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ATOMS Condensed Matter 1.Bosons & Fermions 2.LASERs 3.Bose-Einstein Condensation.

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Presentation on theme: "ATOMS Condensed Matter 1.Bosons & Fermions 2.LASERs 3.Bose-Einstein Condensation."— Presentation transcript:

1 ATOMS Condensed Matter 1.Bosons & Fermions 2.LASERs 3.Bose-Einstein Condensation

2 BOSONS & FERMIONS All particles in nature are either Bosons (e.g. photons) can have same position, momentum, energy, etc. Boson +1 wavefunction or Fermions (e.g. electrons) cannot share same position, momentum, energy, etc. Fermion -1 wavefunction

3 FERMIONS Pauli Exclusion Principle: No two electrons can occupy the same state (in an atom)  diversity of elements e.g. electrical

4 BOSONS Iight mplification timulated mission adiation Many Photons Same Wavelength Same Direction In phase (intense) Normal light source -> different wavelengths, directions, phases

5 How to make a LASER? Spontaneous Emission Electron spontaneously jumps down, emits one photon hf Stimulated Emission (Einstein) Incoming photon stimulates electron to jump down 2 nd photon emitted, identical to incoming hf

6 1 photon -> 2 photons -> 4 -> 8 -> 16 -> 32 –> 64 -> … Chain reaction…all photons of same wavelength, direction

7 Temperature Scales Everyday Use Lab Use Lowest temp possible 0 K = - 459 0 F = ABSOLUTE ZERO All atoms stop moving* *Uncertainty Principle prevents attainment, zero-point motion persists

8 Bosons → Bose-Einstein condensation At very low temp, many particles enter zero-point motion E.g. Liquid Helium Atoms @ 2 K Liquid Helium below 2 K is uperfluid → flows without viscosity

9 uperconductivity = electrical (electron) flow without resistance BUT…Electrons are fermions → cannot Bose-Einstein condense ?? 2 x Electron = Boson (-1 x -1 = +1) Cooper Pairs → formed in some metals, ceramics at low temp e.g. Meissner magnetic effect

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