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PA2003: Nanoscale Frontiers Quantum Dots • Artificial atoms • Schrödinger equation • Square well potential • Harmonic oscillator • 2D Harmonic oscillator • Real quantum dots • Semiconductors • Semiconductor nanocrystals Tipler Chapters 36,37 Dr Mervyn Roy, S6 Quantum Dots PA2003: Nanoscale Frontiers Artificial Atoms Real atom: Electrons confined by coulomb potential in 3D - discrete energy levels Quantum dot: any nanostructure that confines electrons in 3D - discrete energy levels - much more flexibility than in nature Applications: molecular scale electronics, spintronics, opto-electronics, quantum cryptography, quantum computing, fluorescent bio-labels Quantum Dots PA2003: Nanoscale Frontiers 1D Standing waves V 1 x=0 1 x=L x Standing waves in a box Quantum Dots PA2003: Nanoscale Frontiers 1D Standing waves V 1 x=0 1 x=L x Standing waves in a box Quantum Dots PA2003: Nanoscale Frontiers Schrödinger equation Wave particle duality - probability waves described by the Schrödinger equation For stationary states Probability density Uncertainty principle Can use to estimate energy, gives Quantum Dots PA2003: Nanoscale Frontiers 1D Square well confinement V 1 x=0 1 x=L x Same as standing waves in a box! Discrete energy levels, quantum number n Lowest energy state not zero! Quantum Dots PA2003: Nanoscale Frontiers 3D Square well confinement Because V(x,y,z) is separable (V=0) treat each direction separately c 1 quantum number for each degree of freedom b a • Stretch box: energy spacing very small - motion in y direction classical • Squash box: energy level spacing in z very large, z motion quantised out - effectively reduce the number of dimensions 10 % iso-surface Quantum Dots PA2003: Nanoscale Frontiers Harmonic confinement probability distributions Quantum Dots PA2003: Nanoscale Frontiers Harmonic confinement probability distributions Quantum Dots PA2003: Nanoscale Frontiers Harmonic confinement Shell filling Spin up / down 1D quantum dot analogues of H, He etc. Correspondence principle Classical behaviour at high energy when n is large Quantum Dots PA2003: Nanoscale Frontiers 2D Harmonic confinement Solve Schrödinger equation in 2D State Energy quantum no’s spin no. e- total no. ground n=0, l=0 2 2 1st n=0, l=§1 4 6 2nd n=1,l=0 or n=0,l=§2 6 12 Quantum Dots PA2003: Nanoscale Frontiers Nanotube quantum dot • Nanotubes are already used in flak jackets, fuel pipes, tennis rackets etc. nanotube source drain 270 nm SiO2 gate • Molecular scale single electron transistor dot 0.5 nm electrostatic confinement potential 2 electrons per shell (spin up, spin down) Quantum Dots 2 electron charge density (Helium) PA2003: Nanoscale Frontiers Pillar dot vertical confinement ~ square well lateral confinement ~ 2D harmonic oscillator (20, 5/2) Electron molecule (pair correlation function) Rotating pentagonal electron molecule (Boron) Calculation by Prof. P. A. Maksym Quantum Dots PA2003: Nanoscale Frontiers Self assembled quantum dot MBE grown dots. ~ 3D quantum box 5 nm InAs dot GaAs 0.0 -0.1 Dots are highly strained Isosurfaces in electron charge density Quantum Dots PA2003: Nanoscale Frontiers Semiconductor bands Dispersion relations Free particles: Eg Semiconductors Electrons: Holes: Hole (absence of electron): +ve charged particle with effective mass holes and electrons recombine near k=0 to produce a photon Quantum Dots PA2003: Nanoscale Frontiers Semiconductor nanocrystals Bulk semiconductors – photon • band gap Eg Nanocrystals - photon • band gap Eg • nanocrystal size small Quantum Dots large depends on: depends on: PA2003: Nanoscale Frontiers Semiconductor nanocrystals Normal semiconductor Eg ~ 1D box, Semiconductor nanocrystals V 1 Ee 1 Eg Eh x=0 x=L Quantum Dots x PA2003: Nanoscale Frontiers Semiconductor nanocrystals Complications: 3D not 1D… R makes no difference: Complications: Electrons and holes present… Ee Quantum Dots Eh PA2003: Nanoscale Frontiers Semiconductor nanocrystals Complications 3D not 1D… R R makes no difference: Complications: Electrons and holes present… Ee Eh Complications: surface effects, correlation effects etc. etc. Quantum Dots Coulomb interaction PA2003: Nanoscale Frontiers Semiconductor nanocrystals Gao et al. Nature Biotechnology, 22, (8), 969 (2004) Quantum Dots
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