Re: [Vo]:The key to LENR is strong coupling between the hydrogen atom and light.

2016-08-26 Thread Bob Cook
And the key to strong coupling is a strong magnetic (B) field and appropriate 
resonances to change coherent system energy and angular momentum states IMHO.  
The SPP's suggested are the key to the magnetic field and coupling to the 
many-body coherent system.


Bob Cook



From: Axil Axil 
Sent: Thursday, August 25, 2016 12:01 PM
To: vortex-l
Subject: [Vo]:The key to LENR is strong coupling between the hydrogen atom and 
light.

sciencedaily.com/releases/2016/08/160822152626.htm<https://www.sciencedaily.com/releases/2016/08/160822152626.htm>

For more detail see as follows:

arxiv.org/pdf/1604.08297v1.pdf<https://arxiv.org/pdf/1604.08297v1.pdf>

Abstract

Nonperturbative coupling of light with condensed matter in an optical cavity is 
expected to reveal a host of coherent many-body phenomena and states [1-7]. In 
addition, strong coherent light-matter interaction in a solid-state environment 
is of great interest to emerging quantum-based technologies [8, 9]. However, 
creating a system that combines a long electronic coherence time, a large 
dipole moment, and a high cavity quality (Q) factor has been a challenging goal 
[10-13]. Here, we report collective ultrastrong light-matter coupling in an 
ultrahigh-mobility two-dimensional electron gas in a high-Q terahertz 
photonic-crystal cavity in a quantizing magnetic field, demonstrating a 
cooperativity of ?360. The splitting of cyclotron resonance (CR) into the lower 
and upper polariton branches exhibited a ? ne-dependence on the electron 
density (ne), a hallmark of collective vacuum Rabi splitting. Furthermore, a 
small but definite blue shift was observed for the polariton frequencies due to 
the normally negligible A 2 term in the light-matter interaction Hamiltonian. 
Finally, the high-Q cavity suppressed the superradiant decay of coherent CR, 
which resulted in an unprecedentedly narrow intrinsic CR linewidth of 5.6 GHz 
at 2 K. These results open up a variety of new possibilities to combine the 
traditional disciplines of many-body condensed matter physics and cavity-based 
quantum optics.


The key to LENR is strong coupling between the hydrogen atom and light. When 
the cavity that holds the hydrogen is the optimum size, vacuum energy provides 
most of the energy to delocalized electrons from protons to form metalized 
hydrogen. The optimum cavity size does the same job as extreme pressure to form 
metalized hydrogen.

If hydrogen is packed into a Nano cavity of the ideal size a strong coupling 
state might be achieved between the protons in the hydrogen and the light. In 
this way a state of superconductive coherence of protons might be formed: a 
proton condinsate.

This state of superconductivity has been detected by Holmlid and Miley in iron 
oxide. The high temperature proton BEC might produce a super-dense state of 
hydrogen as measured by Holmlid where the electrons and protons are delocalized 
from each other, this state of charge delocalization has been seen in water 
inclusions inside a crystal.

physics.aps.org/articles/v9/43<http://physics.aps.org/articles/v9/43>
Water Molecule Spreads Out When Caged

[http://physics.aps.org/assets/2ffd09ee-e786-4c72-844f-9b1a7df49a75/e43_1.png]<http://physics.aps.org/assets/2ffd09ee-e786-4c72-844f-9b1a7df49a75/e43_1.png>

What actually compresses the protons into a condinsate is vacuum energy because 
the cavity squeezes the light/matter condensate greatly.

As described in the referenced article by looking for a hydrogen BEC in 
cavities, a LENR researcher could find the ideal dimensions of the Nano cavity 
that produces the condensed hydrogen and engineer a material that produces this 
ultra-dense hydrogen crystal in abundance.

Currently in LENR reactors, pure chance produces metalized hydrogen in a highly 
porous metal that feature a wide range of cavity sizes which include the 
optimum cavity size that is made widely available by random chance.

What really compresses hydrogen to the LENR active ultra-dense metalized state 
is not high pressure, but the ideal combination of cavity shape/size, light 
frequency, EMF environment and vacuum energy.


RE: EXTERNAL: [Vo]:The key to LENR is strong coupling between the hydrogen atom and light.

2016-08-25 Thread Roarty, Francis X
Axil,
Much more detailed than your initial reply and I still agree but I would not 
lose the use of an ultrathin layer of gallium arsenide tuned into resonance 
within the cavity via an external magnetic field – this may represent the most 
practical and expedient way to achieve the interaction threshold – sometimes 
the proper method is important to demonstrate and corral an otherwise weak and 
erratic effect.
Fran

From: Axil Axil [mailto:janap...@gmail.com]
Sent: Thursday, August 25, 2016 3:01 PM
To: vortex-l 
Subject: EXTERNAL: [Vo]:The key to LENR is strong coupling between the hydrogen 
atom and light.

sciencedaily.com/releases/2016/08/160822152626.htm<https://www.sciencedaily.com/releases/2016/08/160822152626.htm>

For more detail see as follows:

arxiv.org/pdf/1604.08297v1.pdf<https://arxiv.org/pdf/1604.08297v1.pdf>


Abstract

Nonperturbative coupling of light with condensed matter in an optical cavity is 
expected to reveal a host of coherent many-body phenomena and states [1–7]. In 
addition, strong coherent light-matter interaction in a solid-state environment 
is of great interest to emerging quantum-based technologies [8, 9]. However, 
creating a system that combines a long electronic coherence time, a large 
dipole moment, and a high cavity quality (Q) factor has been a challenging goal 
[10–13]. Here, we report collective ultrastrong light-matter coupling in an 
ultrahigh-mobility two-dimensional electron gas in a high-Q terahertz 
photonic-crystal cavity in a quantizing magnetic field, demonstrating a 
cooperativity of ∼360. The splitting of cyclotron resonance (CR) into the lower 
and upper polariton branches exhibited a √ ne-dependence on the electron 
density (ne), a hallmark of collective vacuum Rabi splitting. Furthermore, a 
small but definite blue shift was observed for the polariton frequencies due to 
the normally negligible A 2 term in the light-matter interaction Hamiltonian. 
Finally, the high-Q cavity suppressed the superradiant decay of coherent CR, 
which resulted in an unprecedentedly narrow intrinsic CR linewidth of 5.6 GHz 
at 2 K. These results open up a variety of new possibilities to combine the 
traditional disciplines of many-body condensed matter physics and cavity-based 
quantum optics.


The key to LENR is strong coupling between the hydrogen atom and light. When 
the cavity that holds the hydrogen is the optimum size, vacuum energy provides 
most of the energy to delocalized electrons from protons to form metalized 
hydrogen. The optimum cavity size does the same job as extreme pressure to form 
metalized hydrogen.

If hydrogen is packed into a Nano cavity of the ideal size a strong coupling 
state might be achieved between the protons in the hydrogen and the light. In 
this way a state of superconductive coherence of protons might be formed: a 
proton condinsate.

This state of superconductivity has been detected by Holmlid and Miley in iron 
oxide. The high temperature proton BEC might produce a super-dense state of 
hydrogen as measured by Holmlid where the electrons and protons are delocalized 
from each other, this state of charge delocalization has been seen in water 
inclusions inside a crystal.

physics.aps.org/articles/v9/43<http://physics.aps.org/articles/v9/43>
Water Molecule Spreads Out When Caged

[http://physics.aps.org/assets/2ffd09ee-e786-4c72-844f-9b1a7df49a75/e43_1.png]<http://physics.aps.org/assets/2ffd09ee-e786-4c72-844f-9b1a7df49a75/e43_1.png>

What actually compresses the protons into a condinsate is vacuum energy because 
the cavity squeezes the light/matter condensate greatly.

As described in the referenced article by looking for a hydrogen BEC in 
cavities, a LENR researcher could find the ideal dimensions of the Nano cavity 
that produces the condensed hydrogen and engineer a material that produces this 
ultra-dense hydrogen crystal in abundance.

Currently in LENR reactors, pure chance produces metalized hydrogen in a highly 
porous metal that feature a wide range of cavity sizes which include the 
optimum cavity size that is made widely available by random chance.

What really compresses hydrogen to the LENR active ultra-dense metalized state 
is not high pressure, but the ideal combination of cavity shape/size, light 
frequency, EMF environment and vacuum energy.


[Vo]:The key to LENR is strong coupling between the hydrogen atom and light.

2016-08-25 Thread Axil Axil
sciencedaily.com/releases/2016/08/160822152626.htm


For more detail see as follows:

arxiv.org/pdf/1604.08297v1.pdf

Abstract

Nonperturbative coupling of light with condensed matter in an optical
cavity is expected to reveal a host of coherent many-body phenomena and
states [1–7]. In addition, strong coherent light-matter interaction in a
solid-state environment is of great interest to emerging quantum-based
technologies [8, 9]. However, creating a system that combines a long
electronic coherence time, a large dipole moment, and a high cavity quality
(Q) factor has been a challenging goal [10–13]. Here, we report collective
ultrastrong light-matter coupling in an ultrahigh-mobility two-dimensional
electron gas in a high-Q terahertz photonic-crystal cavity in a quantizing
magnetic field, demonstrating a cooperativity of ∼360. The splitting of
cyclotron resonance (CR) into the lower and upper polariton branches
exhibited a √ ne-dependence on the electron density (ne), a hallmark of
collective vacuum Rabi splitting. Furthermore, a small but definite blue
shift was observed for the polariton frequencies due to the normally
negligible A 2 term in the light-matter interaction Hamiltonian. Finally,
the high-Q cavity suppressed the superradiant decay of coherent CR, which
resulted in an unprecedentedly narrow intrinsic CR linewidth of 5.6 GHz at
2 K. These results open up a variety of new possibilities to combine the
traditional disciplines of many-body condensed matter physics and
cavity-based quantum optics.



The key to LENR is strong coupling between the hydrogen atom and light.
When the cavity that holds the hydrogen is the optimum size, vacuum energy
provides most of the energy to delocalized electrons from protons to form
metalized hydrogen. The optimum cavity size does the same job as extreme
pressure to form metalized hydrogen.

If hydrogen is packed into a Nano cavity of the ideal size a strong
coupling state might be achieved between the protons in the hydrogen and
the light. In this way a state of superconductive coherence of protons
might be formed: a proton condinsate.

This state of superconductivity has been detected by Holmlid and Miley in
iron oxide. The high temperature proton BEC might produce a super-dense
state of hydrogen as measured by Holmlid where the electrons and protons
are delocalized from each other, this state of charge delocalization has
been seen in water inclusions inside a crystal.

physics.aps.org/articles/v9/43
Water Molecule Spreads Out When Caged



What actually compresses the protons into a condinsate is vacuum energy
because the cavity squeezes the light/matter condensate greatly.

As described in the referenced article by looking for a hydrogen BEC in
cavities, a LENR researcher could find the ideal dimensions of the Nano
cavity that produces the condensed hydrogen and engineer a material that
produces this ultra-dense hydrogen crystal in abundance.

Currently in LENR reactors, pure chance produces metalized hydrogen in a
highly porous metal that feature a wide range of cavity sizes which include
the optimum cavity size that is made widely available by random chance.

What really compresses hydrogen to the LENR active ultra-dense metalized
state is not high pressure, but the ideal combination of cavity shape/size,
light frequency, EMF environment and vacuum energy.