Transcript Devices

Quantum well laser
Energy
electrons
holes
Alferov
Kroemer
Nobel Prize in Physics 2000
A quantum well laser is an improved LED.
Electrons and holes are kept together
inside the semiconductor at the center,
which has a smaller gap. That makes it
easier for electrons to find holes. It also
creates quantized energy levels with a
highly-concentrated density of states.
Solar cell
A photon from the Sun generates an electron-hole pair in a
semiconductor. The electron is pulled to the front, the hole
to the back of the solar cell, thereby creating a battery.
Energy diagram of a solar cell
E
The electron and hole are pulled apart by the electric field
between the p- and n-doped regions.
It is critical not to lose electrons and holes on their way out.
Crystalline semiconductors are good at that, but expensive.
100x100 square miles of solar cells would
satisfy the electricity needs of the US.
Here is
the catch:
Goal
1 $/W
x 0.4 TW =
= 0.4 Trillion $
Low end
High end
Crabtree and Lewis, Physics Today 60, March 2007, p. 37
Inexpensive thin film solar cells
• Use nanoparticles, molecules, polymers
• Less material, low temperature processing
• Print solar cells like newspaper, roll-to-roll
Nanoparticle ink on metal foil
(Nanosolar)
Shockley-Queisser limit for a single junction
Lose excess photon energy
beyond the band gap.
1/3
Converted by a crystalline
silicon solar cell
1/3
Photons below the band
gap are not absorbed.
1/3
Use nanoparticles and molecules for
tunability
Dye-sensitized solar cell (Grätzel cell)
Porphyrin dye:
Metal atom in a
cage of 4 nitrogens
Energy levels to play with in a solar cell
A large energy drop between adjacent levels facilitates
carrier separation (more current), but reduces the voltage.
Energy levels in a Grätzel cell
Lose half the voltage
on the donor side.
Bottlenecks for Grätzel Cells
½
Red , IR not absorbed
½
Level mismatch on the donor side
½
Fill factor:
( IV )max  ( Imax  Vmax )
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⅛
(now 11%)