Course name : Power System AnalysisCourse code : 00697Topic : Presentation on “QUANTUM

TUNNELING COMPOSITE”

Section : ESubmitted to : Rethwan Faiz(course

instructor)

Name :IDHaque,Md Rashidul : 13-24186-2HaqueTahsin,Shamsul Arefin : 12-21353-2 Haq, Shezan Ehsanul :13-24109-2Azmaeen,Mesbah Hossain : 13-24003-2

Consequence of the wave nature of matterFirst used to explain alpha decay of heavier elements in 1928 by George GamowShown experimentally by Leona Esaki in 1958 in the tunneling diode

At the quantum level, matter has corpuscular and wave-like propertiesTunneling can only be explained by the wave nature of matter as described by quantum mechanicsClassically, when a particle is incident on a barrier of greater energy than the particle, reflection occursWhen described as a wave, the particle has a probability of existing within the barrier region, and even on the other side of it

An engineered material made from two or more constituents with significantly different physical or chemical properties which remain separate and distinct on a macroscopic level within the finished structure.

particles do not actually need to touch each other

The nickel particles are not smooth spheres;The particles are surrounded or wetted by an

insulating layer of silicone rubber which prevents them from touching even when pressure is applied.

The spikes on the particles allow a higher concentration of electrons

This reduces the distance and energy needed for the electron charge

Solutions to the wave equation have the general form (I)In the barrier region, the solution becomes (II)

The wave function decays exponentially in the barrier regionIf some portion of the wave function still exists on the other side of the barrier, transmission has occurredThe width of the barrier is the most prominent factor in determining the probability of transmission

(I)

(II)

Images courtesy of Wikipedia

University of Colorado Tunneling ProgramFrom http://phet.colorado.edu/new/simulations/sims.php?sim=Quantum_Tunneling_and_Wave_Packets

George Gamow used tunneling to explain α-decay in Uranium 238

The α particle does not have enough kinetic energy to escape the nucleus

There is a chance, due to it’s wave function, that it will escape the potential barrier of the nucleus boundary

Due to the exponential decay nature of the wave function in the barrier region, the width of the barrier can manifest itself in the half-life of the isotope

92238U 90

234Th24He

As microchip developers create smaller production processes, we reach the limit of classical computer technologyThe feature size of the most advanced microchip today is 45 nmWith such small widths, the electrons in the channel can tunnel out with relative ease, possibly affecting other transistors in the chipCurrent approximations show that the minimum feature size is about 4 nmAfter that point tunneling is not only possible, but highly likely and the chip would fail

The Scanning Tunneling Microscope was invented in 1981 by Gerd Binnig and Heinrich RohrerWhen a metal tip, usually made of tungsten or platinum-iridium, is brought within .4-.7nm of the sample, electrons tunnel across the gap and create a current in the tipThis current is then fed to a computer and used to generate an image of the atomic surface of the sample

Image courtesy of Wikipedia

At this distance the coulomb force between the tip and an atom of the sample is actually enough to move the atomThis has allowed physicists to create images and structures on the atomic level

Images courtesy of IBM

Developed in 1958 by Leona Esaki at SonyTunneling diodes are designed with a heavily doped p-n junction that is only 10 nm wideAt low voltages, the p and n states are aligned, allowing electrons to tunnel across the gapAs voltage increases these states become more misaligned and fewer electrons flow This negative resistance region allows the diode to operate at very high frequencies, well into the Gigahertz range

Image courtesy of Wikipedia

A UK company is developing flexible force sensors that use quantum tunnelingThese sensors are made out of Quantum Tunneling Composite materialsQTC’s are essential non-conducting in their normal stateWhen flexed by an applied force, the atoms of the QTC are brought close enough so that tunneling can occurTunneling changes the QTC from an insulator to a conductor with a predictable exponential decay in resistance

Image courtesy of Peratech

Toys and GamesQTC may be used to replace existing switches and sensors in games controllers and computer mice to give increased sensitivity for greater control.

QTC in Sportcan be used as a sensor in many areas, from force sensors in training dummies for boxing to fencing jackets which incorporate touch sensors.

QTC in Medicinesensors can be incorporated into the cuffs of blood pressure machines to ensure that they are tightened correctly to reduce inaccurate readings.

QTC in ClothingWearable applications include mp3 player controllers built into the sleeves of jackets.

QTC in Toolsincorporated into the handles of power tools to act as a cut out switch or variable controller.

QTC in Roboticsused as durable finger pads in prosthetic / robotic hands which allow the amount of pressure being applied to be controlled.

QTC in Keyboardsused to make a flexible, durable, portable QWERTY keyboard which can be connected to a mobile phone, laptop or other device using Bluetooth.

http://www.peratech.co.uk/science.htm

http://en.wikipedia.org/wiki/Tunnel_diode

http://en.wikipedia.org/wiki/Quantum_tunneling

http://en.wikipedia.org/wiki/Scanning_tunneling_microscope

http://psi.phys.wits.ac.za/teaching/Connell/phys284/2005/lecture-02/lecture_02/node13.html

Rex, A. & Thornton, S. T. (2006) Modern Physics for Scientists and Engineers 3rd ed. Belmont CA: Thomson Brooks/Cole

http://www.almaden.ibm.com/vis/stm/gallery.html