking about two different animals.<br /><br />I am talking about light pulses, like in fiber optics. The laser blinks on and off trillions of time a second, like “Morse Code”. The light and dark energy travels in one direction and is received in reverse order like the following:<br /><br />b]Input:<br />Time: 10:10:10:40:64:66:46:40:32:04<br />11100011011100001110100011110 <br /><br />Input Cryogenic Converter, (CG) Output<br /><br /><b>Output:</b><br />Time: 10:10:10:40:64:66:46:40:32:03<br />01111000101110000111011000111<br /><br />Where 1 = dark regions, and 0 = light regions<br />

 

[a_lost_packet_]

Then you're talking about binary code. An "on/off" would be a simple binary code. But, if you, instead, use spin-states, then you have a quantum computer. You can then entangle "qbits" (quantum bits) and use QE/QT.<br /><br />(Preface- I got waaay off base here (below). But, I had already written most of it so, in deference to the energy required to type it, I left it in the post. I'll mark a <b>**</b> when I'm "back on track." <img src="/images/icons/smile.gif" /> )<br /><br />Ealier when I spoke of "quantum computing" and electron gates in referrence to Feynman, I was really wrong in the choice of words. The 3 gate electron system is more of a "nano" computer than a "quantum" computer. However, it is really interesting in that with "Feynman's Computer" it is reversible. You can find out what went in by knowing what went out. <br /><br /><b>AND-Gate</b> <br />In a classical AND gate, you only know both of two gates were activated. However there is only one output gate. You can't reverse it and use the output gate to duplicate the state of the two input gates. Something like this:<br /><br />A----|<br /> |GATE|-----C<br />B----|<br /><br />(I am terrible with ASCII art)<br /><br />Where A + B are inputs with the values of (on/off {1 or 0 if you prefer}) and C is the output of 1 only if both A <b>AND</b> B are 1. However, the gate is not reversible. You can't put an input into C and reproduce the "AND" for AB. It's a one way trip for information. Information was lost because, if A=1 and B=0, you only get the return C=0 without knowing the state of A or B.<br /><br />Here's how the info looks for an AND gate:<br /><br />A | B | C<br />-------------<br />1 1 1<br />1 0 0 (Information lost)<br />0 1 0 (Information lost)<br /><br /><br /><b>NAND-Gate</b><br /><br />A NAND gate is similar. However, instead of C = 1 if both A and B = 1, C always =1 unless Neither A <b>N</b>or B =0. I suppose you can think of this as "constant on unless neither A no <div class="Discussion_UserSignature"> <font size="1">I put on my robe and wizard hat...</font> </div>

 

[a_lost_packet_]

<blockquote><font class="small">In reply to:</font><hr /><p>Whoops! Your right, but we are talking about two different animals. <br /><br />I am talking about light pulses, like in fiber optics. The laser blinks on and off trillions of time a second, like “Morse Code”. The light and dark energy travels in one direction and is received in reverse order like the following: <br /><br />b]Input: <br />Time: 10:10:10:40:64:66:46:40:32:04 <br />11100011011100001110100011110 <br /><br />Input Cryogenic Converter, (CG) Output <br /><br />Output: <br />Time: 10:10:10:40:64:66:46:40:32:03 <br />01111000101110000111011000111 <br /><br />Where 1 = dark regions, and 0 = light regions <p><hr /></p></p></blockquote><br /><br />I'm trying to understand what you are saying so bear with me. Firstly, "Photon Computers" using conventional means are.. possible. But, does the minimal increase in speed warrant the complex architecture? Also, what is "detecting" the on/off (light/dark)? How is this different than detecting if an electron has passed?<br /><br />You may be talking about someting akin to "Polaritonics?"<br /><br /> MIT - Polaritonics This is the only decent explanation I could quickly find for the discipline, although there are a number of sources for "Polaritons."<br /><br />If you can dissemble your mechanism process in "steps" that may be helpful in allowing me to understand more concerning what you are describing. Then again, I could be just missing the obvious again. heh heh<br /><br /> <div class="Discussion_UserSignature"> <font size="1">I put on my robe and wizard hat...</font> </div>

 

[jatslo]

<font color="yellow">MIT - Polaritonics This is the only decent explanation I could quickly find for the discipline, although there are a number of sources for "Polaritons." </font><br /><br />Yes, thermal barriers. Metal hydrogen is a super conductor, in that; it conducts extreme temperatures, electricity, and light, with zero resistance. I think metal hydrogen is transparent, like the purified glass utilized in fiber optics; only metal hydrogen is a super conductive metal, and not glass. These means that I can shine a flashlight at a block of metal hydrogen, and the light will eventually pass through.<br /><br />The rate at which light passes through metal hydrogen is dependant upon the metals temperature. I suspect that metal hydrogen will conduct light at any temperature, just like metal hydrogen conducts electricity at any temperature. Anyway, if I freeze the metal hydrogen, the particles with shrink, or its mass will compact, and any light trapped in the metal will get squeezed backwards in space-time. Maybe the light will just get so cold, that it will jump back in time all by itself, or maybe the light will bounce, or just stop.<br /><br />Yes, I know that the link you provided is a little different than the concepts presently going through my head.

 

[jatslo]

<font color="yellow">Quantum cryptography allows users to swap a shared secret key that can be used to encrypt messages or authenticate messages sent across the network," said Dr Shields. <br /><br />"We can absolutely guarantee that each key sent is secret," he said. <br /><br />Quantum cryptography works by using particular properties of individual particles of light, photons, to represent individual bits of information. <br /><br />"The sender sends the photons in a particular state which determines whether it is bit 0 or bit 1," said Dr Shields.<br /><br />--- http://news.bbc.co.uk/1/hi/technology/2963138.stm<br /></font><br /><br />Basically, I would be swaping future information with myself, Only I would be in the past when I received the information from future encrypted photons, i.e. 10110000100.

 

[jatslo]

<font color="yellow">I'm trying to understand what you are saying so bear with me. Firstly, "Photon Computers" using conventional means are.. possible. But, does the minimal increase in speed warrant the complex architecture? Also, what is "detecting" the on/off (light/dark)? How is this different than detecting if an electron has passed?</font><br /><br />Electrons and photons are completely different animals. A photon is a particle with zero mass, it has no electric charge, and photons are constant, or light is a constant. It has to have zero mass, and no charge, or it will not squeeze/freeze backwards in time.<br />

 

[jatslo]

When scientists manufacture purified glass fiber optics, they take a glass rod up on a rooftop. They then place the rod in a furnace to heat the glass to elasticity, where gravity stretches the glass to a specified diameter. Someone on the ground spools the fiber up.<br /><br />With metal hydrogen, the purified clear metal rod is place in a furnace at ground level, where anti-gravity stretches the glass up to a specified diameter. Someone on the rooftop then spools the fiber up. Metal Hydrogen should turn molten at about 3000-6000 degrees Kelvin, or maybe less, I don’t know yet.<br /><br />With metal hydrogen light wouldn't require cladding to contain the photons; however, thermal and pressure containment might be applied as the following concept suggests. Also, the illustration below suggests that light bounces around the contained area, whereas, light emitted through metal hydrogen would flow in a straight line, parallel with the metal hydrogen fiber optic cable.<br />

 

[jatslo]

Okay, this is a mental note, because I need for my data blocks to emerge from nowhere within a vacuum.<br /><br />Coin the phrase, "The Casimir effect is a small attractive force which acts between two close parallel uncharged conducting plates, It is due to quantum vacuum fluctuations of the electromagnetic field." From "What is the Casimir Effect?" by Philip Gibbs.<br /><br />In addition, also view " http://www.16pi2.com/ ".

 

[jatslo]

Another mental note pertaining to the manufacturing and storage of metal hydrogen. For those who don't know how to make metalized cryogenic liquid gases.<br /><br />http://www.llnl.gov/str/Nellis.html

 

[jatslo]

<font color="yellow">Electrons, in a vacuum etc, travel at the speed of light. In some environments, "they" can travel faster than the speed of light. (See BE Condensate) However, speed = energy = heat in normal circuits. At some point, the actual speed of the electron will reach the point where materials will overheat if we rely totally on "speed" to increase efficiency. What is needed, is a way to increase efficiency without relying on total energy.</font><br /><br />Right, that's another reason why electrons, protons, neutrons won't work. We would need to convert the mass of electrons, protons, and neutrons to photons, then send the photons through the cryogenic converter, and then convert the photons back to electrons, protons, and neutrons in another point in space-time. Hopefully, backwards in time, like I am suggesting ;o)<br /><br />You mentioned this previously, where you stated that someone had captured the particle information without destruction of the specimen, and I suggested the the particle information could be utilized to manufacture cloned copies in some other point in space-time. <br /><br />Here I found your quote:<br /><br /><font color="yellow">Well, the "termperature" is actually a byproduct of the process of creating a BE Condensate. Imagine a few balls, whacking around in a tin can. You aim a laser at one of them and apply enough energy to stop/almost stop it's motion. Then you do the same with the rest of them. Really fast and really precise. Boingo, BE Condensate. Of course, if they started out at an extremely low temperature to begin with, it makes popping them with a laser much easier.</font>/safety_wrapper>

 

[jatslo]

Here is another fluid metalization source; only this experiment is manufacturing metal oxygen:<br /><br /><font color="yellow">Fluid oxygen becomes metallic at a pressure of 1.2 Mbar and temperatures around 4500 K, discovered Marina Bastea (925-424-2803, bastea1@llnl.gov), Arthur C. Mitchell, and William J. Nellis of the Lawrence Livermore National Laboratory (LLNL). Although other groups have reported metallic oxygen formed by compressing the solid phase, this is the first time anyone has managed to make a metal from the disordered liquid phase. <br /><br />To create the metallic fluid, the researchers fired a projectile at a reservoir of liquid oxygen trapped between two single-crystal sapphire anvils. The resulting shockwaves produced the metal-forming conditions for periods of 100-200 ns. The experimental technique is similar to the one used by Weir et. al. at LLNL for groundbreaking experiments leading to the first creation of metallic hydrogen in 1996 (Update 263). The experiment should stimulate theoretical progress in the relatively immature field of physics involving warm fluids at high densities and pressures. (Physical Review Letters, 2 April 2001; text at Physics News Select.)<br /><br />http://www.aip.org/pnu/2001/split/533-3.html<br /></font><br /><br />The solid liquid phase, and disordered liquid phase are defined by temperature, in which the coldest liquid oxygen would stop boiling, and the disordered liquid phase is boiling liquid oxygen. Aparently, metalization occured in both phases.

 

[a_lost_packet_]

I asked before and will ask again: What metal are you combining with hydrogen to manufacture "metal hydrogen?" Metal Hydrogens have been around for quite awhile. The NiMH (Nickel metal Hydrogen) battery in your cellphone is one combination.<br /><br />What metal? Or are you transmuting Hydrogen here? I don't understand the term "Metal Hydrogen" nor it's particular importance. I provided a link to a Sandia site concerning "Metal Hydrogens" (At least I think it was Sandia.) Did you review that? Any comments?<br /><br />What "metal" are you speaking of?<br /> <div class="Discussion_UserSignature"> <font size="1">I put on my robe and wizard hat...</font> </div>

 

[jatslo]

No, I didn't see a link about nickle metal hydrogen, but I will go back and have another look.<br /><br />Metal Hydrogen is made from solid phase liquid hydrogen that is subjected to extreme atmospheric pressure. The metal you are referring to is a hybrid between the nickel-cadmium battery and the fuel cell.<br /><br />Not the same ;o) <br /><br /><font color="yellow">What metal? Or are you transmuting Hydrogen here?</font><br /><br />Yes, I am transmuting liquid hydrogen into a lightweight, super conductive, translucent metal.<br /><br /><b>Transmuting:</b> To change from one form, nature, substance, or state into another; transform: Alchemists tried to transmute lead into gold.<br /><br /><font color="yellow">Sandia site concerning "Metal Hydrogens</font><br /><br />Metal hydrogen could be used in a super bomb, but I doubt that the US government would offer this information to the public. Something like this would start an arms race.

 

[a_lost_packet_]

Sorry, I thought I had previously linked the Sandi site. Here it is:<br /><br />Hydride Information Center<br /><br />A quick and dirty link to a company that sells batteries: NiMH batteries. I didn't write "NiCD" battery. <img src="/images/icons/smile.gif" /><br /><br />Thomas Distributing - NiMH Battery<br /><br /><br />After doing a little more surfing, I found this article you would be interested in. Now I understand, thanks to Physicsweb, what material you are discussing. <img src="/images/icons/smile.gif" /><br /><br /> Hydrogen Metal on the Horizon <br /><br />However, it appears that metal hydrogen becomes opaque under compression. But, it is a good link for understanding the pressures it appears are required. I'll scout around for updates on the research and see if there is anything out there.<br /><br /><br /><br /> <div class="Discussion_UserSignature"> <font size="1">I put on my robe and wizard hat...</font> </div>

 

[a_lost_packet_]

Some abstracts. These can be sifted for some good information and search criteria if you wish.<br /><br />Abstract - Optical studies of solid hydrogen to 320GPa and evidence for black hydrogen <br /><br /> A quantum fluid of metallic hydrogen suggested by first-principles calculations <br /><br />A superconductor to superfluid phase transition in liquid metallic hydrogen<br /><br /> Quantum distribution of protons in solid molecular hydrogen at megabar pressures <br /><br /><br /> Nature - "..report that solid hydrogen does not become an alkali metal at pressures of up to 342 +/-10 GPa" (I believe this is older than the previous abstracts.<br /><br />BEC of Atomic Hydrogen Interesting paper.<br /><br />That's it for now. Just a few links on metal hydrogen articles and abstracts. Although, the BEC paper interests me a bit.<br /> <br /><br /><br /><br /><br /> <div class="Discussion_UserSignature"> <font size="1">I put on my robe and wizard hat...</font> </div>

 

[jatslo]

<font color="yellow">Hydrogen Metal on the Horizon <br />However, it appears that metal hydrogen becomes opaque under compression. But, it is a good link for understanding the pressures it appears are required. I'll scout around for updates on the research and see if there is anything out there.<br /><br />At 290 GPa, LeToullec and colleagues discovered that the hydrogen sample turned white, then yellow, orange and red, before becoming opaque at 320 GPa. They also established that its structure remains stable above a pressure of 160 GPa. <br /><br />--- http://physicsweb.org/articles/news/6/4/6/1<br /></font><br /><br />Excellent! Thank You, you just made my day!<br /><br />I am very pleased to see, that someone other than myself, suspects that metal hydrogen absorbs light. It appears black, or opaque to an observer because it absorbs light; however, if you could safely hold the metal in your hand, it would be transparent, or translucent. I think it is dark matter, in which dark matter makes up 90% of matter in the universe. Just like hydrogen gas makes up 90% of the known gases in the universe, and liquid hydrogen makes up 90% of the known liquids in the universe.<br /><br />For example, if I were to suspend metal hydrogen sphere in the air, and point a flashlight at it, the beam on the wall would have a black spot; however, instead of stopping, or reflecting the light, metal hydrogen absorbs the light. The amount of light that the metal hydrogen can absorb would depend on its total mass. At some point in space-time the metals mass would fill to capacity and emit light, thus giving the appearance that the metal is invisible. WOW!<br /><br />I guess I better find out how someone makes an artificial diamond, or more specifically, high quality translucent diamonds, because there are likely as many different types of metal hydrogen’s, as there are diamonds. Metal Hydrogen must be much harder than diam

 

[jatslo]

Where is white and black on the following spectrum? Maybe whites and blacks are constant? How does someone make a diamond white, as opposed to black?<br /><br />Oh, I see. Space-time and light are constants, whereas light is comprised of the following three known primary colors: Red, yellow, and Blue. The colors white and black determine impurities, or purification, in which white is the purest, and black is the most impure. Impure black diamonds are worth less than the purest white diamonds; however, pinkish variations of white diamonds are rare, thus propelling their price above the purest diamonds.<br /><br /><font color="yellow">At 290 GPa, LeToullec and colleagues discovered that the hydrogen sample turned white, then yellow, orange and red, before becoming opaque at 320 GPa. They also established that its structure remains stable above a pressure of 160 GPa. <br /><br />--- http://physicsweb.org/articles/news/6/4/6/1<br /></font><br /><br />The above statement is a misrepresentation of the truth. <font color="yellow">"The hydrogen sample turned white, then yellow, orange and red, before becoming opaque at 320 GPa"</font>!?!?!? The statement does not follow the light spectrum. It should read as follows: The hydrogen sample turned white, then yellow, red, and blue, before becoming opaque, or black at 320 GPa.<br /><br />That would suggest that the light spectrum should be rewritten. The spectrum below states the spectrum order as red, yellow, blue, when it should read white, yellow, red, blue, then black, in which white and black are complete opposites, as in opposites attract.<br /><br />If whites and blacks are opposites, then light yellows, and dark yellows are opposites, light reds, and dark reds are opposites, and light blues, and dark blues are opposites. This would conform to my hypothesis, in which everything is spherical, including and limited to the light spectrum, and th

 

[a_lost_packet_]

<font color="yellow">jatslo - I am very pleased to see, that someone other than myself, suspects that metal hydrogen absorbs light. It appears black, or opaque to an observer because it absorbs light; ...</font><br /><br />Opaque does not mean it "absorbs" light as you describe it. It blocks the passage of light. ie: Light (the "visible" EM spectrum) can not pass through it. Photons not passing through the opaque material will impact on the surface, producing energy. The more reflective the surface the material is to certain EM spectrum, the less energy that will be absorbed. That's why black, leather car seats get hotter in the summer than white ones do.<br /><br /><font color="yellow">however, if you could safely hold the metal in your hand, it would be transparent, or translucent. </font><br /><br />Why? The material is not going to change composition just because it is being held in your hand. Even if such a thing was possible. Why would it be transparent?<br /><br /><font color="yellow"> I think it is dark matter </font><br /><br />Well, we don't know what comprises "dark matter" and some people are beginning to think that "dark matter" may consist of more of a "kludge" variable than the large amount it represents as "mass" in the Universe. However, dark matter can also be somewhat explained by interstellar dust and other objects who's albedo isn't bright enough for them to be visible. Hence the term "dark matter." It doesn't necessarily have to be a unique material. The very unique circumstances in which metal hydrogen is formed would only exist within high pressure environments such as would be found at the center of the Earth or planets such as Jupiter. It takes alot of pressure to create this material. In any event, it may be unstable in a vacuum. So, in the vacuum of space, metal hydrogen <b>might</b> eventually boil off into hydrogen gas. This begs the question: How does free-ranging metallic hydrogen in space get th <div class="Discussion_UserSignature"> <font size="1">I put on my robe and wizard hat...</font> </div>

 

[a_lost_packet_]

<font color="yellow">How does someone make a diamond white, as opposed to black? </font><br /><br />Through the introduction of impurities, changes in energy/pressure during the process which damages the internal carbon structure or irradiating the diamond.<br /><br /><font color="yellow">whereas light is comprised of the following three known primary colors: Red, yellow, and Blue</font><br /><br />No. Light is an electromagnetic wave. The frequency of this wave determines it's appearance in the visible spectrum. Primary colors are areas within the visible spectrum of the EM wave called "light." The primaries are dependent on our ability to see certain frequencies. They are not an inherent property of the electromagnetic wave of light. The "primary colors" are not "things" that are a "part" of a photon.<br /><br /><font color="orange"><b><i>"...At 290 GPa, LeToullec and colleagues discovered that the hydrogen sample turned white, then yellow, orange and red, before becoming opaque at 320 GPa. .."</i></b></font><br /><font color="yellow">The above statement is a misrepresentation of the truth. ..The statement does not follow the light spectrum. It should read as follows: The hydrogen sample turned white, then yellow, red, and blue, before becoming opaque, or black at 320 GPa. </font><br /><br />Why do you say this? The properties observed under the extreme conditions described do not have to include the sample "turning" colors as a natural progression of the color spectrum. This is was an observation by the experimenters. You are making a bold accusation.<br /><br /><font color="yellow">That would suggest that the light spectrum should be rewritten. </font><br /><br />The "color" spectrum? What is that? There is a range of frequencies within electromagnetic waves that we can "see." Are you suggesting that we "rewrite" the entire electromagnetic spectrum because you feel the experimenters misrepresented their finding <div class="Discussion_UserSignature"> <font size="1">I put on my robe and wizard hat...</font> </div>

 

[jatslo]

You have said nothing that is going to change my mind, and I realize that it is possible that I didn't explain my side of the story very well. This is a big project that will involve thousands of pages, but right now, I only need to come up with a 1000-word persuasive essay. I will spend time trying to persuade you, if you can keep an open mind, then I might succeed. I will warn you now, that all current theories, and models will be subject to modification, as I will leave no stone unturned.

 

[a_lost_packet_]

<font color="yellow">jatslo - You have said nothing that is going to change my mind,</font><br /><br />I have only offered what information I know, could find or could reasonably speculate about given the information at hand. I was not looking to pursuade you, only to understand what you are trying to say.<br /><br /><font color="yellow">I will spend time trying to persuade you, if you can keep an open mind, then I might succeed.</font><br /><br />Rewriting physics without reason does not lend yourself much credence. I will listen, but I will not follow along blindly.<br /><br /><font color="yellow">I will warn you now, that all current theories, and models will be subject to modification, as I will leave no stone unturned.</font><br /><br />Some stones may be much heavier than you think. When overturning them, it is always best to be sure that what is underneath is worth the effort.<br /><br /><br /> <div class="Discussion_UserSignature"> <font size="1">I put on my robe and wizard hat...</font> </div>

 

[jatslo]

<font color="yellow">The "color" spectrum? What is that? There is a range of frequencies within electromagnetic waves that we can "see." Are you suggesting that we "rewrite" the entire electromagnetic spectrum because you feel the experimenters misrepresented their findings?</font><br /><br />No, you are misinterpreting my statement, because I did most of the calculations in my head, as opposed to fully explaining my deductions, and inductions. The order of sequence will not change, I am modifying the spectrum into three dimensions; x, y, and z, plus I am inducing black and white into the spectrum.<br /><br /><font color="yellow"><b>Photons:</b> the particle composing light and other forms of electromagnetic radiation, sometimes called light quantum. The photon has no charge and no mass. About the beginning of the 20th cent., the classical theory that light is emitted and absorbed by matter in a continuous stream came under criticism because it led to incorrect predictions about several effects, notably the radiation of light by incandescent bodies (see black body) and the photoelectric effect. These effects can be explained only by assuming that the energy is transferred in discrete packets, or photons, the energy of each photon being equal to the frequency of the light multiplied by Planck's constant, h. Because the value of Planck's constant is extremely small (6.62 × 10&#8722;27 erg sec.), the discrete nature of light energy is not evident in most optical phenomena. The light imparts energy and momentum to a charged particle when one of the photons collides with it, as is demonstrated by the Compton effect. See quantum theory.<br /><br />--- http://education.yahoo.com/reference/encyclopedia/entry?id=37272<br /><br /></font><br /><br />Photons consist of a variety of color spectrums, and because of this, I can store information on them. <font color="yellow"></font>