All you need to know about Pirate-Community

[Jman]

What do you meen by unique?

[neo]

Does he deny is identy when you say its Matyuv? LIke "WHO is Matyuv?".

[Hunchman801]

By unique, I mean different from any other's. It's up to you to say how And he does not deny his identity, he does not even want to hide ^^

[Xenon]

If he returns has his old self, we'd welcome him with open arms of course..

[neo]

But unfortanetly he will not come back... wow, its been a long time since I have talked about rayman.

[Xenon]

He might come back, if th3()ne just leaves us alone, but yes, probably not for a long while. And wasn't that a little random?

[neo]

Yes, but I just remembered about it.

[Xenon]

I don't visit the Rayman forum much anymore either.

[Hunchman801]

I still go there, yet I post everywhere.

[neo]

I have been there twice recently, but for that PM I sent to that one person... I forgot his name...

[Hunchman801]

You can check your sentbox

[noob1]

In modern physics, the photon is the elementary particle responsible for electromagnetic phenomena. It mediates electromagnetic interactions and makes up all forms of light. The photon has zero invariant mass and travels at the constant speed c, the speed of light in empty space. However, in the presence of matter, a photon can be absorbed, transferring energy and momentum proportional to its frequency. Like all quanta, the photon has both wave and particle properties, exhibiting wave–particle duality.

[noob1]

The photon concept has led to momentous advances in experimental and theoretical physics, such as lasers, Bose–Einstein condensation, quantum field theory, and the probabilistic interpretation of quantum mechanics. According to the Standard Model of particle physics, photons are responsible for producing all electric and magnetic fields, and are themselves the product of requiring that physical laws have a certain symmetry at every point in spacetime. The intrinsic properties of photons — such as charge, mass and spin — are determined by the properties of this gauge symmetry. Photons have many applications in technology such as photochemistry, high-resolution microscopy, and measurements of molecular distances. Recently, photons have been studied as elements of quantum computers and for sophisticated applications in optical communication such as quantum cryptography.

[noob1]

I am the clevor.

[noob2]

In modern physics, the photon is the elementary particle responsible for electromagnetic phenomena. It mediates electromagnetic interactions and makes up all forms of light. The photon has zero invariant mass and travels at the constant speed c, the speed of light in empty space. However, in the presence of matter, a photon can be absorbed, transferring energy and momentum proportional to its frequency. Like all quanta, the photon has both wave and particle properties, exhibiting wave–particle duality.

[noob1]

The classical formulae for the energy and momentum of electromagnetic radiation can be re-expressed in terms of photon events. For example, the pressure of electromagnetic radiation on an object derives from the transfer of photon momentum per unit time and unit area to that object, since pressure is force per unit area and force is the change in momentum per unit time.

[Hunchman801]

You are repeating yourselves. You lack organization ^^

[noob1]

Quantum chemistry mathematically describes the fundamental behavior of matter at the molecular scale. It is, in principle, possible to describe all chemical systems using this theory. In practice, only the simplest chemical systems may realistically be investigated in purely quantum mechanical terms, and approximations must be made for most practical purposes (e.g., Hartree-Fock, post Hartree-Fock or Density functional theory, see computational chemistry for more details). Hence a detailed understanding of quantum mechanics is not necessary for most chemistry, as the important implications of the theory (principally the orbital approximation) can be understood and applied in simpler terms.

In quantum mechanics (several applications in computational chemistry and quantum chemistry), the Hamiltonian, or the physical state, of a particle can be expressed as the sum of two operators, one corresponding to kinetic energy and the other to potential energy. The Hamiltonian in the Schrödinger wave equation used in quantum chemistry does not contain terms for the spin of the electron.

Solutions of the Schrödinger equation for the hydrogen atom gives the form of the wave function for atomic orbitals, and the relative energy of say the 1s,2s,2p and 3s orbitals. The orbital approximation can be used to understand the other atoms e.g. helium, lithium and carbon.

[Xenon]

What is all this gobble?

[noob1]

We knowed you wood not onderstand.