Tuesday, May 31, 2011

CENTRAL INSTITUTE OF PLASTIC ENGINEERING-MTECH

CENTRAL INSTITUTE OF PLASTIC ENGINEERING TECHNOLOGY INVITED APPLICATION FOR MTECH-PE/PT,POLYMER NANO TECHNOLOGY,ME CAD/CAM MSC-TECH COURSES.LAST DATE TO SUBMIT APPLICATION IS JUNE 24th.ENTRANCE EXAM WILL BE ON JULY 17TH.FOR MORE DETAILS VISIT www.cipet.gov.in

Monday, May 30, 2011

PG/UG ADMISSION KANNUR UNIVERSITY,KERALA 2012-13

KANNUR UNIVERSITY INVITED APPLICATION FOR ADMISSION IN VARIOUS UG/PG/MPHIL COURCES IN ITS TEACHING DEPARTMENTS . COURSES INCLUDING MEDICAL BIO CHEMISTRY,MICRO BIOLOGY,BIO CHEMISTRY,MEDICAL LABORATORY TECHNOLOGY,BIO TECHNOLOGY,COMPUTER SCIENCE,MATHEMATICS,STATITICS,PHYSICS,CHEMISTRY,GEOGRAPHY,ENVIRONMENTAL SCIENCE,CLINICAL AND COUNCELLING,PSYCHOLOGY,MA,MSC,MCA,LLM ETC
LAST DATE TO APPLY IS 23-6-12

Application forms for admission to the courses offered will be issued from 23.05.2012 onwards. 
Filled in applications alongwith all necessary documents should reach the Departments/Schools/
Centres concerned on or before 23.06.2012. For details regarding fee, date and the 
procedure, please log on to www.kannuruniversity.ac.in.


FOR MORE DETAILS VISIT www.kannuruniversity.ac.in

REGIONAL INSTITUTE OF EDUCATION (RIE) ,MYSORE ADMISSION 2011-12

RIE ,MYSORE OFFERS THE FOLLOWING COURSES
1. 4 YEAR INTEGRATED BSC.ED (8 SEMESTER)
2. 4 YEAR INTEGRATED BA.ED (8 SEMESTER)
3. 6YEAR INTEGRATED MSC.ED(12 SEMESTERS)
IN PHYSICS CHEMISTRY AND MATHEMATICS
4. ONE YEAR M.ED
5. INTEGRATED DIPLOMA IN GUIDANCE AND COUNCELLING(IDGS)
FOR MORE DETAILS VISIT
www.riemysore.ac.in
LAST DATE: JUNE 20

MG UNIVERSITY CAP 2011 ADMISSION

APPLICATION INVITED FOR ADMISSION IN VARIOUS COLLEGES OF MG UNIVERSITY KERALA FOR UG COURSES . ADMISSION WILL BE THROUGH CENTRALISED ALLOTMENT CAP 2011.FOR MORE DETAILS VISIT WWW.MGU.AC.IN

Wednesday, May 18, 2011

CENTRAL UNIVERSITY OF KERALA ADMISSION 2011

CENTRAL UNIVERSITY OF KERALA INVITED APPLICATION FOR MA MSC MPHIL COURSES . ADMISSION WILL BE ON THE BASIS OF CUCET2011 ENTRANCE EXAMINATION .

Tuesday, May 10, 2011

QUANTUM COMPUTERS

When the microprocessor came out, it pretty much revolutionized the computer industry; the development was exponential, and from rudimentary calculus machines, we went to today's standards, when an average computer can make more calculations than half of mankind put together. But this development seems to have reached a sort of plateau; after all, there is a limit to how many transistors you can use, there is a limit to how many processors you can put on a motherboard. Where can we go from here ? The answers seems to come up from the most surprising of places - quantum mechanics; and the next step ?Quantum computers.
In the world of quantum mechanics, things don't happen as they do in the real world. It has its own set of laws, that were developed for the purpose of explaining why light somehow acts like a wave, and sometimes like particles. The result is you get a bunch of phenomena that seem just absurd in the real word, but they are very much true in the quantum world; two of these phenomena are quantum entanglement and quantum superposition (if you are interested, find explanations about these at the end of the article).
Basically, instead of using bits, in the quantum computing system, you would use qubits. How they differ from bits is actually extremely interesting; bits are basic... bits of information. They are either 1 or 0, black or white, and this is how they work and how they transfer information. The qubit on the other hand has with additional dimensions associated to the quantum properties of a physical atom. The physical construction of quantum computers is itself an arrangement of entangled atoms, and the qubit represents[clarification needed] both the state memory and the state of entanglement in a system. Basically, a qubit can be either a 1, a 0, and there is a possibility for each one of these outcomes. Doesn't make a lot of sense, does it ? For quanta, it does.
The advantages here are absolutely huge - they would be able to make much more calculations, extremely more calculations actually. Thus we would see significant developments in astronomy, sociology, physics, and pretty much every field of science which relies on computer models - almost all of them, actually.
However, there is still a long way to go to reach that place. Although the scientific world has been abuzz with the sale of a quantum computer, researchers claim that there is still a really long way to go until we get a competitive one. But they will come, and hopefully, the world will know how to make good use of them.

MG UNIVERSITY ADMISSION 2011

APPLICATION INVITED FOR VARIOUS COURSES INCLUDING MSC,MPHIL ETC IN VARIOUS TEACHING DEPARTMENTS IN MG UNIVERSITY,kerala.FOR MORE DETAILS VISIT mgu.ac.in

Thursday, May 5, 2011

ELEMENTARY PARTICLES

The search for the origin of matter involves the comprehension of elementary particle sand with the advent of holism, the venture to know about them required an understanding not only about their characteristics, but also about how they interact and relate to other particles and forces of Nature, in the field of Physics called particle physics. More than 2000 subatomic particles have been discovered so far detected in sophisticated particle accelerators.
These are the most basic physical constituents of the universe. In modern physics, the elementary particles are described by the standard model, categorized in three basic families, the electron- like, the muoun- like and the tau- like. The standard model is the ruling model that describes the world of the subatomic particles and interactions. In the Standard model, the quarks, leptons and gauge bosons are considered elementary particles. Historically, even whole atoms and hadrons were considered elementary particles.
A central feature in this theory is the 20th century idea of "quanta", which revolutionized the understanding of electromagnetic radiation and introduced quantum mechanics. Elementary particles in relation to mathematical purposes are normally considered as point particles, although some particle theories such as string theoryconceive a physical dimension.
Standard model
The Standard model is widely considered to be a provisional theory rather than a truly fundamental one, since it is unknown if it is compatible with Einstein's general relativity. Hypothetical elementary particles which are not described by the standard model, such as the graviton carry the gravitational force and supersymmetric partners of the ordinary particles. This model of particle physics contains 12 flavors of elementary fermions, their corresponding antiparticiples, as well as elementary bosons that mediate the forces.
The 12 fundamental fermions value are divided into 3 generations of four particles each. The grouping include: six of the particles are quarks, remaining six are leptons and three of which are neutrinos and the remaining three of which have an electric charge of -1, the electron and its two cousin the muon and the tau.
Anti participles
There are 12 fundamental fermionic antiparticiples which correspond to these 12 particles distinguished under Antileptons and Antiquarks.
Antiparticles are produced naturally in beta decay and in the interaction of cosmic rays in the Earth's atmosphere. The combination of Particle- antiparticle pair can produce photons, by destroying each other, since the charges of both are opposite and preserved. Although particles and their antiparticles have opposite charges, electrically neutral particles need not be equal to their antiparticles.