Circle of Trust

"Particle physics is the unbelievable in pursuit of the unimaginable. To pinpoint the smallest fragments of the universe you have to build the biggest machine in the world. To recreate the first millionths of a second of creation you have to focus energy on an awesome scale."

The Guardian

If one understod this observation held to the nature of the very small, one might see how such observations as Brian Greenes could place a six foot tall human being in a piece of the beginning.

Of course I am outside of the "circle of trust" :) here in terms of debating the essence of what scenario's might have an influence on the "safety of humanities concerns" while a whole vast network of scientist and all the like, work in the society around LHC.

There are 1800 physicists (Including 400 students) participating from more than 150 universities and laboratories in 34 countries.

It would be a career suicide for someone within these years established, to say such a thing counter to what had taken from 1955 to what it has become what it is today.

Here Peter Woit might be happy to know that experimental processes have instigated a whole history of developement that is ongoing through trial runs and the sort, for those who will track these histories from the beginning of collision process.

So "Risk assessment," although we had been presented with this outfit in concert from the developing perspective of questions dated to 2003, are asking in light of concerns, how it can be of detriment to having some influence on society?

So gaining ground from a informative stance on where society is today with it's scientists leading the way is important. Do they have "watch dog process" that determines these factors in advance of any proposals that would initiate scientific concerns and risks attachments sanctioned that the process is okay?

I personally do not think it has to be a behind the scene process, in terms of how the watch dogs in society might have revealled their concerns. Were then, given demonstrable arguments as to why there are no needs to worry.

This process in itself might be telling in terms of how scientists and the experiments that are put forward, are responded too, before the actually implementation.

I don't know how this works and it might be interesting from a societal point of view?

Might I use Peter Woits steadfastness to present thoughts about string theory as an example of why such atttudes would be allowed predominance and encouragement, to present the argements for, and against, as to somethings viability? We know now that the commitment is well documentated in what already exists, so I don't think it to likely at this point one could stop the process.

I would be extremely happy to know that extra diensional work, has no bearing on what is being produced, while we get a clear picture of our universe?

Information about LHC :So You Want to Play Games?

LHC - THE LARGE HADRON COLLIDER

So of course such contributions to involvement the general public in a style response screen saver thought bend towards the increase of computation abilities to digest?

In January of 2004, Ben Segal and François Grey of the IT Department were asked to plan an outreach event for CERN’s 50th anniversary that would allow people around the world to get an impression of the computational challenges facing the LHC. Ben and François got in touch with Dave Anderson, the Director of SETI@home, who was just beginning to test the new BOINC platform his team had developed. At the same time, a couple of Danish students got in touch with François, eager to find an exciting project for their Masters thesis. This was the beginning of LHC@home. Christian Søttrup and Jakob Pedersen worked furiously all spring and summer to get SixTrack and BOINC to function together. You can read their thesis , which describes the opportunities for combining public resource computing, such as LHC@home, with Grid computing like the LHC Computing Grid.

The LHC is a synchrotron. A synchrotron accelerates particles by having them travel around and around in a vacuum tube. The LHC will have two such tubes placed side by side so that the same kind of particles - protons - can be accelerated in opposite directions and then smashed into each other.

As one read previously throughout this thread and leading through Pierre Auger experiments and related links, I had come to the conclusion that the evidence for microstate blackhole hole procduction was happening all around us, from cosmic interactions. IN the risk assessment.org, this saids it is not of a concern or comparable?


A critical look at risk assessments for global catastrophesAdrian Kent

Speculative suggestions are occasionally made about ways in which new physics experiments could hypothetically bring about a catastrophe leading to the end of life on Earth. Some of these hypothetical catastrophes, including the “killer strangelet” scenario considered in this paper, would also lead to the destruction of the planet and wider catastrophic consequences. In any case, the proposed catastrophe mechanisms generally rely on speculation about hypothetical phenomena for which there is no evidence, but which at first sight do not contradict the known laws of physics. Sometimes, such pessimistic hypotheses can be countered by arguments which show that the existence of the catastrophe mechanism is highly improbable, either because closer analysis shows that the proposed mechanism does in fact contradict well established physical principles, or because its existence would imply effects which we should almost certainly have observed but have not.

Far be it that my visionary skills kick in, and from reading, I see such microstate as passing though all things around us, and yet, if such a gathering was to take such features and increase, what saids that such valuations might never have been collected at the core? What would be the trigger mechanism that would instigate gravitational collapse, has been a geometrical puzzle for me, as I move through this cyclical valuation of what began, and ends from such universes?

IN Viscosity State Production is ?

Thus, a black hole can be created with such energy packed into the corresponding length scale. These mini black hole will evaporate in 10-88 seconds, losing most of its mass by Hawking radiation. It is estimated that the final burst should radiate a large number of particles in all directions with very high energies. The decay products include all the particle species in nature. The LHC could provide the first evidence for Hawking radiation from such signatures of the black holes. Figure 04a depicts the simulated decay of a black hole inside a particle detector. From the center of the accelerator pipe (black circle) emerge particles (spokes) registered by layers of detectors (concentric colored rings). The sequence from birth to death of a mini black hole with an initial mass of 10 Tev is shown schematically in Figure 04b. It is created by the collision of two energetic particles (a). The scenario suggests that it will emit gravitational and electromagnetic waves as it settles

It's always good to have some idea of the process. So what is the liquid drop?

So there are some things that make the production process a interesting one, and froma layman perspective talk about intuitions taken a leap here. So I made ealier comparsions here because of th enature of the superfluids involved heeree and how developing perspective around them provide for enviromenta cosniderations dealing i the substance of such collisions.

LHC cryogenic unit keeps its cool

The cryogenic system for the Large Hadron Collider (LHC) at CERN reached a major milestone on 7 April by achieving operation of the unit at Point 8 at its nominal temperature of 1.8 K. The LHC and its superconducting magnets are designed to operate at this very low temperature, making the 27 km accelerator the coldest large-scale installation in the world. Although acceptance tests performed on the surface had already reached the required temperature in 2002, this is the first time that the nominal temperature has been achieved in situ.

Yet here we are thinking about Microstate blackhole production, and we have advanced the ideas somewhat into the reality of the situation. So here in this bottle neck, and I have not seen how this works in reality, so I am guessing here by using analogies to help push my perspective forward. Some of the unique characteristics of superfluids are helping to define the process somewhat?

The Blackhole as a Superfluid: It's Viscosity

Now you must understand that thinking of any first principle is hard to refrain from, especially, if one had thought like I do, that the geometrical tendencies are inherent in the way this is handled, and that it leads to other things? "The equations of relativity fail, and new laws emerge." saids George Musser. " A quark-gluon plasma, in three spatial dimensions - behaves as if it has a viscosity near zero, the lowest yet measured."

That's important, is it not from a geometrical perspective, because from this Dirac's visionary quest might have said, that here lies the opportunity for such a notion to begin, hyperbolically, or spherically. One way, or the other??

Blackhole substances are perhaps the most-perfect fluids in existence because they have ultra-low viscosity.

No matter what you call it, though, that substance and others similar to it could be the most-perfect fluids in existence because they have ultra-low viscosity, or resistance to flow, said Dam Thanh Son, an associate physics professor in the Institute for Nuclear Theory at the University of Washington.

Son and two colleagues used a string theory method called the gauge/gravity duality to determine that a black hole in 10 dimensions - or the holographic image of a black hole, a quark-gluon plasma, in three spatial dimensions - behaves as if it has a viscosity near zero, the lowest yet measured.

Lubos Motl:

The quark picture is more ordinary and materialistic but the black hole picture with an extra dimension is actually more useful to understand some general laws, such as the bounds on viscosity.

The problem might have been missed, with what one might, or should have look at? Herein the condense matter specialist might have thought hey, a superfluid indeed, and we have created a blackhole of a kind? What is this Bound Viscosity?

Sungho Hong on December 6, 2003 :

There is an interesting proposal by Andreas Karch. With certain assumtions, he showed that the entropy bound implies the viscosity bound. Moreover, this relation seems true even beyond the assumptions that he made. An interesting point is that the tabletop experiments could test this. The viscosity of superfluid He4 misses the bound only by a factor of 10.

Thse ideas that begin to manifest, have been from venturing into ideas of expeirmentation. What had arisen from blackholes in our colliders?

Frozen Stars
Black holes may not be bottomless pits after all
By George Musser July 2003

Under the right conditions, a fluid can turn into a superfluid, governed by quantum mechanics even on macroscopic scales. Chapline, along with physicists Evan Hohlfeld, Robert B. Laughlin and David I. Santiago of Stanford University, has proposed that a similar process happens at event horizons. The equations of relativity fail, and new laws emerge. "If one thinks of spacetime as a superfluid, then it is very natural that in fact something physical does happen at the event horizon--that is, the classical event horizon is replaced by a quantum phase transition," Chapline says.

So you don't lose sleep, or the world is a nice place, la te da... because it is what it is?:) It's just a generalization, as any assumption of the data might have convinced one, either way? What is it's value?

One might have assume because of the time involved, that accumulation and gatherings, might have taken up residence at the center of the earth. So? Okay? :)

Blackhole Creations

Steve W

Your paper linked:

STUDY OF POTENTIALLY DANGEROUS EVENTS
DURING HEAVY-ION COLLISIONS AT THE LHC:
REPORT OF THE LHC SAFETY STUDY GROUP

Cosmic Rays 2.21

Cosmic-ray processes reach the energies and energy densities that will be encountered at the LHC and, therefore, they may provide limits on possible disaster scenarios. Such limits have been discussed in Refs. [1] and [3] and much of the analysis applies also to the LHC. Recent results obtained with a detector adding time-of-flight information to an array large enough to reach energies at and above the knee [9], approaching the LHC-equivalent energy region, confirm with improved accuracy that heavy ions have started to dominate the spectrum. Although the precise chemical composition is not known, the average value of A corresponds to that of magnesium, with ions at least as heavy as iron forming a substantial part. We summarize briefly here the main conclusions, taking into account the recent data from RHIC.

This is one of the sobering facts that we can contend with, when we realize not only are we dealing with things that are happening around us, but that we understand that dissipation is just a part of this process, as to find how we might see into these extra dimensions.

Horatiu is referring to a mathematical similarity between the physics of the real world, which govern RHIC collisions, and the physics that scientists use to describe a theoretical, “imaginary” black hole in a hypothetical world with a different number of space-time dimensions (more than the four dimensions — three space directions and time — that exist in our world). That is, the two situations require similar mathematical wrangling to analyze. This imaginary, mathematical black hole that Horatiu compares to the RHIC fireball is completely different from a black hole in the real universe; in particular, it cannot grow by gobbling up matter. In other words, and because the amount of matter created at RHIC is so tiny, RHIC does not, and cannot possibly, produce a true, star-swallowing black hole.

There is a summ total of the interactive processes taking place in nature around us and we are part of this scenario. We do control the energies demanded in experimental research, but this does not disavow the process from happening in nature with the inability for us to control those same energies.

Many physicists find extra dimensions a distasteful notion. In remarks to an American Physical Society newsletter, physicist Frank Wilczek of MIT called the black hole study a sound way to test an unattractive idea.

"There's no question that the Auger observatory will be sensitive to this signal, if it exists," says Penn State's Stéphane Coutu, a member of the international Auger Observatory team. "We'll definitely look."

So rest easy.

Think about what we see in the daylight, and if such dissipated valuation can be assigned these microstates, then what say that we see the nature of things in ways that we had not before?

While it is speculative on my part from what I have understood is that such emissions would have found harmonical values to the way we describe what we see in reality? Yet, there are dimensions to this world that we have not considered?

Where have we run into our limitations? Imagine that such processes can be mirrored in our environment, as we strive to control the experiments we see Pierre Auger has continued along and developed as well.

High Energy Physics

The study of high energy physics, also known as particle physics, grew out of nuclear and cosmic ray physics in the 1950’s, and measured the properties and interactions of fundamental particles at the highest energies (millions of electron-volts) then available with a relatively new technology, particle accelerators. Today that technology has advanced so that forefront particle accelerators produce exquisitely controlled beams with energies of trillions of electron-volts and intense enough to melt metal. The science has advanced with the technology to study ever-higher energies and very rare phenomena that probe the smallest dimensions we can see and tell us about the very early history of our universe. While the science has revolutionized our understanding of how the universe works, elements of the technology have helped transform other fields of science, medicine, and even everyday life. The science and its impacts will be remembered as one of the highlights of the history of the late 20th century.

It was important to keep these two lines of investigation in perspective, as they diverged.

After doing some more research I am coming across statements that run contrary to what I might have proposed as not of sufficient consideration alongside fo LHC and Cosmic interactive feature in comparison. I find somet of thesse thngs a little troubling bt that is my own uncertainty about the effect.

Do Blackholes Radiate

The prediction that black holes radiate due to quantum effects is often considered one of the most secure in quantum field theory in curved space-time. Yet this prediction rests on two dubious assumptions: that ordinary physics may be applied to vacuum fluctuations at energy scales increasing exponentially without bound; and that quantum-gravitational effects may be neglected. Various suggestions have been put forward to address these issues: that they might be explained away by lessons from sonic black hole models; that the prediction is indeed successfully reproduced by quantum gravity; that the success of the link provided by the prediction between black holes and thermodynamics justifies the prediction.

This paper explains the nature of the difficulties, and reviews the proposals that have been put forward to deal with them. None of the proposals put forward can so far be considered to be really successful, and simple dimensional arguments show that quantum-gravitational effects might well alter the evaporation process outlined by Hawking. Thus a definitive theoretical treatment will require an understanding of quantum gravity in at least some regimes. Until then, no compelling theoretical case for or against radiation by black holes is likely to be made.
The possibility that non-radiating "mini" black holes exist should be taken seriously; such holes could be part of the dark matter in the Universe. Attempts to place observational limits on the number of "mini" black holes (independent of the assumption that they radiate) would be most welcome.

After following up and continuing this research, something very amazing made itself known that I had not considered although I seemed to be moving in that direction.

Consider indeed for a moment that the "superfluid" that had been created had indeed held the context of the blackhole and what is revealled in the aftermath, as a strange Quark(?). This had some interesting insights that are leading to other things that might have manifested had we see the relaton of the iron core and what could have gathered at it. You have to wonder and I will be moving in that direction.

Risk Evaluation Forum

References :

1.. Study of potentially dangerous events during heavy-ion collisions at the LHC : Report of the LHC Safety Study Group. CERN 2003-001 28 February 2003.

2.. Study of potentially dangerous events during heavy-ion collisions at the LHC :

LHC Safety Study Group. J.P. Blaizot, J. Iliopoulos, J. Madsen, GG. Ross, P. Sonderegger, H-J. Specht « No date for this study, available Internet May 2004 ».

3..E-mail exchange between Greg Landsberg and James Blodgett March 2003.

James Blodgett Internet Forum. http://www.risk-evaluation-forum.org/links.htm

Avalaibable at : Risk Evaluation Forum PO BOX 2371 Albany, NY 12220 – 0371 USA

4.. Might a laboratory experiment destroy planet Earth F. Calogero 2000

Available in Forum. http://www.risk-evaluation-forum.org/links.htm

5..A critical look at risk assessment for global catastrophes CERN-TH 2000-029 DAMTP-2000-105 Revised April 2003. hep-ph/0009204 Adrian Kent

6..Trous noirs Nrumiano http ://nruminiao.free.fr/fetoiles/int_noir2.html

7..Black holes at the large hadron collider Phys Rev Lett 87, 161602 (2001)

8.. Working paper: a cosmic ray/micro-black hole model James Blodgett

Available in Forum. http://www.risk-evaluation-forum.org/links.htm

9.. High energy colliders as black hole factories: the end of short distance physics Steven B. Giddings, Scott Thomas. Phys Rev D65 (2002) 056010

10.. Discovering new physics in the decays of black holes. Greg Landsberg. Phys Rev. Lett.88, 181801 (2002)

11.. CERN to spew black holes Nature 02 October 2001

12.. Brookhaven national laboratory News 5 may 2004

New Machine Record for Heavy Ion Luminosity at RHIC

13.. Collider mini black holes: loss of protective considerations James Blodgett 2004

Available in Forum. http://www.risk-evaluation-forum.org/links.htm

14.. Review of speculative disaster scenarios at RHIC September 28,1999

W.Busza, R.L. Jaffe, J.Sandweiss and F.Wilczek

15.. Spectre des rayons cosmiques de très haute énergie Source [GAI]

16.. Atlas de l’Astronomie Albin Michel 1983

17.. Stephen Hawking Physics Colloquiums - Gravitational Entropy (June '98).

18.. Trous noirs et distorsions du temps. Kip S. Thorne.

Flammarion 1997. ISBN 2-08-0811463-X

Original title : Black holes and times warps.1994 Norton. New York.

19.. “will relativistic heavy-ion colliders destroy our planet ?”.

A.Dar, A. De Rujula and U. Heinz,, August 1999, submitted to Nature

20.. L’Univers élégant. Brian Greene. Laffont september 2000. ISBN 2-221-09065-9

Original title The elegant Universe. ISBN 0-393-04688-5 Norton. New York.

21.. Science & Vie N°107 Juin 2002 “stars with quarks in our galaxy”

22..Science & Vie N°1029 Juin 2003 “ L’énergie du vide”

23.. La Recherche N°376 Juin 2004. « La force qui vient du vide »

24. La Recherche » ( 1990 ? ) about « La supersymétrie étendue » :

25. Ciel et Espace Avril 2003 page 43

26..Brane worlds and Extra Dimensions. Brian Gantz PHY 312. May 11, 2000

27.. James Blodgett Working paper (about cosmic rays)

James Blodgett Internet Forum. http://www.risk-evaluation-forum.org/links.htm

Avalaibable at : Risk Evaluation Forum PO BOX 2371 Albany, NY 12220 – 0371 USA

28..Science & Vie N° 1042. Juillet 2004. « Centre de la Terre. »

29.. Power of ten. 10exp-16.htm Bruce Bryson 200-04

30..Greg Landsberg i chep 2002 Amsterdam Internet Key: Greg Landsberg

http://www.ichep02.nl/Transparencies/BSM/BSM-4/BSM-4-3.landsberg.pdf

31..Science & Vie N°1043 Août 2004 Théorie du Tout.

32.. Results of several Delphi groups and physicist questionnaires, James Blodgett, Risk Evaluation Forum, forthcoming.

33.. Science et vie N°1050 Mars 2005 « Matière en route vers son ultime continent »

34.. La recherche N°384 Mars 2005. pourquoi l’Univers accélère.

35.. Adam D. Helfer, "Do black holes radiate?", Rept.Prog.Phys. 66 (2003) pp. 943-1008

http://xxx.lanl.gov/abs/gr-qc/0304042 Questions whether black holes radiate.

36.. V.A. Belinski, "On the existence of quantum evaporation of a black hole," Physics Letters A, Vol 209 Num 1 (1995) pp. 13-20. Asserts that Hawking radiation does not exist.

37.. La Recherche N° 382 Janvier 2005 l’antimatière questionne le Big Bang

38.. BBC New uk edition Thursday 17 March 2005 11 :30 GMT “Lab fireball may be black hole”

Update on Cosmic Strings

Hubble: cosmic string verdict by February

I just wanted to keep this for inspection, and relate Lubos's current statement in this regard, together, for refreshing look at this topic.

This is of course from 2005/July 11 of 2005, but it serves to have a look a what was being discussed in this way, that we can see how "the history" has unfolded into cosmological dissertations.

Update on cosmic strings
Joseph Polchinski
KITP, UCSB

Joseph Polchinski, KITP, UCSB: Update on cosmic strings

KK Tower

Like many people who devote their time to understanding the nature of the cosmo and the micro perspective of the world around us, these things have their own motivational packages which move to further rquired comprehensions. In that, one needs to further educateas to what they are talking about.

It's definitiely not easy, but I am trying, and devote a lot of time to this regardless of what schooling is required, it is not my intent to send people down the wrong paths, or, no paths at all, before I have investigated the terrain as best I can.

Mountains can give persepctive where sitting in the valleys circumspect what the greater can be?

KK Tower

What is it?



Kaluza-Klein theory(Wiki 4 Jan 2006)

A splitting of five-dimensional spacetime into the Einstein equations and Maxwell equations in four dimensions was first discovered by Gunnar Nordström in 1914, in the context of his theory of gravity, but subsequently forgotten. In 1926, Oskar Klein proposed that the fourth spatial dimension is curled up in a circle of very small radius, so that a particle moving a short distance along that axis would return to where it began. The distance a particle can travel before reaching its initial position is said to be the size of the dimension. This extra dimension is a compact set, and the phenomenon of having a space-time with compact dimensions is referred to as compactification.

Kaluza-Klein theory is a model which unifies classical gravity and electromagnetism. It was discovered by the mathematician Theodor Kaluza that if general relativity is extended to a five-dimensional spacetime, the equations can be separated out into ordinary four-dimensional gravitation plus an extra set, which is equivalent to Maxwell's equations for the electromagnetic field, plus an extra scalar field known as the "dilaton". Oskar Klein proposed that the fourth spatial dimension is curled up with a very small radius, i.e. that a particle moving a short distance along that axis would return to where it began. The distance a particle can travel before reaching its initial position is said to be the size of the dimension. This, in fact, also gives rise to quantization of charge, as waves directed along a finite axis can only occupy discrete frequencies.

Kaluza-Klein theory can be extended to cover the other fundamental forces - namely, the weak and strong nuclear forces - but a straightforward approach, if done using an odd dimensional manifold runs into difficulties involving chirality. The problem is that all neutrinos appear to be left-handed, meaning that they are spinning in the direction of the fingers of the left hand when they are moving in the direction of the thumb. All anti-neutrinos appear to be right-handed. Somehow particle reactions are asymmetric when it comes to spin and it is not straightforward to build this into a Kaluza-Klein theory since the extra dimensions of physical space are symmetric with respect to left-hand spinning and r-hand spinning particles.

So in order to get to the summation, views of hidden dimenisons had to be mathematically described for us, so a generalization here would suffice in the following diagram.



Now, not having the room to explain, and having linked previous information on extension of KK theory, I wondered about the following. If we understood well, the leading perspective that lead us through to the dynamical realizations, then the road Gauss and Reimann lead us to would help us to understand the visualization materializing by the calorimeter disciptions of each energy placement harmonically describing each particle's value? Even in a empty space, there seems to be something of a harmonical consideration?


If one understood well enough about the direction of discernation of early universe consideration and microstates, then such questions would have been of value in the ideas of topological considerations?

Getting Ducks in a Row

Energising the quest for 'big theory'
By Paul Rincon

We are at a point where experiments must guide us, we cannot make progress without them," explains Jim Virdee, a particle physicist at Imperial College London

Good to see Joanne contributions here as well as Marks.

Even though Dissident throws up tidbits for the "unlikely scenario of Blackholes" that devour? These were early fears that were propogated by those of us who did not understand. Maybe the new TV show will make itself known here? What has our past shown in this regard?

Peter Steinberg

Unfortunately, all of this is overstated. At RHIC we don't make a "real" black hole, in the sense envisioned by Einstein's General Theory of Relativity. Rather, Nastase's point of view is that RHIC collisions can be described by a "dual" black hole. But what does "dual" mean in this context? It's not "two-ness" in any sense, but rather indicates that one can write down a theory which describes the collision as a black hole, but in a completely different world than that we see around us. To make his model work, he (and many other researchers who are exploring this direction) make a calculation of a black hole in 10 dimensions in order to describe difficult (but gravitationally benign) aspects of the strong interaction in 4 dimensions.

I was equally dismayed by the understanding that this methods were not understood by dissident, as to the value of Pierre Auger's views containing the very ideas that we see in the enviroment around us. Is it an alternative to how we see particle interactions? Of course. John Ellis made this point very clear, as I have demonstrated through out this site, gaining perspective as spoken by Ellis on information given.

Plato:

The Fly's Eye and the Oh My God Particle John Ellis was instrumental in opening up perspective here. What is happening outside of collision reductionist processes of the colliders

I get a little philosophical myself sometimes, with the hope that "pure thought" can lead me to the very math structure that would be most appropriate. But like anything, there are so many maths in which to talk about the world in such an abstract way, one wonders if they are actually talking about reality? But they are are. :)

If conceived as a series of ever-wider experiential contexts, nested one within the other like a set of Chinese boxes, consciousness can be thought of as wrapping back around on itself in such a way that the outermost 'context' is indistinguishable from the innermost 'content' - a structure for which we coined the term 'liminocentric'.

The ideas around KK are also included, like most, I have a lot to learn. But the KK tower is explanatory about the a lot of things in relation to the energy values that are being assigned here? Just diffrent ways at looking at scattering amplitudes and counting might have looked if we took nature to gluonic perceptions? A granularaization? While at such levels then there are no geometries in which anything can emerge?

DumbBiologist:

There’s no other necessary connection to stringy physics except that it’s a KK theory (I guess the compactified dimensions can still be pretty big compared to the Planck length…perhaps they have to be?). It’s not obviously related to quantum gravity, anyway.

So how do you include such "weak field "manifestation in your global perspective(standard model). Some things are recorded, and some can't be seen? So what is the glue that binds:)

A collision had produced the "superfluid" has no place in quantum gravity issues?

He⁴ came from information the beginning, that a Giddings or a Steinberg might have given us about the nature of the "source" of this collision? How would such a thing from this place have figured, this was a place in which to begin to count? So we write it in and hope that such views in context of this "unitary nature" will have revealled all the tragetories of the scatterings, to have said this is a complete view?


Lubos Motl:

When you add a force that you want to treat perturbatively, which should be possible if the success of QED is reproduced by your quantum theory of gravity and electromagnetism, then you are expanding around "g=0" where "g" is the gauge coupling. In quantum gravity, there is a new ultraviolet cutoff "g.M_{Planck}" above which the effective theory breaks down. If "g" goes to zero, then this scale goes to zero, too. The theory therefore breaks down at all scales. You can't expand around the point where gravity is the strongest force because a quantum theory of gravity in which gravity is stronger than other forces is inconsistent.

The Lap Top of the Future?

I think technology is great, and some of the stories we can produce, equally as thought provoking. Ipod's and Mission Impossible?

Oh Clifford, where are you?

While some might of thought the analogy to the "blackgold" as a standard in a economic sense, I still try to think of the "gold reserves" as the true monitor of banks and money printed. Yet, we find that new indicators are setting the price of living, to standards that the few make towards cost of living realizations? US ruin where rerserves, China's gain? A worthy trading partner indeed.

Okay that's to political. On to the essence of the story.:)

My plan is not a incidious one, where I will try and convert you to "evil," but put into perspective the state of affairs. Not concieved to derail geometrical thinking at it's finest, but bring one in concert with the strumming of "good songs" as we ride the "river of life:)" Oh my, I am being bombarded by solitonic images of boats traveling channels, and all sort of things.

Written and directed by Kenneth Alan Taylor


I would rather think of the Goose that laid the Golden Egg, then eggs that could possibly hatch as the dumbest ideas of Rooster's:)

Okay, so I am struggling.

You have to remember the basis of this question is "held in light" of a thought experiment linked at the heading of this post. I know it's possibilties yet containment really makes it difficult to fathom. So I like to think of tall tails and sailing ships as possible stories that were created in fiction, have now made it possible for Jack to bring this Golden Egg, back for consideration. Or maybe the Princess's Pea as a measure of what would have been contained in the singularity, had drawn to delving all minds to consider this nagging question that we tend to sleep on? The "Beginning of the universe?"

Did you know Plato like the "idea of ideas?" While it might made one think of the emphemeral qualities of mind, I know that to be "grounded" would be a good thing, while we look at Jack in the Beanstalk's journey to fetch the Golden Egg.

Anthony A. on Jan 2nd, 2006 at 7:41 pm :

In an infinite universe, there appears to be, as I noted before, some interchangeability between the different branches of the wavefunction and the different copies that exist in the infinite universe. (In fact this is the basis for a new interpretation of quantum mechanics that I have been reading, and got me thinking about the whole matter.)

The thought provoked here, is contained in the structure of this statement, "different branches of the wavefunction" could lead to new quantum reality taken from the artifacts, and released into probable futures? This is a summation of how one might see all that can be contained in the outcome of heads or tails, and from such information, provide for model apprehensions that could have been emitted from the very beginning of this universe? Why not?

We punch in the probability of this reference of quantum perception with cosmological data and if 13.7 billions years could be contained in the model, then what says the limit of this universe could not be contained in what this universe might have become?

The amount of information that can be stored by the ultimate laptop, 10 to the 31st bits, is much higher than the 10 to the 10th bits stored on current laptops. This is because conventional laptops use many degrees of freedom to store a bit whereas the ultimate laptop uses just one. There are considerable advantages to using many degrees of freedom to store information, stability and controllability being perhaps the most important. Indeed, as the above calculation indicates, to take full advantage of the memory space available, the ultimate laptop must turn all its matter into energy. A typical state of the ultimate laptop's memory looks like a plasma at a billion degrees Kelvin — like a thermonuclear explosion or a little piece of the Big Bang! Clearly, packaging issues alone make it unlikely that this limit can be obtained, even setting aside the difficulties of stability and control.

But what's the point here in recognition?

That there are indeed outcomes from thinking of a certain point, could have manifested possibilities. The outcome here is present questions although contained in the article linked in from 2000, it points the mind to direction currently manifesting in our everyday lives, as we move to question the nature and geometry of this beginning of the universe and it's possible branches thereof?

But let's see this in contrast to early computation models. Rooms filled with equippment to have now found such levels atomized to current technological wonders?

Being part of this scenario in our past and witnessing the moves to such lenghts, bring perspectve to the nature of the colliders and the quest for perspctive held in contrast to quantum probabilites. Looking at this bold highlighrted statement of Seth Loyd brings th every nature of what is being pursued asa viable question about what we had hoped to conatin inthe LAPTOP, BUT SEEING THE COMPLEX QUESTION OF CONTAINMENT MAKES THIS QUITE UNLIKELY. It does not remove the question of probable outcomes and th every nature of geoemtries assigned, as this is a leading indicator to values held in contrast to the depth of pereception needed?

Danger, Phil Anderson by Sean Carroll

Looking for such a position, can be a fickled thing, so where would such things lead from a "flat spacetime" to have then gone either way in the speculations of the geometries?

Sorry, a layman dreaming. Is it a philosophical question, that the possibilties could have ever be increased from negative things(geoemtries in expression), heated up, to create new possibitlies?

Einstein Was Right (Again):

Lubos Motl:

In the particular case of the recent "E=mc^2 tests", the accuracy was "10^{-7}" while we know experimentally that the relativistic relations are accurate with the accuracy "10^{-10}", see Alan Kostelecky's website for more concrete details. We just know that we can't observe new physics by this experiment.

NIST and MIT Confirm that E= mc2
Archives-http://physics.nist.gov/News/TechBeat/techbeat.html

An instrument called GAMS4, originally designed and built at NIST and now located at Institut Laue Langevin in France, was used in experiments that helped to confirm Einstein’s famous equation E=mc². GAMS4 measured the angle at which gamma rays are diffracted by two identical crystals made of atoms separated by a known distance. The two crystals are the dark gray rectangles on circular platforms in the foreground and background of the photo.




The gamma rays in this process have wavelengths of less than a picometer, a million times smaller than visible light, and are diffracted or bent by the atoms in the calibrated crystals at a particular energy-dependent angle. Using a well-known mathematical formula, scientists can combine these angles with values for the crystal lattice spacing to determine the energy contained in individual gamma ray particles.