Monday, February 13, 2006

Intersection of D Branes

I'm not going to try and kid you with "this stuff," as it is extremely beyond anything that any of us mere mortal can understand. So, if such a thought would be to simplify, then how would such thinking be attributed to such model building and make it easier for us lay people to comprehend where these people are working in terms of the way they do things.

What is important is that we can derive some method to this madness:) okay! rather this abstract thinking, to show some kind of similarity in lay people's current thought patterns for easy recognition.

I'll burn in hell, if I get this wrong, but surely from my "faulty trails (not Tower)" I can be forgiven, until a clearer picture is given to us, that I could revamp all that I said, and leave for you now, the trials and tibulation of a rogue what?:)

Now you have to think about what I am saying, if you understand indeed, that such a place exists in the picture below, which for us mortals to consider. Think for a minute about the blackhole and where I had been talking in relation to the collider, as well as, the cosmic collisions taking place, with higher energy particles in our own atmosphere.

Weak field manifestation has particle consideration evident, and we find these here on earth, as neutrinos. Do You see now?

Physicists Andrew Strominger and Cumrin Vafa, showed that this exact entropy formula can be derived microscopically (including the factor of 1/4) by counting the degeneracy of quantum states of configurations of strings and D-branes which correspond to black holes in string theory. This is compelling evidence that D-branes can provide a short distance weak coupling description of certain black holes! For example, the class of black holes studied by Strominger and Vafa are described by 5-branes, 1-branes and open strings traveling down the 1-brane all wrapped on a 5-dimensional torus, which gives an effective one dimensional object -- a black hole.


I thought this to be part of the trivial effort with which I had departed to the bulk perspective, without really undertanding how I had got there. Yet I do see in these ways and many things are encompassed within it(gravitonic concentration). I would say, like Clifford telling us about the proper way in which we should move within these mathematical environs, then I would say what a rogue scholar I make, becuase this seems be the bastard child I am whose school is by insight developement, and some of it, wrong of course. But I try.

Superstrings, black holes and gauge theories


D-branes are non-perturbative excitations of string theory on which open strings can end. Open strings have gauge fields, so the D-branes define a gauge theory. There is a class of black hole made of D-branes, and these have a quantum gauge theory description. The closed strings define a field theory of gravity.



PROSPECTS FROM STRINGS AND BRANESA.SEVRIN

Strings occur in two versions: closed and open strings. Roughly speaking, one has that closed strings carry the gravitational interaction and the open strings carry the gauge interactions. While closed strings can freely propagate in space, the modern point of view is that the end points of open strings are “stuck” on p-dimensional hypersurfaces, where p ∈ {1, 2, · · · , 9}. These hypersurfaces are known as Dp-branes. They are dynamical but they are extremely heavy in the perturbative regime of string theory (their tension or energy per unit of volume is inversely proportional to the string coupling constant): they are solitons. A D0-brane is a point-like object, a D1-brane a string-like object, a D2-brane a membrane, ... Just as a propagating point particle sweeps out a curve – the world-line – in space-time, a Dp-brane sweeps out a p + 1-dimensional volume – the world-volume – in the 10-dimensional space-time. The effective dynamics on the world-volume is then described by a p + 1-dimensional field theory.





D-branes represent a key theoretical tool in the understanding of strongly coupled superstring theory and M-theory. They have led to many striking discoveries, including the precise microphysics underlying the thermodynamic behaviour of certain black holes, and remarkable holographic dualities between large-N gauge theories and gravity. This book provides a self-contained introduction to the technology of D-branes, presenting the recent developments and ideas in a pedagogical manner. It is suitable for use as a textbook in graduate courses on modern string theory and theoretical particle physics, and will also be an indispensable reference for seasoned practitioners. The introductory material is developed by first starting with the main features of string theory needed to get rapidly to grips with D-branes, uncovering further aspects while actually working with D-branes. Many advanced applications are covered, with discussions of open problems which could form the basis for new avenues of research


The link below contains over 222 pages, so if you are on Dial-up, you have to think twice about clicking on it. Another of Cosmic Variance's very own.


D-Brane PrimerClifford V. Johnson
Following is a collection of lecture notes on D-branes, which may be used by the reader as preparation for applications to modern research applications such as: the AdS/CFT and other gauge theory/geometry correspondences, Matrix Theory and stringy non-commutative geometry, etc. In attempting to be reasonably self-contained, the notes start from classical point-particles and develop the subject logically (but selectively) through classical strings, quantisation, D-branes, supergravity, superstrings, string duality, including many detailed applications. Selected focus topics feature D-branes as probes of both spacetime and gauge geometry, highlighting the role of world-volume curvature and gauge couplings, with some non-Abelian cases. Other advanced topics which are discussed are the (presently) novel tools of research such as fractional branes, the enhancon mechanism, D(ielectric)-branes and the emergence of the fuzzy/non-commutative sphere.

Sunday, February 12, 2006

Cosmic Variance's Very Own: Strangelets in 10 or 11

Cosmic Variance's very own.

Hewett, Lillie and Rizzo found that if so called micro-black holes, which are smaller than the nucleus of an atom, exist, they can be used to determine the number of extra dimensions. If scientists were to smash two high energy protons together they could theoretically make such a micro-black hole. Such a collision could happen at CERN’s Large Hadron Collider (LHC), which will become operational next year. Once created, the micro-black hole decays quickly and emits over a dozen different kinds of particles such as electrons, neutrinos and photons, which are easy to detect. Using the predicted decay properties of the black hole into neutrinos, Hewett, Lillie and Rizzo solved complex equations to determine if our universe has 10, 11, or more dimensions — perhaps too many dimensions to be explained by critical string theory.


So what is the experiment that is being produced?

Using the predicted decay properties of the black hole into neutrinos,

While I consider the state itself, the thoughts of ICECUBE come to mind. This previous ICECUBE post on this is extremely helpful.

What is also helpful is to remember what the collision process produces and how we can see this process in relation to cosmic collisions. Not just in the colliders themself. While we might of debated the strange matter below, I enlist the idea of the gravitonc considerations and maybe it is not altogether clear, it is with some satisfaction that such thinking of dimensional attributes are actually given parameters with which to work?

Strange Matter (12 Feb 2006)

Some theories suggest that strange matter, unlike neutronium, may be stable outside of the intense pressure that produced it; if this is so, then small substellar pieces of strange stars (sometimes called strangelets) may exist in space in a wide range of sizes all the way down to atomic scales. There is some concern that ordinary matter, upon contacting a strangelet, would be compressed into additional strange matter by its gravity; strangelets would therefore be able to "eat" any ordinary matter they came into contact with, such as planets or stars. This possibility is not considered likely, however.

Strangelets are thought to have a net positive charge, which is neutralized by the presence of degenerate electrons extending slightly beyond the edge of the strangelet, a kind of electron "atmosphere." If a normal matter atomic nucleus encounters a strangelet, it will approach until it begins penetrating this negatively charged atmosphere. At that point it will start to see the positive electrical potential and be repelled from the strangelet. Sufficiently energetic nuclei, or neutrons (which are unaffected by electrical charges), can reach the strangelet and be absorbed; the up/down/strange quark ratio would then readjust by beta decay.


See:
Phases of Matter for Reference

Exotic physics finds black holes could be most 'perfect,' low-viscosity fluid

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.

It is easy to see the difference in viscosity between a jar of honey or molasses at room temperature and a glass of water. The honey is much thicker and more viscous, and it pours very slowly compared with the water.

Using string theory as a measuring tool, Son and colleagues Pavlo Kovtun of the University of California, Santa Barbara, and Andrei Starinets of the Perimeter Institute for Theoretical Physics in Waterloo, Ontario, have found that water is 400 times more viscous than black hole fluid having the same number of particles per cubic inch.


See:

  • Blackhole Creations

  • Strangelets in Cosmic Considerations

  • Cosmic Ray Collisions and Strangelets Produced

  • Microstate Blackhole Production

  • Quark Gluon PLasma II: Strangelets Produced

  • Accretion Disks

  • Strangelets Form Gravitonic Concentrations

  • IN a Viscosity State Production is ?

  • What Are those Quantum Microstates
  • Saturday, February 11, 2006

    History of the Superfluid: New Physics



    Nice Picture above.



    It is really confusing for me sometimes so I have to revisit the set up, to make sure I have things slotted to the way it is being used to penetrate reductionistic views, that help us understand the new physics that emerges from Gold Ion collisions.

    So what is a color glass condensate? According to Einstein's special theory of relativity, when a nucleus travels at near-light (relativistic) speed, it flattens like a pancake in its direction of motion. Also, the high energy of an accelerated nucleus may cause it to spawn a large number of gluons, the particles that hold together its quarks. These factors--relativistic effects and the proliferation of gluons--may transform a spherelike nucleus into a flattened "wall" made mostly of gluons. This wall, 50-1000 times more dense than ordinary nuclei, is the CGC (see Brookhaven page for a letter-by-letter explanation of the CGC's name). How does the gluon glass relate to the much sought quark-gluon plasma? The QGP might get formed when two CGC's collide


    So you say that the particles are supported by the HE4 Superfluid, then how does that energy leak off into the extra dimensions? Hmmmm. As thread unfolds below? What are these strangelets that are catapulted beyond the collider? Porous induced shell casing?

    As well as bringing the accelerator's counter-rotating beams together, LHC insertion magnets also have to separate them after collision. This is the job of dedicated separators, and the US Brookhaven Laboratory is developing superconducting magnets for this purpose. Brookhaven is drawing on its experience of building the Relativistic Heavy Ion Collider (RHIC), which like the LHC is a superconducting machine. Consequently, these magnets will bear a close resemblance to RHIC's main dipoles. Following a prototyping phase, full-scale manufacture has started at Brookhaven and delivery of the first superconducting separator magnets to CERN is foreseen before the end of the year.


    Bose Nova revisited

    I wanted to bring this to the surface again for inspection, as this comes out of the work another fellow and I had discussed at length as we shared perspective on the nature and dynamics geometrically inclined.


    Accretion Disk


    Sometimes, if one does not realized what is governing the thought process, why and how would such things not make some kind of sense. As we move our perceptions ever deeper into the workings of the reductionistic world and find, that these results are being meet in a theoretical sense, as developing well along experimental one too.

    As a layman these views are important to me ,more then the cyncism that pervades the supposed debate on model assumption. While the cynic provides no service other then being that. I have learn to see where the patience and developemental attitude requires a more conducive field of opportunity to bring out the best in each of those scientist that very quickly, the desired approach, is being gone after.

    So herein lies a little history, and the synoptic event that is holding my thoughts today.

    Do the Bosenova

    To set a BEC swirling Ketterle's team shone a rotating laser beam on it while holding it in place with strong magnets. The experiment is like "stroking a ping-pong ball with a feather until it starts spinning," muses Ketterle. The surprising thing was that suddenly, a regular array of whirlpools appeared in the BEC. "It was a breathtaking experience when we saw those vortices," recalls Ketterle. Researchers had seen such whirlpools before (in liquid helium and in BECs) but never so many at once. This array of superfluid whirlpools was exactly the kind of storm system astronomers predicted would swirl beneath the iron crust of a neutron star.

    Evidence for the swirling depths of neutrons stars is based on the fact that some neutron stars are pulsars - the emit a powerful beam of radiation as they spin - like a cosmic lighthouse. The pulses are very regular but occasionally there is a glitch and a pulse might come slightly too early or too late and it is these glitches that are thought to be due to superfluid vortices hammering into the inside of the neutron star's crust.

    Ketterle adds that attractions between atoms in a BEC could parallel the collapse of a neutron star so emulating the distant and massive in the laboratory too. The explosive collapse of a BEC, dubbed a "Bosenova" (pronounced "bose-a-nova") by Wieman releases only a tiny quantity of energy, just enough to raise the temperature of the BEC by 200 billionths of a degree. Supernovae release many times the energy.


    So while I had drawn attention to the process afew years ago that we had discussed, it was important that the very idea of a geometrical process that encompass all the information we currently have, has been filed to specific areas for consideration.

    While the tidbits placed our perspectives all over the map, and held the idealization of the geometry to Feynman's toy models, a greater implication existed that few of realized as we can read about Dirac and the way in which he sees. While I had not been blessed with such a mathematical mind, it seems my vision of things are quite capable, while speaking about reductionistic proceses intuitive roads that lead to the developmental understanding of the nature of the supefuid. A place in which flatspacetime geometry would allow you to consider properties that ask us to explain what this emergent property might be.

    So, if such supersymmetrical idealization was to exist what was this place to say about what began here, or there, in the expression of our universe? Something had to be created that was new to us in our assessment as "new physics." So what was produced? Where did this avenue and funnel allow such an expression that we would look at the bose nova expressing itself, in a model approach.

    Whirling atoms dance into physics textbooks

    Superconductivity is superfluidity for charged particles instead of atoms. High-temperature superconductivity is not fully understood, but the MIT observations open up opportunities to study the microscopic mechanisms behind this phenomenon.

    "Pairing electrons in the same way as our fermionic atoms would result in room-temperature superconductors," Ketterle explained. "It is a long way to go, but room-temperature superconductors would find many real-world applications, from medical diagnostics to energy transport." Superfluid Fermi gas might also help scientists test ideas about other Fermi systems, like spinning neutron stars and the primordial soup of the early universe.


    Historical Perspective
  • Eric Cornell

  • Carl Wieman

  • Wolfgang Ketterle

  • 2001 Nobel Prize in Physics

  • Neutron star

  • M. Coleman Miller




  • Today and the New Physics



    So now that you see that this process is a interesting one, it is necessary to see how such comparative views on a cosmological scale could have been ever immersed in the microperspective.

    This has been my attempt at bringing the place for persepctve into line so that such "new physics" woud have captured the layman's mind. Found the seed bed for new maths, to have created a visionary world that could have arisen from this point on the brane, that such circles, had a greater meaning then one could have ever realized.

    What was happening outside of our colliders that we could speak to what was happening inside of the colliders? This is amazing story, as we now see that events happening with high energy particles, have made themself known in our immediate envirnment to have said what can exist here now in such weak field manifestations, that we had graduated from the normal gravity wave perception GR lead us from, and sent us too?

    Many Holes?

    So now that a cosmological event has captured our mind, the big bang taken us to the first microseconds of our universe, the supersymmetrical view realized, what say we see the possiblility in those new bubbles that arise from Dirac's Sea?

    Each hole while existing within the frame work of a supefluid state madeit possible for us to realize that such expressions would have happen at such micro levels that we had been thinking about how we send our measures to such levels? The new physics is what had been strange to our normal way of thinking and now?

    It would have been my hope that bringing five different people together in the Cosmic Variance scheme of things, would have created the perfect group, as to bringing persepctive and varied opinion together in perception into the family and said how nice that these different perspectives were really one aspect of the whole picture?

    Thursday, February 09, 2006

    Warm Dark Matter

    Having a global perspective using the cyclical model, seem to open some of the ideas about the nature and geometry of this universe as mentioned in article below.

    I have been watching since the earlier days of the jamming session on the train, where individuals who seem to get together, seem to produce this amazing idea in just a short span of time.

    Reference to Aaron's article linked of Steinhardts

    For most astronomical observations the simplest possible choice seems to give an adequate description: the dark matter is primarily made up of elementary particles which are long-lived, cold and collisionless and has been termed cold dark matter. The most direct way to see if this choice is correct is via earth based laboratory particle detectors and several experiments are underway.


    Well what was troubling to me then, was that if you had a age to the universe, let's say 13.7 billion years, then while some like Lubos might refer to Andy Stromingers blackhole issue and living in it, I was somewhat puzzle in ascertions about this geometry and cyclcial nature, that such a idealization could exist in parts of our universe.

    Andy's public lecture

    Lubos Motl:
    Andy answered many questions and some of them have been very frequent questions that follow many similar talks. What is a string made of (nothing else), is it made of matter (no, you would get an F), is it made of waves of space (no), was the Big Bang a black hole (if it were, we are still in it), what can string theory say about the origin of the Universe (not much so far), and so forth


    What events in galaxy formation could be taken back to that beginning, yet the ideal state of affiars held to a flat space time considered and slowing expansive rates of expression? Show relationship to over all nature of this universe in action. Would it not conflict with arrow of time in it's expression, to know that such galaxy formations woud take us back to the birth of this universe?

    What made this equally complicated was that no event in this cosmos, could be older then the 13.7 billions years, yet, we see in nucleosythesis processes, we can do this in our ascertion of of what happened in the first microseconds of this universe? It would mean, no event can be older than?

    If you have a global persepctive on universe cyclical operations, then where are the places that take us to the origins of nucleosysthesis processes (Geometrical inclusion of our own universe)in all galaxy formations? Blackholes?:)

    It would mean all comparative examples of such galaxies would then never be older then the age of the universe, and we run into trouble with the arrow of time?

    Or, can any event that we take to the age of the universe, be a natural process?

    Wednesday, February 08, 2006

    The Lowest Octave State

    Sometimes simple concepts, like something representing the lowest vibration mode of the string, the lowest octave helps in a sense helps to orientate what the particles mean, such as protons,neutrons and electrons. Where they exist now as they cosmic collsions meet and dissapte it's influence in our atmospheres, our planet.

    Yet Moshe speaking about sparticles has interesting relations in context of symmetry breaking, yet, without thinking about what experiments are now being listed, what value this lowest vibration mode? What value that leads us to think about this lower scale as evidence now held within our views.

    Clifford:
    We’ve got to remember what we assumed in order to get to the cirtical dimensions, and then revisit those assumptions every time we learn something new about the whole story


    Would be a consistent pattern, when new options and experimental consideration are introduced. In the case I listed above in ICECUBE.

    The relative 'up' and 'down' rates provide evidence for distortions in neutrino properties that are predicted by new theories."


    I think this would be consistent on the level of what you are saying Clifford? Lay people like myself would understand this I think. While very aware of the higher energy considerations in context of reductionism, had taken us too dual blackhole considerations within the collisions taking place not just in the colliders.

    It presented opportunites in how we see what strings might have emplied in Cerenkov radiation? What is it that we should see in this relation, that strings would have said here is another opportunity?

    Cerenkov Radiation and the Blue Glow

    At full power (200 kilowatts), the UMR Reactor core produces approximately 6.4 trillion fissions per second. Each fission event liberates a tremendous amount of energy, a portion of which is carried away by fission products which then decay and produce high-energy beta particles. Often, these beta particles are emitted with such high kinetic energies that their velocities exceed the speed of light (3.0x108 meters per second) in water. When this occurs, photons, seen to the eye as blue light, are emitted and the reactor core "glows" blue.

    While no particle can exceed the speed of light in a vacuum, it is possible for particles to travel faster than light in certain mediums, such as water. The speed of light in a particular medium, v, is related to the speed of light in a vacuum, c, by the index of refraction, n, by v = c/n. Water has an index of refraction of 1.3, thus the speed of light in water is 2.3x108 meters per second. Therefore, beta particles with kinetic energies of 0.26 MeV travel at speeds in excess of 230 million m/s!


    It is important to remember somethings here. I am trying to hone in on the exact reasons for this idealization, to see in the ways that we do. Why the sky is blue in relation to the sun that shines and the Earth as it is ?:) How often has the child asked, while we had been witness to the very thing in our everyday waking lives.

    Thus we are quickly transported into the strange world of refractve indexes and such, as examples of what angle and departures these particle might take in their collisions courses. Yet we know as we look up that beyond the blue, it gets dark again Redshifting on the horizons as our sun sets.

    Cosmological particles exsit that are free of our atmosphere. What say these things in that environ, while it is dark? What shall we say of these things when the sun influences dances on our outer atmosphere?

    Wikipedia and the Uses of Cerenkov Radiation(8 Feb 2006)

    When a high-energy cosmic ray interacts with the Earth's atmosphere, it may produce an electron-positron pair with enormous velocities. The Cherenkov radiation from these charged particles is used to determine the source and intensity of the cosmic ray, which is used for example in the Imaging Atmospheric Cherenkov Technique (IACT), by experiments such as H.E.S.S. and MAGIC. Similar methods are used in very large neutrino detectors, such as the Super-Kamiokande.


    So I am again drawn back to the state of the earth's gravitational field, with which this planet being weak, lets us see particle states that it does? How shall I keep in mind, that such circumstance free of refractive indexes( a vacuum)speed of light wil mett the chance to have faster then light capabilties, in a blue glow? Have I then nailed the reasons why such concepetualization take to the two extrmes of what vison had garnered for us, and the circles meaningwhile it signfied this interchangeability?

    Ah, my more layman head. :)Like a Koan supplied to tax the mind, a simple statement is drawn out, over and over again, while in time, the mind becomes flooded with so many possibilities with a flash of light. What is this Koan, that I speak of?

    Brian Greene:
    How can a six-foot tall human being 'fit' inside such an unbelievably microscopic universe? How can a speck of a universe be physically identical to the great expanse we view in the heavens above


    Don't worry Clifford, while Brian Greene might have been the spokesperson for all scientist actors, it is still with some benefit that we undertand how the abstract mind releases itself, but for a short time. While the influence of nature has its way with us. Whilst we had been so intensely looking, the break from the work, allowed the culmination to seep through in a simple jesture of understanding. That seems to be the way of it.

    Tuesday, February 07, 2006

    Evidence for Extra Dimensions and IceCube

    ...the creative principle resides in mathematics. In a certain sense therefore, I hold it true that pure thought can grasp reality, as the ancients dreamed.
    Albert Einstein

    Sometimes if we paid attention enough, the neurons seem to fire appropriately and the detachment of the ideas seemingly distant from one another, become illuminated and connected? Imagine it taking place in Clifford's other office.

    Foundations Study Guide: Philosophy of Mathematics by David S. Ross, Ph.D.

    The philosophy of mathematics is the philosophical study of the concepts and methods of mathematics. It is concerned with the nature of numbers, geometric objects, and other mathematical concepts; it is concerned with their cognitive origins and with their application to reality. It addresses the validation of methods of mathematical inference. In particular, it deals with the logical problems associated with mathematical infinitude.

    Among the sciences, mathematics has a unique relation to philosophy. Since antiquity, philosophers have envied it as the model of logical perfection, because of the clarity of its concepts and the certainty of its conclusions, and have therefore devoted much effort to explaining the nature of mathematics.


    Such a cognitive fucntion then would be important as these math symbols arose in our minds. Possible new mathematical models in which to describe the nature we see around us. So one makes sure they have a pad and pencil, while they ventured away from the regime, with which the mind has been so intensely engaged?

    Now being so far from the understanding of these mathematics, I can only hope to understand the concepts as they unfold in a geometrical insight, while I try to make sure I understand them in relation to abstract thinking.

    SNO on the go – at last!


    Over the past 30 years, five different experiments have sought to measure the flux of these elusive particles from the Sun (produced by the same nuclear processes that make it shine) and have consistently come up short of theoretical predictions. One explanation is that the neutrinos emitted ‘oscillate’ into another variety of neutrino which past experiments could not detect.


    Within the IceCube collaboration the Univ. of Uppsala and the Univ. of Berkeley have joined the DESY initiative. The DESY team is also in close contact to the groups in Europe, the USA and Asia which are working on acoustic detectors for Neutrino-Telescopes installed in water. Details on the different projects have been presented on the First Workshop on Acoustic Cosmic Ray and Neutrino Detection held at Stanford in September 2003.




    The muon will travel faster than light in the ice (but of course still slower than the speed of light in vacuum), thereby producing a shock wave of light, called Cerenkov radiation. This light is detected by the photomultipliers, and the trace of the neutrinos can be reconstructed with an accuracy of a couple of degrees. Thus the direction of the incoming neutrino and hence the location of the neutrino source can be pinpointed. A simulation of a muon travelling through AMANDA is shown here (1.5 MB).


    Some understanding of the dual nature of blackholes is needed here in order to understand what is "produced" and how this is "spread out."

    "String theory and other possibilities can distort the relative numbers of 'down' and 'up' neutrinos," said Jonathan Feng, associate professor in the Department of Physics and Astronomy at UC Irvine. "For example, extra dimensions may cause neutrinos to create microscopic black holes, which instantly evaporate and create spectacular showers of particles in the Earth's atmosphere and in the Antarctic ice cap. This increases the number of 'down' neutrinos detected. At the same time, the creation of black holes causes 'up' neutrinos to be caught in the Earth's crust, reducing the number of 'up' neutrinos. The relative 'up' and 'down' rates provide evidence for distortions in neutrino properties that are predicted by new theories."





    Before engaging article below it is important that the differences be noted between strangelets(strange quarks), and the distortions in neutrino properties. If it is understood the microstate blackholes are created, then the dispersion of other particle in the atmosphere give us indications and consequences gained from dual nature of the blackhole.

    I am confused here, and this point of interactive consideration is holding my mind as to why both these situations together are important. The difficulty may come from from the immediate association, while reocgnition of these two have been raised from the event and collision.

    Earth punctured by tiny cosmic missilesBy Robert Matthews, Science Correspondent
    (Filed: 12/05/2002)

    Strangelets - sometimes also called strange-quark nuggets - are predicted to have many unusual properties, including a density about ten million million times greater than lead. Just a single pollen-size fragment is believed to weigh several tons.

    They are thought to be extremely stable, travelling through the galaxy at speeds of about a million miles per hour. Until now, all attempts to detect them have failed. A team of American scientists believes, however, that it may have found the first hard evidence for the existence of strangelets, after scouring earthquake records for signs of their impact with Earth.



    See:

  • Cosmic Ray Collisions and Strangelets Produced
  • Strange Abstract Movements

    When one is engaged in the strange world of the abstract, Quark to Quark measures left me in a strange state. Lines having been given values in distance. That were not readily available to the eye. These lines are happening in spaces, that give "energy values" to that every distance? Gausssian coordinates. The metric.


    The Clebsch Diagonal Cubic Surface. It is smooth and all its different 27 lines are real. There are 10 so-called Eckardt points, i.e. points in which three of the lines meet.


    So this is a preview to me while working in these abstract spaces, I wanted to make sense of it all, and how such expressions that arise in the standard model, had some framework in which it can follow.




    Dürer Magic Square with Lines


    A new perspective hidden in the Prof.dr R.H. Dijkgraaf second rendition, and thesis image, reveals a question mark of some significance?:) So how would we see the standard model in some "new context" once gravity is joined with some fifth dimensional view?


    What gravity would imply if all dimensional relations are introduced to the entropic models of matter states, while this energy valuation to determination, using information gathered are forcing us to see in ways in regards to those same energy density states?

    So you look for these things, in model approaches like, the first three minutes of Steven Weinberg's or even further yet into model approaches given here.


    Big Bang Nucleosynthesis Edward L. Wright



    OKay. So You Say the Beginning


    As can be seen from the curves, at the higher temperatures only neutrons and protons exist, with there being more protons than neutrons. But, as the temperature decreases, there is an increase in the amount of deuterium and helium nuclei. Just below 1 billion degrees there is a significant increase in deuterium and helium, and a decrease in the abundance of protons and neutrons. This is the deuterium "bottleneck" mentioned previously. This uses up the all the free neutrons and some protons, and causes the neutron line to drop off, and the proton line to dip (relatively few protons are used up). The deuterium abundance only increases to a point because it is an intermediate to the formation of helium. So as it is created, it is quickly consumed to complete the process of helium nucleosynthesis. Once all the neutrons have been used up, its presence drops off.


    So while you are intrigued by this beginning, something happens that confronts the rational, of how you ever got to this point. Does it matter? I think it does, and if you to are ever to conlucde this assertion of a cyclial nature, you need foundational perspective that helps recognize why string theorist's abhor infinities. What the heck do they mean?


    In fact, the temperatures and densities reached in these collisions are similar to those found in the early universe a few microseconds after the Big Bang.


    So how much closer can you be taken to the beginning? You need an overview for this cyclical nature to make sense of it.

    Monday, February 06, 2006

    My Attempt at Playwriting?

    It's nice we have somebody to keep a tight reign on the transmissions of science in the media? :) I was thinking of those who collaborations are used when developing movie scenarios. "Brian Greene" playing himself on Frequency.

    You played yourself--twice--in the movie, "Frequency". The movie is about a father communicating from 1969 with his son in the present on a ham radio, due to an unusual atmospheric aurora that bounces radio signals across time, not just space. You played Brian Greene being interviewed by Dick Cavett as both a younger and older man. Any reflections on either the interesting premise of the movie, or the adventures of being on the big screen?



    I couldn't help think of

    as an example of Humble Boy by Charlottle Jones?

    In regards to "bumblebee wing rotations." This is my italicized bumbling attempt :( How a waiter with a tray could make a complete loop(bumblebees finding the quickest route while hovering or travelling), so how was it employed in this play(something about bee keeping, but not my version)?

    Here's my attempt.

    I'm Dressed up in a bumblebee suit waiting tables. While working I change my striped waiter vest completely inside out without it leaving my body? Qui Non!

    As the science meme continues, the story unfolds:

    Confused and lost in the abstract world, the waiter mistakenly puts on the suit not realizing he was not to take it so literal. The differentiation between the waking reality, and the one in which he was transported, was a psychological cover to mask the real events going on in his dream life.

    Letting loose the masking and not retaining funtionability with his reality sense based recognitions, he slipped easily over the edge?

    Alien transportation had occurred, and induced psychological dramas did not sway the determination of a mind that had venture into unfamiliar territory. The edge, was what was the limit of the people in the resturaunt, while the waiter, thought his actions normal. :)

    In another scene Alien abductors, are left scratching their heads as to how model implants had been been foiled and taken so literal, when it was realized the waiter had already be abducted once before, and meme introduction had been superimposed over a previous attempt to included natural symbolic functions.

    White Owl and the Bee clashed leaving the poor waiter in a state of actions less then correct while dawning hs suit.

    On Humble Boy

    I have not seen the play of Humble Boy, but the thought about plays was held in my thinking yesterday as Clifford talked about Nature.

    So maybe that's the trick then? Read out loud/sound what you've written, brings dimensionality to the written word?:)

    Humble Boy "Links" Borrowed:

  • National Theatre production
  • Manhattan Theatre Club production
  • Interview at Floreat Domus
  • Article in the Daily Telegraph
  • Article in Playbill
  • Article in Physics Today

    Reviews:

  • The British Theatre Guide
  • CurtainUp
  • Daily Telegraph
  • Financial Times
  • The Guardian (1)
  • The Guardian (2)
  • Amanda Hodges
  • Humbug's Guide to London Theatre
  • The Independent (scroll down for review)
  • Tom Keatinge
  • New York
  • The Observer (1)
  • The Observer (2)
  • Online Review London
  • Talkin' Broadway
  • Vengatoro
  • The Village Voice

    Charlotte Jones:

  • Profile at The Guardian
  • Charlotte Jones
  • Sunday, February 05, 2006

    Phase Transitions

    While I am reading the discussion on cosmicvariance posted by Sean, Why 10 or 11?,I am struggling to see in ways that a lot of us are not accustom too. So for every way that is being presented for the layman, the struggle is to undertsand the relatinship to dimensional perspectve as shared by those who are speaking and clarifying.

    What is held in the mind of one who would encompass all this from a event like the Gold Ion collision process, setting the stage for a comprehensive view, being talked about there?

    I struggle.

    While reading this, this is ole news, but if you hold it in context of what is being talked about in the abstract terms about "what began in the beginning," such associations are important for me as I delve into what is making sense and what isn't.

    Earlier such a schematic revealled to us in earlier cosmolgical thinking/linking from the time from the big bang, would be ripe for associative analogies, to help push perspective? Well, it does for me. Of course, I am going beyond Steven Weinberg's first three minutes.

    Understanding the nature of matter requires knowing the boundary between its different phases, and how it changes from one phase to another. For example, imagine trying to understand the nature of water without knowing that under the right conditions it can be transformed into ice or steam. To understand the nature of atomic nuclei, scientists have long treated the nuclei as tiny drops of liquid, for which the physical properties and behaviors have been well-characterized
    .

    Thursday, February 02, 2006

    Time

    You need a "Axion point" to derive symmetry breaking from equilibrium? Hmmmmm..... I'm thinking here.

    The idea is taking the first three minutes and moving it to the first three seconds and that's where strings come in...

    I must warn you though, that the model of superstrngs is facing strong opposition today because is does not have the scienctific proof and validation that any model should have. On this basis alone ,it is being challenged.

    One must remember though, that it has a strong theoretcial structure that will remain incomprehensible to most, to me, that I have only the faintest ideas as to the complexity of the math structures.

    Part of this insight is to take macroscopic views and have them reduced to microperspective views while looking about the every structure of this universe. So they use the LHC/RhIC reference for analogies as to what happens in those very beginnings.

    The overcoming incompatibility relationship between quantum mechanics and relativity has been the goal, and in this theoretcial structure, this has been accomplished.

    Brian Greene

    Time is far more subtle than our everyday experience would lead us to believe. In many ways, time may simply be a psychological construct for organizing the world. It is a device we scientists have found useful, but it may in fact be a dim approximation of something far more complex."


    Einstein in his bold statements about a pretty girl helped to direct our attention to the fleeting moments. It was last years tribute to Einstein and Beyond that helped many in dfferent perspectves and of time bring us back to what this man did for us.

    Kaluza and Klein helped to push this perspective further. Some debate this model as well, yet I do not know many who have advnaced our thinking from the geometrical inclinations as Einstein did for us when he attributed time to the spacetime realization of what Gravity does for us.

    The spacetime fabric became something more then the very impression that mass would reveal of itself. Energy, had a relationship in this, and yet, we are drawn to the very implication of where two diffwerent points could have ever told us that spacetime is flat. Where is this? I have given three cases where this is possible, and I have given theoretical valuation to what strings have done for us, in our microscopic view of this universe.

    You had to follow strings through the theoretcical developement assigned, in or colliders. What was the result of microstate blackhole production? HE4 or lagrange points between the earth, moon and sun?



    You had to know what theoretical associations had been marrried to scientific progress. If you have somebody who denounces and rejects the model how would you have ever thought to unite flat space, with reality models?

    This is the interesting thing about choosing models, is that experimental processes are not as devoid as those whose main goal was to affront string theory, was to announce this renunciation without ever understanding it's implications.



    Setting up such a wall(Peter Woit) was a disservice to those who wanted to explore this theoretical structure. It's implications, as to the first three seconds of our universe. Steven Weinberg laid it out for us in the first three minutes, why not a more introspective view in the consequences of this universe borne to what it is?