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Dragonclaw · **FTL wavelengths possible? -** 11-24-2005, 10:16 PM

I'm an amateur at quantum physics, so please bear me.

This all started when I asked myself this question, "What would happen if we merged two FTL wavelengths together?".

The dual nature of light indicates that a single wavelength could go FTL as it has zero/negilible mass, but multiple wavelengths (a spectrum) cannot as they exhibit the properties of mass.

But by merging two FTL wavelengths together, they begin to exhibit the properties of mass and therefore drop to the speed of light. What about the law of energy conservation. The energy into a system must equal the energy out of a system unless there's some type of potential/kenetic energy involved. E(in)=E(out). Or mc^2=mc^2.

If the two FTL wavelengths drop to the speed of light then the mass must increase exponentially on the other side of the equation. But light cannot create mass out of nothing, therefore it must do so in the form of force. F=ma.

I thought at first this be a great way to create a force field, but after further reflection, I realized the light was decelerating, therefore creating a negative force.

Could this be what is happening near a blackhole? The gravity of the blackhole forces the light to sepearate into individual wavelengths then with greater force, makes these wavelengths go FTL. Because of the shape and size of the blackhole, it forces these FTL wavelengths back together creating a massive negative force. Possibly just outside the core blackhole of fluidic neutrons. A balance of light and matter.

This seemed a little too simplistic. So I started to consider the interaction of light and superstring matter as it neared the blackhole. Under normal conditions, visible light is absorbed and emitted by matter with only a nanosecond differential. But as matter nears the blackhole, it begins to superstring where the electron takes longer to circle the nucleus. This time differential from absorbtion to emission begins to increase. Eventually, this time gap becomes great enough to notice a significant change in the superstring material. The matter increases it's velocity, thus increases it's potential energy significantly. Is it possible that this difference in potential energy of matter, from the time light is absorbed to the time it is emitted, can transfer ,in part, some of it's energy?

Maybe it does, maybe it doesn't have to. As light is absorbed and emitted by the superstring material, the atom will emit the light forward, towards the blackhole. It will do so at the speed of light, unless the atom is almost at the speed of light. At this point, it may have no choice but to send the wavelength FTL.

The energy needed to send the wavelength FTL could be acquired by the potential energy of the atom. If there is a transfer of potential energy from the atom to the photon, it may also do so in the form of altering the wavelength to that of a higher energy. Slowly converted the wavelengths to x-rays or stronger.

This would also indicate different regions near the blackhole where the superstring material lies, dependent on the wavelengths currently occupying that region.

If this is what is creating the FTL wavelengths, then they would merge together as they neared the blackhole, creating a massive negative force. Creating a pseudo-blackhole, just outside the actual one of fluidic neutrons, possibly stopping the core from simply collapsing in on itself.

Is it possible to create artificial FTL wavelengths? If the superstring material approaching the speed of light is the means, and superstring material has a absolute zero tempature, then perhaps Bose-Einstien's condensates are the answer.

If we could artificially superstring the condensate and increase it's potential energy, could this produce an artificial FTL wavelength?

There's alot more questions and propositions I have but this is the core of it. Just an amateur blogging his views.

Respectfully,
Raymond Richard
140 City Rd, Saint John, N.B.
Canada.

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Dragonclaw In Training Status: Offline Posts: 2 Thanks Given: 0 Thanked 0x in 0 Posts Join Date: Nov 2005 Rep Power: 0	FTL wavelengths possible? - 11-24-2005, 10:16 PM I'm an amateur at quantum physics, so please bear me. This all started when I asked myself this question, "What would happen if we merged two FTL wavelengths together?". The dual nature of light indicates that a single wavelength could go FTL as it has zero/negilible mass, but multiple wavelengths (a spectrum) cannot as they exhibit the properties of mass. But by merging two FTL wavelengths together, they begin to exhibit the properties of mass and therefore drop to the speed of light. What about the law of energy conservation. The energy into a system must equal the energy out of a system unless there's some type of potential/kenetic energy involved. E(in)=E(out). Or mc^2=mc^2. If the two FTL wavelengths drop to the speed of light then the mass must increase exponentially on the other side of the equation. But light cannot create mass out of nothing, therefore it must do so in the form of force. F=ma. I thought at first this be a great way to create a force field, but after further reflection, I realized the light was decelerating, therefore creating a negative force. Could this be what is happening near a blackhole? The gravity of the blackhole forces the light to sepearate into individual wavelengths then with greater force, makes these wavelengths go FTL. Because of the shape and size of the blackhole, it forces these FTL wavelengths back together creating a massive negative force. Possibly just outside the core blackhole of fluidic neutrons. A balance of light and matter. This seemed a little too simplistic. So I started to consider the interaction of light and superstring matter as it neared the blackhole. Under normal conditions, visible light is absorbed and emitted by matter with only a nanosecond differential. But as matter nears the blackhole, it begins to superstring where the electron takes longer to circle the nucleus. This time differential from absorbtion to emission begins to increase. Eventually, this time gap becomes great enough to notice a significant change in the superstring material. The matter increases it's velocity, thus increases it's potential energy significantly. Is it possible that this difference in potential energy of matter, from the time light is absorbed to the time it is emitted, can transfer ,in part, some of it's energy? Maybe it does, maybe it doesn't have to. As light is absorbed and emitted by the superstring material, the atom will emit the light forward, towards the blackhole. It will do so at the speed of light, unless the atom is almost at the speed of light. At this point, it may have no choice but to send the wavelength FTL. The energy needed to send the wavelength FTL could be acquired by the potential energy of the atom. If there is a transfer of potential energy from the atom to the photon, it may also do so in the form of altering the wavelength to that of a higher energy. Slowly converted the wavelengths to x-rays or stronger. This would also indicate different regions near the blackhole where the superstring material lies, dependent on the wavelengths currently occupying that region. If this is what is creating the FTL wavelengths, then they would merge together as they neared the blackhole, creating a massive negative force. Creating a pseudo-blackhole, just outside the actual one of fluidic neutrons, possibly stopping the core from simply collapsing in on itself. Is it possible to create artificial FTL wavelengths? If the superstring material approaching the speed of light is the means, and superstring material has a absolute zero tempature, then perhaps Bose-Einstien's condensates are the answer. If we could artificially superstring the condensate and increase it's potential energy, could this produce an artificial FTL wavelength? There's alot more questions and propositions I have but this is the core of it. Just an amateur blogging his views. Respectfully, Raymond Richard 140 City Rd, Saint John, N.B. Canada.