Elements of Particle Physics - The Institute of Mathematical Sciences
... Mendeleev’s periodic table of atoms. Further some of the so called ”elementary particles” also began to display signatures of an internal structure. Just as the systematics of periodic table indicated an underlying structure of atoms made up of electrons and nuclei, the table of particle data indica ...
... Mendeleev’s periodic table of atoms. Further some of the so called ”elementary particles” also began to display signatures of an internal structure. Just as the systematics of periodic table indicated an underlying structure of atoms made up of electrons and nuclei, the table of particle data indica ...
m L
... • n = 1, 2, 3…..etc. These numbers correlate to the distance of an electron from the nucleus. In Bohr’s model, these corresponded to the “shell” orbiting the nucleus. • n determines the energies of the electrons • n also determines the orbital size. As n increases, the orbital becomes larger and the ...
... • n = 1, 2, 3…..etc. These numbers correlate to the distance of an electron from the nucleus. In Bohr’s model, these corresponded to the “shell” orbiting the nucleus. • n determines the energies of the electrons • n also determines the orbital size. As n increases, the orbital becomes larger and the ...
A little Big Bang
... 40K and 41K, two isotopes of potassium that differ by a mere neutron, but which behave so differently because of their bosonic and fermionic nature. We now encounter a puzzle: if fermions cannot condense into one and the same state, but condensation and superfluidity are intrinsically linked, how ca ...
... 40K and 41K, two isotopes of potassium that differ by a mere neutron, but which behave so differently because of their bosonic and fermionic nature. We now encounter a puzzle: if fermions cannot condense into one and the same state, but condensation and superfluidity are intrinsically linked, how ca ...
Quantum Numbers
... Each Quark is assigned a new quantum number Colour – can have 3 values Red, Green & Blue and the particle wave function has an extra factor |Ψcolor> Which is anti-symmetric All particles – baryons & mesons are colourless – so each of the 3 quarks in a baryon has a different colour (r, g, b) ! In a m ...
... Each Quark is assigned a new quantum number Colour – can have 3 values Red, Green & Blue and the particle wave function has an extra factor |Ψcolor> Which is anti-symmetric All particles – baryons & mesons are colourless – so each of the 3 quarks in a baryon has a different colour (r, g, b) ! In a m ...
Chapter 2 Second Quantisation - Theory of Condensed Matter
... other words, all oscillator states k 0 6= k are in their ground state, whilst mode k is in the first exited state. The vector space generated by linear combinations of states |ki is called F1 . This procedure can be iterated in an obvious manner. Simply define the space FN to be generated by all sta ...
... other words, all oscillator states k 0 6= k are in their ground state, whilst mode k is in the first exited state. The vector space generated by linear combinations of states |ki is called F1 . This procedure can be iterated in an obvious manner. Simply define the space FN to be generated by all sta ...
SOME ELEMENTS OF ATOMIC STRUCTURE THEORY
... As everyone knows, an atom is the smallest unit of a chemical element, and atoms combine to form molecules and solids. Each element is uniquely specified by its atomic number Z. However a given element may occur in several different versions, called isotopes; these have the same Z but different atomic ...
... As everyone knows, an atom is the smallest unit of a chemical element, and atoms combine to form molecules and solids. Each element is uniquely specified by its atomic number Z. However a given element may occur in several different versions, called isotopes; these have the same Z but different atomic ...
Lecture 7 - TTU Physics
... • Specifically, a system with f degrees of freedom can be described by a (many particle!) wavefunction Ψ(q1,q2,….qf,t), where q1,q2,….qf ≡ a set of f generalized coordinates which are required to characterize the system (needn’t be position coordinates!) – A particular quantum state (macrostate) of ...
... • Specifically, a system with f degrees of freedom can be described by a (many particle!) wavefunction Ψ(q1,q2,….qf,t), where q1,q2,….qf ≡ a set of f generalized coordinates which are required to characterize the system (needn’t be position coordinates!) – A particular quantum state (macrostate) of ...
