Line 18a3s4 Black Hole SuperB INFN Belle II LHC CERN Electron Capture WOW SETI
Black hole
Line 18a3s4 Black Hole SuperB INFN Belle II LHC CERN Electron Capture WOW SETI
part 125 of 100 videos there are more videos after this one i’ll post all then update the #.
Math Equation Wow Seti 1977 radio signal alien
14/
3/4/4/1/1/1/1/11=0.017
14/0.017=823.5294
Feb 10 2012 714 pm est
My thoughts
I Googled Osterwalder-Schrader and found this paper Mathematical Physics…
It talks about mathematical systems of axioms. I know that “key” word came up before.
Axioms comes up in Line 18f :
axiomatic formulations of thermodynamics under DATA to READ.
Hilbert is another key word it comes up in Line 17i, 17 Line Index, Line 16a
Hilbert + Banach Spaces in Line 17i
Line 17i Linear Topological Space Vector Space Hilbert Banach WOW SETI
So we have Quatum Field Theory + Axiomatic Formulations of Thermodynamics + Hilbert Spaces + Banach Spaces = Linear Topological Space + Vector Space + Hilbert Series
See data from line 16a adding more here about Hilbert as a key word and then go to Line 18as5 video for more about the connections to this key word.
Feb 10 2012 702 pm est
My thoughts
When I read about Super B I immediately thought of the testing for the Neutrinos, non gravity, matter and rotating space ship.
Can they use the test results from superb with the formula’s provided in the line wow SETI equations to test the liquid gas + the neutrino’s.
I remember writing about cooling the neutrino’s to slow them down and see if they can split in half like an atom?
They are particles, do they all split?
If not, why?
What can we do to produce energy from these particles by mixing them with the gases mentioned in the WOW SETI solutions..
notes
Black hole
• On Black hole microstates. - a one hour presentation on the interpretation of black hole microstate counting using entanglement. Given at the high energy seminar, UH Manoa. – Summer 2004
• Entanglement interpretation of black hole entropy in string theory - a one hour talk given at the ISCAP seminar, Columbia university. – Summer 2005
• Black hole entropy - A one hour presentation on black hole entropy, its evaluation in string theory, and a possible interpretation as entanglement. – Fall 2005
Pasted from
quote
inventions patents
Entanglement Interpretation of Black Hole Entropy in String Theory
Ram Brustein, Martin B. Einhorn, Amos Yarom
(Submitted on 29 Aug 2005)
We show that the entropy resulting from the counting of microstates of non extremal black holes using field theory duals of string theories can be interpreted as arising from entanglement.
The conditions for making such an interpretation consistent are discussed. First, we interpret the entropy (and thermodynamics) of spacetimes with non degenerate, bifurcating Killing horizons as arising from entanglement.
We use a path integral method to define the Hartle-Hawking vacuum state in such spacetimes and discuss explicitly its entangled nature and its relation to the geometry. If string theory on such spacetimes has a field theory dual, then, in the low-energy, weak coupling limit, the field theory state that is dual to the Hartle-Hawking state is a thermofield double state.
This allows the comparison of the entanglement entropy with the entropy of the field theory dual, and thus, with the Bekenstein-Hawking entropy of the black hole. As an example, we discuss in detail the case of the five dimensional anti-de Sitter, black hole spacetime.
Subjects: High Energy Physics – Theory (hep-th); General Relativity and Quantum Cosmology (gr-qc)
Journal reference: JHEP 0601 (2006) 098
DOI: 10.1088/1126-6708/2006/01/098
Report number: NSF-KITP-05-64
Cite as: arXiv:hep-th/0508217v1
Submission history
From: Ram Brustein [view email]
[v1] Mon, 29 Aug 2005 14:27:55 GMT (118kb)
Pasted from
GOOGLE wick rotation diagram
Gian-Carlo Wick
Gian-Carlo Wick
In physics, Wick rotation, named after Gian-Carlo Wick, is a method of finding a solution to a mathematical problem in Minkowski space from a solution to a related problem in Euclidean space by means of a transformation that substitutes an imaginary-number variable for a real-number variable. This transformation is also used to find solutions to problems in quantum mechanics and other areas.
Pasted from
quote
Wick calculated the magnetic moment of the hydrogen molecule with group-theoretical methods.
He extended Fermi’s theory of beta decay to positron emission and K-capture, and explained the relationship between the range of a force and the mass of its force carrier particle.
He also worked on slowing down of neutrons in matter, and joined a group of Italian physicists led by Gilberto Bernardini which made the first measurement of the lifetime of the muon.[1]
Pasted from
Pasted from <http://en.wikipedia.org/wiki/K-capture
If you know how to compute a function fE(x0,\x) in Euclidean
spacetime and know that it is analytic in x0, you can
analytically continue to get the corresponding
fM(t,\x)=fE(it,\x)
in Minkowski spacetime. If you know fE only numerically,
you can fit a rational function in t to the data and analytically
continue the latter. This usually gives reasonable results.
So Osterwalder-Schrader is exactly the right thing to look for.
Type these two names
into http://scholar.google.com/
to get plenty of additional information!
Pasted from
[PDF]
AdA: The First Electron-Positron Collider
cas.web.cern.ch/cas/Baden/PDF/Bernardini.pdf
Block all cas.web.cern.ch results
File Format: PDF/Adobe Acrobat - Quick View
by C Bernardini - Cited by 17 - Related articles
Gilberto Bernardini received his doctoral degree in Pisa in 1928, held a chair in Bologna from. 1938–1946, was at Columbia University and the University of …
Pasted from
Mathematical Physics
Osterwalder-Schrader axioms – Wightman Axioms
Palle E.T. Jorgensen, Gestur Ólafsson
(Submitted on 6 Jan 2000)
The mathematical axiom systems for quantum field theory grew out of Hilbert’s sixth problem, that of stating the problems of quantum theory in precise mathematical terms.
There have been several competing mathematical systems of axioms, and here we shall deal with those of A.S. Wightman and of K. Osterwalder and R. Schrader, stated in historical order.
They are centered around group symmetry, relative to unitary representations of Lie groups in Hilbert space. We also mention how the Osterwalder–Schrader axioms have influenced the theory of unitary representations of groups.
Comments: Encyclopedia article
Subjects: Mathematical Physics (math-ph)
Journal reference: Appeared under the title “Quantum field theory, axioms for” in Encyclopaedia of Mathematics, Supplement II, M. Hazewinkel, ed., Kluwer Academic Publishers, 2000, pp. 393–394.
Cite as: arXiv:math-ph/0001010v1
Submission history
From: Brian Treadway [view email]
[v1] Thu, 6 Jan 2000 19:47:32 GMT (4kb)
Pasted from
Feb 10 2012 714 pm est
My thoughts
I Googled Osterwalder-Schrader and found this paper Mathematical Physics…
It talks about mathematical systems of axioms. I know that “key” word came up before.
Axioms comes up in Line 18f :
axiomatic formulations of thermodynamics under DATA to READ.
Hilbert is another key word it comes up in Line 17i, 17 Line Index, Line 16a
Hilbert + Banach Spaces in Line 17i
Line 17i Linear Topological Space Vector Space Hilbert Banach WOW SETI
So we have Quatum Field Theory + Axiomatic Formulations of Thermodynamics + Hilbert Spaces + Banach Spaces = Linear Topological Space + Vector Space + Hilbert Series
See data from line 16a adding more here about Hilbert as a key word and then go to Line 18as5 video for more about the connections to this key word.
SuperB will study how heavy particles called B mesons decay into a welter of other exotic particles.L. Taylor, T. McCauley, V. Chiochia, C. Lourenco / CERN
Various Quotes to Read:
Published online 10 October 2011 | Nature | doi:10.1038/news.2011.585
News
SuperB particle-accelerator project launches
Funding uncertainty could delay high-speed Italian development.
The accelerator will be what physicists call a B-factory, where electrons and their antiparticles, positrons, will race around two 1.3-kilometre-long rings, then collide and produce heavy B mesons.
By studying the way these particles decay, physicists hope to fill some of the gaps in the standard model of physics, such as why there is more matter than antimatter in the Universe, and whether the exotic particles predicted by the theory of supersymmetry really exist.
SuperB will produce 100 times more collision events each year than did the two B factories previously built: the BaBar experiment at the SLAC National Accelerator Laboratory in Menlo Park, California, which shut down in April 2008, and the ongoing Belle experiment at the KEKB accelerator in Tsukuba, Japan. This increased luminosity should allow researchers to study even the rarest of physical phenomena.
Italy’s National Institute for Nuclear Physics (INFN) is running the project. Under an agreement signed by the INFN and Tor Vergata on Friday, the two will set up an international laboratory to oversee the construction and operation of SuperB; the lab will be named after Italian physicist Nicola Cabibbo.
Roberto Petronzio, who will soon give up his post as president of the INFN to become director general of the new laboratory, says that SuperB will complement the Large Hadron Collider (LHC) particle accelerator at CERN, Europe’s high-energy physics laboratory near Geneva, Switzerland, by helping to build a theoretical model around the LHC’s future discoveries.
“Whereas the LHC uses high energies to produce as-yet-unknown particles, SuperB will look for the indirect effects of those particles on the ones we already know,” says Petronzio.
The Italian Institute of Technology in Genoa is expected to join the collaboration within a few months. It will build synchrotron laboratories, which will conduct microscopy using the high-energy radiation produced by the accelerator.
United States, which plans to provide reusable components from the BaBar detector
Japanese Belle experiment, to be called Belle II, work on which will begin next year.
Construction of SuperB is expected to begin next year and operations are scheduled to start in 2017 — a breakneck timetable brought on by the competition with Belle II.
Although it will not reach SuperB’s luminosity, the upgraded Japanese experiment is expected to start taking data in 2016.
“We’ll probably be one year late,” says Petronzio. “We can catch up because we will see many more collisions, but we cannot afford to be later than that.”
INFN activities include many other large-scale experiments, such as neutrino and dark-matter research at the Gran Sasso Laboratories, the Virgo gravitational-wave observatory near Pisa and a strong involvement in the LHC.
Pasted from
SuperB will study how heavy particles called B mesons decay into a welter of other exotic particles.L. Taylor, T. McCauley, V. Chiochia, C. Lourenco CERN
Feb 10 2012 702 pm est
My thoughts
When I read about Super B I immediately thought of the testing for the Neutrinos, non gravity, matter and rotating space ship.
Can they use the test results from superb with the formula’s provided in the line wow SETI equations to test the liquid gas + the neutrino’s.
I remember writing about cooling the neutrino’s to slow them down and see if they can split in half like an atom?
They are particles, do they all split?
If not, why?
What can we do to produce energy from these particles by mixing them with the gases mentioned in the WOW SETI solutions..
Comments are closed.