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Manipulating electron and photon waves

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1 Manipulating electron and photon waves
An electron wave packet can be manipulated by squeezing it into a quantum box with a size com-parable to the electron wavelength ( nanometer). The wave packet determines the behavior of the electron, for example in an electronic device. Such “engineered” electron wave packets make useful devices , such as the quantum well laser. Every DVD player contains a quantum well laser. Ch. 2.5

2 A quantum box An electron wave with wavelength  = 2L fits into the box.  determines the momentum: p = h/ = h/2L p determines the kinetic energy: Ekin = ½ mev2 = ½ p2/me A smaller box requires higher energy = h2/8meL2  = 2L L Energy Position

3 Crystal size determines the color
Nanocrystals Crystal size determines the color Blue when small ( small elec  large Eelec  large Ephot  small phot )

4 A leaky quantum box When the walls of a quantum box get too thin, an electron wave packet is able to leak out. This process of magically penetrating the wall of a box is called tunneling . It is like getting across a wall by digging a tunnel through the wall instead of climbing over it.

5 Tunneling between leaky boxes
When another leaky box is brought nearby, the electron may disappear from one box and appear in the other ! That works only if the wall is just a few atoms wide. A solid acts like a box for electrons, vacuum like a wall.

6 Changing the wall thickness
The tunneling probability decreases rapidly for thicker walls. High probability Low probability

7 Scanning Tunneling Microscope (STM)
Electrons tunnel from the yellow surface atoms to the blue atoms at the tip, even though they don’t have enough energy to get across the vacuum in between (which acts like a wall). Very sensitive to height ! The tunneling probability changes by a factor of 100 when the tip moves by an atom diameter . While the tip scans across the surface, its height is recorded.

8 Quantum Corral 48 iron atoms are assembled into a circular ring.
The ripples inside the ring are electron waves.

9 Manipulation of atoms  Manipulation of electron waves
A ‘quantum corral’ is assembled by moving individual iron atoms on a copper surface with the tip of a STM. As the circle of atoms becomes more com- plete , electron waves at the surface become more orderly. This shows how the behavior of electrons can be manipulated by a nanometer-size pattern (here 14 nm diameter). 1 2 3 4

10

11 Playing with atoms Kanji character for atom (lit. original child)
Carbon Monoxide man

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