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Department of Electronics Nanoelectronics 04 Atsufumi Hirohata 10:00 Tuesday, 20/January/2015 (B/B 103)

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Presentation on theme: "Department of Electronics Nanoelectronics 04 Atsufumi Hirohata 10:00 Tuesday, 20/January/2015 (B/B 103)"— Presentation transcript:

1 Department of Electronics Nanoelectronics 04 Atsufumi Hirohata 10:00 Tuesday, 20/January/2015 (B/B 103)

2 Quick Review over the Last Lecture Maxwell equations with ( scalar ) potential (  ) and ( vector ) potential ( A ) : ( Lorentz ) gauge : ( Scalar potential ) Positive charge ( Electric field E ) Electrical current ( Magnetic field H ) ( Vector potential )

3 Contents of Nanoelectonics I. Introduction to Nanoelectronics (01) 01 Micro- or nano-electronics ? II. Electromagnetism (02 & 03) 02 Maxwell equations 03 Scalar and vector potentials III. Basics of quantum mechanics (04 ~ 06) 04 History of quantum mechanics 1 05 History of quantum mechanics 2 06 Schrödinger equation IV. Applications of quantum mechanics (07, 10, 11, 13 & 14) V. Nanodevices (08, 09, 12, 15 ~ 18)

4 04 History of Quantum Mechanics 1 Black body radiation Light quantum Photoelectric effect Compton scattering De Broglie wave

5 Black Body Radiation In 1900, Max Planck reported energy unit of h between light and a material : Black body : * http://www.wikipedia.org/ Non-uniform distribution : cannot be explained by statistical mechanics. in an equilibrium state, each degree of freedom holds E = k B T / 2  equal distribution If the energy unit is h, for k B T < h, no distribution for k B T > h, distribution of k B T / h  non-uniform distribution

6 Einstein's Light Quantum Hypothesis In 1905, Albert Einstein explained that each photon has the energy of h : No suntan ! * http://www.wikipedia.org/ E = h is small. Suntan ! E = h is large.  induces chemical reaction to skin

7 Photoelectric Effect - Experiments In 1887, Heinrich R. Hertz found ultraviolet light encourages discharge from a negative metallic electrode : * http://www.wikipedia.org/ In 1888, W. L. F. Hallwacks observed electron radiation by light. metal plate electrons Metallic foil electrode glass bottle ** http://www12.plala.or.jp/ksp/quantum/photoelectric1/ light source In 1902, Philipp E. A. von Lenard found radiated electron energy is independent of light intensity but dependent upon. electrons photons strong lightweak light *** http://homepage2.nifty.com/einstein/contents/relativity/contents/relativity3005.html large small

8 Photoelectric Effect - Theory In 1905, Albert Einstein proposed theories of light with using a light quantum : * http://www.wikipedia.org/ Light consists of a light quantum (photon). W : work function for an electron to be released Light holds both wave and particle nature. Momentum of a photon is predicted to be h / c.

9 Milikan's Oil-Drop Experiment In 1916, Robert A. Millikan and Harvey Fletcher measured the Planck constant : * http://www.wikipedia.org/ In 1912, an electron charge measured to be : 1.592  10 -19 C (1.60217653  10 -19 C) ~ kV uniform electric field oil spray microscope A critical voltage, at which no electron motion (no photocurrent) is realised :

10 Compton Scattering In 1923, Arthur H. Compton measured the momentum of a photon : * http://www.wikipedia.org/ : wavelength of a photon before scattering, ’ : wavelength of a photon after scattering, m e : electron mass,  : scattered photon angle, h : Planck constant and c : speed of light

11 Electron Interference Davisson-Germer experiment in 1927 : Electrons are introduced to a screen through two slits. Electron as a particle should not interfere. ≠ Photon (light) as a wave * http://www.wikipedia.org/ - +  Electron interference observed !  Wave-particle duality

12 De Broglie Wave Wave packet : contains number of waves, of which amplitude describes probability of the presence of a particle. where : wave length, h : Planck constant and m 0 : mass of the particle. * http://www.wikipedia.org/  de Broglie hypothesis (1924 PhD thesis  1929 Nobel prize) According to the mass-energy equivalence : where p : momentum and : frequency. By using E = h,

13 Schrödinger Equation In order to express the de Broglie wave, Schrödinger equation is introduced in 1926 : E : energy eigenvalue and  : wave function Wave function represents probability of the presence of a particle  * : complex conjugate (e.g., z = x + iy and z * = x - iy ) Propagation of the probability (flow of wave packet) : Operation = observation : operator de Broglie wave observed results : normalisation

14 Scrödinger's Cat Thought experiment proposed by Erwin R. J. A. Schrödinger in 1935 Radioactive substance Hydrocyanic acid The observer cannot know if a radioactive atom has decayed. if the vial has been broken and the hydrocyanic acid has been released. if the cat is killed. * http://www.wikipedia.org/  The cat is both dead and alive according to quantum law : superposition of states The superposition is lost : only when the observer opens the box and learn the condition of the cat. then, the cat becomes dead or alive.  quantum indeterminacy

15 Comparison between Classical and Quantum Mechanics In order to express the de Broglie wave, Schrödinger equation is introduced in 1926 : Classical mechanicsQuantum mechanics Coordinate Momentum Energy Variables Equation Amplitide / wavefunction Energy / probability

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