Difference between revisions of "Band Regime versus Hopping Regime"
Line 40: | Line 40: | ||
leading to geometry relaxations | leading to geometry relaxations | ||
* | *intramolecular modes | ||
* | *intermolecular modes. | ||
|} | |} | ||
Revision as of 11:51, 22 June 2009
Previous Topic | Return to Transport Properties Menu | Next Topic |
Band regime vs Hopping regime
Band regimen and hopping regimes are the two limiting systems for transport although there are variations of each.
In band regime the charge carrier (wavefunction) is delocalized over the entire molecule or system.
In hopping regime there is a localized charge carrier on a single molecule and you can follow the movement of the charge from molecule to molecule or chain segment to chain segment. Depending on the geometry and orientation of crystals hopping may result in differing mobilities in different directions or when hopping between layers.
In a band regime the delocalization over the whole system means there is only a probability of finding the charge carrier in any location. This results in coherent transport. In a sense the charge carrier has a “memory” of where it was before.
In the case of hopping the transport is incoherent because each hop is random and has no correlation to the immediately preceding hop.
Electronic coupling is large in the band regime and is the dominant factor. Whereas in the hopping regime coupling of charge carrier with vibrations, caused by geometry relaxations, is the dominant factor. In pi conjugated systems with a charge localized somewhere on a chain or a molecule there will be a geometry relaxation around that charge leading to the formation of a phonon. A phonon is a mode of vibration in an ordered solid material or molecular substance that involve then entire lattice.
Geometry relaxations can lead to intramolecular vibrations as well as intermolecular vibrations in which adjacent molecules move with respect to one another.
band regime | hopping regime |
---|---|
delocalization of the charge carrier wavefunctions | localization of the charge carrier wavefunctions |
coherent transport | incoherent hops |
electronic coupling | electron-phonon coupling-
leading to geometry relaxations
|
See Chemical Reviews 2004[1]
See Chemical Reviews 2007[2]
In order to achieve a band regime (which has the largest carrier mobility) you must have a highly ordered structure or single crystal with few impurities. Low temperature is required because vibrations in adjacent coupled molecules due to temperature will decrease the electronic coupling and therefore decrease the mobility. For this reason mobility decreases with increasing temperature. In the case of methyl, which has a high charge carrier density, the decrease in mobility means the conductivity also decreases with temperature. The increase in intermolecular and intramolecular vibrations has generally a negative impact on the mobility of charge carriers.
The second requirement for a band regime is the well ordered structure provides a large electronic coupling between adjacent sites on adjacent molecules or polymer repeat units. In a perfectly ordered polyacetylene the wavefunctions for the charge carriers are delocalized over the whole system. If there are polarons and solitons this means there must not be a perfect crystalline structure because these polaronic structures are associated with a geometry relaxation of a the system. Charge polarons and solitons dissappear when there is complete delocalization. Polysulfur nitride ( (SN)x ) has crystals with strong interactions between the chains and no distortions. As a result there are no solitons. Normally samples of polyacetylene and transpolyacetylene are somewhat disordered and soliton and polaron behavior is observed.
Evidence for band regime vs hopping regime
Time domain
In the time domain the typical residence time t of a charge carrier on a site in a molecular materials or polymer repeat chain is described by an Heisenberg-like equation:
- <math>\Tau \propto \frac {\hbar} {W} \rightarrow \tau \propto \frac {2}{3} \frac {10^{-15}} {W_{(eV)}} S\,\!</math>
Where:
- <math>T\,\!</math> is the residence time on a unit
- <math>\hbar\,\!</math> is the period in the Heisenberg uncertaintly pricinciple equation
- <math>W\,\!</math> is the bandwidth
The wider the bandwidth the larger the electronic coupling between adjacent units.
If W, the conduction bandwidth (for electrons) (and, or) the valance bandwidth (for holes) is large enough (.2-.3 eV) then tau is shorter than 10-13 s and band transport is possible.
This is because the carrier will not “sit” long enough on any single molecule for that molecule to have time to geometrically relax (relaxaton for C-C requires 20 ms) making band transport possible.
In a simple tight-binding approximation:
- <math>W = 4 . t\,\!</math>
where:
- <math>t\,\!</math> is the electronic coupling between adjacent sites or adjacent repeating units. T is can also be called the transfer integral or the resonance integral Β(in Hueckel terminology), or tunneling matrix element (in physics).
Energy Domain
There are two possibilities from an energy perspective. The charge carrier can fully delocalize along the system in which case there is no geometry relaxation and the energy gained by electronic coupling and charge carrier delocalization is larger than the energy gained by electron-phonon coupling (geometry relaxations around the charge) leading to charge carrier localization and polaron formation. In delocalization π electrons from several isolated orbitals contribute to form a filled lower energy valence band and an empty higher energy conduction band. Thus the energy was lowered by delocalization. In this case the band regime favored. In Marcus theory this is called minimizing the reorganization of the energy of the system.
However if more energy is gained by geometry relaxation then the hopping regime is favored.
In molecular materials we distinguish between intramolecular vibrations for instance the stretching of a C-C in a pentacene molecule (which is not not affected by adjacent molecules) and intermolecular vibrations (phonons) which propagate across an entire lattice.
Lattice modes have frequency of 50-200 wavenumbers whereas intramolecular C-C stretch can have wavenumbers of 1500-1600. Phonon modes have 20-50 times less energy than intramolecular modes. As temperature in the system increases the phonon mode of vibration are the first to be excited. The frequency is lower so they are 20-50 times slower than a C-C bond stretch. In addition the higher temperature decreases the electronic coupling and increases localization.
References
Previous Topic | Return to Transport Properties Menu | Next Topic |