Tagged: Physics

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February 1st, 2010

Differentiantion of 1-forms

In General Relativity, which relies on differential geometry and tensor calculus, a quick way to do coordinate free calculus is to use differential forms. A differential k-form, that is a form of degree k, is a smooth section of the k-th exterior power of the cotangent bundle of a smooth manifold M.

As examples, a differential 0-form is a smooth function on M, where a differential 1-form is the dual to a vector field on M. If we let U be an open set on \mathbb{R}^n, then there exists some smooth function f on U, which we define to be the differential 0-form. Given a vector field v on \mathbb{R}^n, for each v, there exists a directional derivative \partial_v f, which is the directional derivative in the usual sense, that is, if v=e_j is the jth coordinate vector then \partial_v f is the partial derivative of f with respect to the jth coordinate function

By their very definition, partial derivatives depend upon the choice of coordinates: Given two coordinate systems x^n and y^n, the transform between them is simply:

\frac{\partial f}{\partial x^j} = \sum_{i=1}^n\frac{\partial y^i}{\partial x^j}\frac{\partial f}{\partial y^i}

Since any vector v is a linear combination \sum v^j e_j of its components, df is uniquely determined by d_f p(e^j) for each j and each p\in U, which are just the partial derivatives of f on U. Since the coordinates x^n are themselves functions on U, and so define differential 1-forms dx^n. Since \frac{\partial x^i}{\partial x^j} = \delta^{i}_{j}, the Kronecker delta function, it follows that

df = \sum_{i=1}^n \frac{\partial f}{\partial x^i} dx^i.

The meaning of this expression is given by evaluating both sides at an arbitrary point p: on the right hand side, the sum is defined “pointwise”, so that

d f_p = \sum_{i=1}^n \frac{\partial f}{\partial x^i}(p) (dx^i)_p.

Remember, since f is an arbitrary smooth function on the dual manifold, we can define, and use, it pointwise. More generally, for any smooth functions g_i and h_i on U, we define the differential 1-form \alpha = \sum_1 g_i dh^i pointwise by coordinates as \alpha = \sum_{i=1}^n f_i d x^i for some smooth functions f_i on U.

The second idea leading to differential forms arises from the following question: given a differential 1-form \alpha on U, when does there exist a function f on U such that \alpha = df? The above expansion reduces this question to the search for a function f whose partial derivatives \frac{\partial f}{\partial x^i} are equal to n given functions f_i. For n>1, such a function does not always exist: any smooth function f satisfies \frac{\partial^2 f}{\partial x^i \partial x^j} = \frac{\partial^2 f}{\partial x^j \partial x^i}

so it will be impossible to find such an f unless \frac{\partial f_j}{\partial x^i} - \frac{\partial f_i}{\partial x^j}=0 \forall i,j.

The skew-symmetry of the left hand side in i and j suggests introducing an antisymmetric product on differential 1-forms, the wedge product, so that these equations can be combined into a single condition \sum_{i,j=1}^n \frac{\partial f_j}{\partial x^i} dx^i \wedge dx^j = 0

where dx^i \wedge dx^j = -dx^j \wedge dx^i.

This is an example of a differential 2-form: the exterior derivative d\alpha of [/latex]\alpha= \sum_j=f_j dx^j[/latex] is given by d\alpha = \sum_{j=1}^n d f_j \wedge dx^j = \sum_{i,j=1}^n \frac{\partial f_j}{\partial x^i} dx^i \wedge dx^j.

Differential forms can be multiplied together using the wedge product, and for any differential k-form α, there is a differential (k+1)-form dα called the exterior derivative of α.

Thus, I hope to have convinced you that differential forms, the wedge product and the exterior derivative are independent of a choice of coordinates. Consequently they may be defined on any smooth manifold M. If this makes you uncomfortable, you can reintroduce coordinates. One way to do this is cover M with coordinate charts and define a differential k-form on M to be a a family of differential k-forms on each chart which agree on the overlaps. However, there are more intrinsic (read: modern) definitions which make the independence of coordinates manifest. See the modern idea of tensors for a good idea what coordinate free geometry can do, and the intrinsic power of dealing with objects in a coordinate free space.

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January 18th, 2010

Brief History of Particle Discoveries

Like all good physics programs, particle physics has kept several different generations of physicists employed. To remain employed, one must succumb to the publish or perish disease currently infesting physics. And of course, to publish, one must discover.

Here, I present a list of particles discovered by physicists, along with some useful information about the particles. This list is not intended to be exhaustive, as there are more particles in nature than useful politicians in Congress. One thing to note is that I only discuss the list of elementary particles discovered, to list all the baryons and mesons made from them is going to have to wait for another blog post.

Particle Year Mass (MeV/c2) Spin Antiparticle Comments
Electron 1897 0.511 1/2 Positron Also known as beta ray
Alpha particle 1899 big 0 anti-helium A doubly ionized Helium nucleus
Photon 1900 0 1 self 1
Proton 1919 938.272 1/2 anti-proton
Neutron 1932 939.566 1/2 anti-neutron
Anti-electron 1932 0.511 1/2 electron 2
Muon 1937 105.7 1/2 anti-muon 3
Pion 1947 134.98 0 Self Predicted in 1935 by Yukawa
Kaon 1947 497.65 0 Self First strange particle discovered
Anti-proton 1955 938.272 1/2 Proton
Electron neutrino 1956 under 2.2×10-6 0 Anti-electron neutrino 4
Up, Down, and Strange Quark 1969 1.5, 3.5, and 70 1/2 for all Anti-up, anti-down, anti-strange Deep elastic scattering in protons led to this discovery
J/Psi meson 1974 3096.916 1 self Showed existence of charm quark
Upsilon meson 1977 9460 1 self 5
Gluons 1979 0 1 self Gluons mediate strong force, and confine quarks.
W and Z bosons 1983 8039.8 (2.3), 9118.76 (21) 1 self Mediate weak force. W bosons violate parity.
Top quark 1995 1731 (13) 1/2 top antiquark 6

Footnotes

  • 1 Also known as gamma radiation, it was originally discovered in 1895 as X-rays, but was only successfully identified as electromagnetic radiation in 1900.
  • 2 Dirac’s relativistic quantum equation predicted this particle would appear, and have the same mass as the electron, but opposite charge. Dirac reasoned it was actually the proton it was predicting, however, the anti-electron was found experimentally in 1932. Despite not predicting it, Dirac still shared in the Nobel prize awarded for its discovery.
  • 3 With a long half-life, the muon can form chemical bonds in atoms.
  • 4 The neutrino was proposed by Wolfgang Pauli in 1931 to save the idea of conservation of energy, one of the most fundamental tenents in physics. During beta decay, it was found that some energy was escaping in an unknown form, so Pauli proposed the neutrino, an unknown particle with no mass and no charge, but containing energy. Neils Bohr favored the idea of getting rid of the conservation of energy instead. Luckily for physics, the neutrino was found, allowing us to keep the conservation of energy intact.
  • 5 Showed bottom quark properties. Feynman immediately predicted top quark existed.
  • 6 This particle is heavier than gold, and the last discovered quark. Some beyond-the-standard-model models predict a fourth generation of quarks, but none have been discovered.

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December 27th, 2009

Molecular transistors

From Wired comes a story about a multi-national team that has finally developed a single molecular transistor. The transistor, a benzene molecule attached to two gold atoms can behave just like a more common silicon/ silicon oxide transistor.

By varying the voltages across the benzene molecule, one can control the energies available for access by the electrons in the molecule.

In Chemical Engineering, benzene, a cyclic aromatic hydrocarbon with a continuous pi bond is capable of being treated as a quantum well. The amount of hydrogen in the chemical structure, C6H6, along with the pi bond, allow electrons to flow easily, along with the formation of carbon-carbon double bonds. For images of the benzoic structure, I will refer you to Wikipedia. As for the small size of benzene, one only need to consider the benzene molecule as a finite three dimensional quantum well and compute the wavefunction leakage from the sides of the well.

The paper is detailed in the December 24th issue of Nature.

This single molecule transistor comes on the heels of last years announcement of a ten molecule graphene transistor. Due to the ease of securing benzene, as well as the difficulty of manufacturing defect free graphene, I am of the opinion that the clunky graphene transistors are already obsolete.

It should be noted, that due to the restrictions of quantum physics, Si/SiOx transistors are at a minimum thirty-two atoms thick, and current manufacturing limits are a hundred-fold larger, at thirty-two nanometers wide.

The use of molecular transistors will lead to the development of larger, and more capable computers, which will require more advanced technology to replace the (soon to be) clunky molecular valves. I only wish it was Bell Labs that was working on this, as they had first discovered the transistor.

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December 21st, 2009

Silly Physics Tricks

Here is a Youtube video of some silly party tricks one can perform to amuse and delight their guests, friends, and random strangers. Enjoy!

And a Link to the good Dr’s. blog. Go check him out, as he has quite a few videos up, and a lot of good information.

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December 20th, 2009

Musical Universe Supplimental Podcast 2

Hello again, and welcome!

I have here another Supplimental Podcast for my radio show, Musical Universe. Musical Universe is a live internet radio show done every Sunday night on riverfrontradio.com, from 9pm to 11pm CST. (UDT -6) The show is about Astronomy, Astrophysics, Space science, Science in general, Educational Science, and Astrophysical Engineering.

The show, much like this podcast, is done with no script, and in one take. The podcast is five and a half minutes long, and I do apologize about the sudden change in sound quality about a minute in. It gets better. I hope you enjoy the podcast!

If you cannot see a music player, make sure that riverfrontradio.com is not blocked at your location.

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December 10th, 2009

New Hubble HUDF

The Hubble Ultra Deep Field 2009 is a four day exposure of the Hubble Ultra Deep Field of 2004, which was an eleven day picture of a starless, apparently empty region of space 1/15th the size of the (full) moon. Of course, when the picture was developed, it turned out that the empty region of space was not so empty after all.

Click to see the picture. The link leads to the HubbleSite page, where you can view the picture at a resolution of your liking.

A couple of beautiful things I would like to note. In the upper left corner, we find a diffracted star (the white object with a red, green, and blue halo, and crossbeams through it). Near this star, we find a diffracted red object, which looks like a star, but is slightly pinkish. This is a quasar, a black hole eating matter and spewing out energy. To the right of the quasar, we find a deeply red dot with no discernible shape. This is a very early galaxy, with an age of thirteen billion years or more. Up, and to the left of the diffracted star, we see a spiral galaxy with only one massive arm, indicating a new galaxy that has recently undergone an interaction with a massive object.

In the top center of the image, we find not one, but two pairs of interacting galaxies. As we move to the right from our galaxies, we find lots of blue streaks. These streaks are clusters of hot, massive stars forming in galaxies that are too dim to see. The stars are so hot, bright, and massive, they drowned out the light from the rest of the galaxy, forcing us to guess at their shape.

Almost dead center in the image, we see a stunning, well formed barred spiral. Contrast this to the still forming, dim spirals nearby. Our barred spiral appears to be a recent galaxy, at least by the pictures standards.

I don’t see any Einstein’s rings yet, but I will keep looking. An Einstein’s ring in an image this old will not only provide a deep look into the very beginnings of galaxies at the beginning of galactic formation, but it may also provide a peek at matter distribution beyond our Hubble Volume.

Pictures in a later post.



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December 2nd, 2009

LHC to 1.18TeV

Straight from CERN’s press station, comes a report that the LHC (Large Hadron Collider) has become the most powerful particle accelerator man has ever built. Just ten days after turning on the LHC, and seven after the first collisions, the juice was cranked up to 1.18 TeV per beam, just over 1/7th the total power available. Next on the agenda is increasing the beam density, then lots of troubleshooting and planning, as the hope is to start going at 3.5 TeV per beam early next year.

On Usenet, the crazies are going full steam, predicting that the LHC will kill us all with their super powerful beams, CERN is powered by atoms that go around in circles without radii, and other such nonsense. As bad as it is now, I have a feeling that it will get far worse when the beams are cranked up, and real physics begins in earnest.

You can find the full CERN press release here.

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Other physicists talk about the LHC powerup.

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November 30th, 2009

A bucketfull of AWESOME!

The Royal Society of England has decided to put some of their most influential or groundbreaking papers up online at http://trailblazing.royalsociety.org/.

Their selected papers include papers by Sir Issac Newton,
Antonie van Leeuwenhoek, Benjamin Franklin, Edward Stone, Bayes, James Watt, James Cook, Young, Herschel, Joule, Maxwell, Rutherford, Fisher, Dirac, and many, many more.

The Royal Society (full name: The Royal Society of London for the Improvement of Natural Knowledge) was founded in 1660, and in over three and a half centuries has become a major force in science, both in funding, and publishing. The Royal Society publishes several journals, including my favorites, the Proceedings of the Royal Society, as well as the world’s longest running scientific journal, Philosophical Transactions of the Royal Society (first published 6 March 1665). For funding opportunities, I urge you to examine other sources, as I have no information.

The Trailblazing site allows you to download the papers, either singly, or by genre. if you have never read a scientific paper, I urge you to grab one, and take a look. For an exceptionally beautiful paper, I recommend This paper by Crick and Watson. It is a masterpiece, beautifully written, and elegant in the science. I once read on the Nature website that this paper was considered so obviously correct by the editor that it was immediately published, and thus made it as one of the handful of modern scientific papers that were published in a reputable journal without peer review.



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November 27th, 2009

Musical Universe Supplimental Podcast

Musical Universe is my Astronomy and Astrophysics internet radio show every Sunday night from 9pm to 11pm CST. (UDT -6)

Since I have been sick recently, I decided to produce a series of supplemental podcasts to replace the missing shows. Here is the first one, produced with no editing, and no script, just like the show.

Some small notes: In the podcast I make the comment “my friend Caolinn O’Connell”. She isn’t really a friend, more of an acquaintance, I do know of her work from a blog she had back in 2005. I apologize for the low volume of the piece, I can’t really speak at full power yet. it strains my throat too much.

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November 26th, 2009

Japanese Neutrino Experiment T2K

From Astronomy.com and Symmetry Breaking, comes the next chapter in Japanese neutrino physics, the Tokai-to-Kamioka (T2K) experiment.

T2K is a neutrino beam generated by a particle accelerator directed at a target clear across the country of Japan, and the target, fourteen iron and scintillation boxes designed to pick up the neutrinos. The neutrinos are generated by a 30 GeV proton beam slamming into a carbon target to produce a short lived particle called pions. The pions decay while travelling through a helium filled space, producing neutrinos. Charged pions decay via the weak interaction (W^{+}) to form a muon and a muon neutrino. The muon then decays to a positron, electron neutrino, and a muon antineutrino.

\pi^+ \rightarrow \mu^+ + \nu_\mu and \mu^+ \rightarrow e^+ + \nu_e + \bar{\nu}_\mu

Thus, the majority of our neutrinos are expected to be muon neutrinos, alongside their antineutrino counterparts, assuming we start with positively charged pions. Since neutrinos oscillate between their three flavors, some of the neutrinos are expected to change into other neutrino forms, while their antineutrino counterparts change into other antineutrino forms. The differences between the amount of neutrino and antineutrino oscillations will help narrow down the differences between matter and antimatter.

From their press release comes evidence that T2K has had three neutrino hits, in line with expectations. Indeed, you can see one of the hits directly here. I look forward to seeing what kind of useful physics comes out of this experiment, since antimatter and matter differ on a fundamental level, and this experiment will root out some of those deep differences with fundamental particles. Since we are dealing with neutrinos, it will also help identify physics beyond the standard model, our current best theory for dealing with particle physics.



Reading the press release carefully, one will note that Symmetry Breaking has copied the press release verbatim, a kind of dick move on their part. Not the worst thing they could have done, since they at least attribute the press release, and link it, but they could have at least given their analysis on it. Your thoughts?

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Posted in Astrophysics, Particle Physics, Physics | 1 Comment »

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