1. TUTORIAL I DEVICE PHYSICS, CHARGE TRANSPORT, APPLICATIONS AND PROCESSING IN ORGANIC ELECTRONICS Nir Tessler Devin Mackenzie March 28, :30 – 5:00 PM

2. MRS SPRING 2005 TUTORIAL I DEVICE PHYSICS, CHARGE TRANSPORT, APPLICATIONS AND PROCESSING IN ORGANIC ELECTRONICS PART 1 DEVICE PHYSICS and CHARGE TRANSPORT Nir Tessler EE Dept. Technion

3. Nir Tessler, EE Dept. Technion
Organic Semiconductors
Nir Tessler, EE Dept. Technion
Semiconductor
High band gap
Low mobility
Molecular
You are holding ~60 slides but we will look together only at part of them. Watch for the slide number

4. Reminder EFM EC EF=EFi EFi EFi EF EV If the band-gap
is high Insulator
Intrinsic
N-type
P-type
Metal EC EV
EF=EFi
EFM
EFi EF EF
EFi

5. Semiconductor

6. Isolated Material E0- Vacuum level Metal EFM EC Semiconductor EF EV
(not in equilibrium)
E0- Vacuum level
Metal
EFM EF EC EV
Semiconductor
Metal
The energy required to “lift” an electron from the metal to the semiconductor
= work function
The (average) energy required to extract an electron.

7. (creating equilibrium)
Making contact
(creating equilibrium) E0
Metal
EFM EF EC EV
Semiconductor
Is there any electronic interaction?

8. Charging a capacitor to a voltage of:
Making contact E0 EC DV
Metal
EFM EF
Semiconductor EV
Charging a capacitor to a voltage of:

9. What assumptions did we use?
There exist equilibrium between M and SC  Fermi level is continuous.
The metal is an infinite reservoir (attaching the SC is a small perturbation)
The potential is continuous (no dipoles ) +Q -Q

10. What will occur after making contact?
Isolated Materials
E0- Vacuum level
Metal
Metal
EFM EF EC EV
Semiconductor
What will occur after making contact?
Will the semiconductor become metallic?
Will the entire volume be chemically reduced?

11. Isolated Material Connected E0 EF EC EV EFM EFM EF EC EV
(no equilibrium)
Connected
(equilibrium) E0
ultra-thin EF EC EV
Metal
EFM
Metal
EFM EF EC EV
Ultra-thin ~ nm scale

12. Ultra-thin EF EC EV
Metal
EFM
Since the ultra-thin region is negligible in size it is not drawn: EF EC EV
Metal
EFM
Interface dipole
Conclusion: the metal workfunction can not be above (below) the conduction (valence) band.

13. What will happen after making contact
2.7
3.5
5.2
5.2
What will happen after making contact
=1.7

14. Thermionic Emission E EC X Current Ec Barrier Basic Assumptions:
Emission from A to B does not depend on emission from B to A but only on the concentration in A and B respectively (there doesn’t have to be equilibrium across the interface).
The charge density in the metal is fixed (infinite reservoir)

15. In Low mobility semiconductors (organics) the emission rates from metal to organic and back are much larger then the current flowing in the device:
There is equilibrium at the contact interface
The thermionic emission process is not important but for ensuring equilibrium.
What may change the above?
What may slow the emission across the interface?
The presence of a thin insulating layer will make the crossing from the metal to the organic (tunneling) very slow and it will become the rate limiting factor (i.e. break the equilibrium).

16. Insulator
N. F. Mott and R. W. Gurney, Electronic processes in ionic crystals (Oxford university press, London, 1940).
M. A. Lampert and P. Mark, Current injection in solids (Academic Press, New York, 1970

17. A current flowing through “insulator”
Without an injection:
velocity
When the charge is evenly distributed:

18. A current flowing through “insulator”
Detailed description:
To be consistent with previous slide, use drift current only:

19. The charge density at the contact interface (N0) is dictated by the contact

20. What does small K mean?

21. Minor problem We neglected diffusion currents
We found that E=0 at the contact
So how come there is any current?
These expressions do not hold at the close vicinity of the contact and as long as the contact region is much smaller then the device it doesn’t matter.

22. Now the charges are in
How do they move?

23. e Molecular  Localization x Conjugated segments  “States”
Charge conduction  non coherent hopping x e

24. What are the important factors?
What is the statistics of energy-distribution?
What is the statistics of distance-distribution?
Is it important to note that we are dealing with molecular SC? Do we need to use the concept of polaron?
Energy difference
Distance
Similarity of the Molecular structures

25. Detailed Equilibrium Ej Ei
Anderson:

26. Molecular Nature of the Envelope Function
The polaron picture:

27. Simplistic approach Elastic energy:
Q is a molecular configuration coordinate
Stretched
Squeezed
Equilibrium

28. Elastic Energy (spring)Q0
E0spring
Configuration coordinates
E=E0+B(Q-Q0)2

29. Adding an electron (mass) will add energy of m*g*hQ0
E0t= E0spring+E0elec Q
Here the particle just entered the system (molecule) and we see the potential surface just before relaxation
After the system undergoes relaxation to a new equilibrium point. The “system” gained elastic energy while the electron energy went down
(mg*Dh-BQ2>0)

30. Q A* A Q0
E0spring
E0t= E0spring+
mgQ0 A*
E0= E0t
BDQ2 -
mgDQ A

31. The electronic equivalent
Stretch mode En
En +dEn L
L + dL
For small variations in the “size” of the molecule the electron phonon contribution to the energy of the electron is linear with the displacement of the molecular coordinates.
For p-conjugated the atomic displacement is ~0.1A and F=2-3eV/A.
The general formalism:
Ee-ph=-AQ

32. Linear electron-phonon interaction:
The system was stabilized by DE through electron-phonon interaction 
Polaron binding energy

33. Transfer will occur when Q1=Q2=Q
Total excess energy to reach this state:
Electron transfer is thermally activated process
Typical number is:

34. If initial and final energies are different:
(In disordered materials E0_e is not identical for the two molecules)
Accounts for difference between the equilibrium energies

35. Requires the “presence” of phonons.
Or the occupation of the relevant phonons should be significant
Average
attempt frequency
Probability of electron to move (tunnel) between two molecules that are in their “best” conformation
Activation of the molecular conformation

36. Bosons: What will happen if T<Tphonon/2 ?
The relevance to our average attempt frequency:
What will happen if T<Tphonon/2 ?
The molecules will not reach the “best” conformation that was accessible at higher (room) temperature
New activation energy
New attempt frequency
Typical temperature at which the transport mechanism changes is k

37. Sites-Energy Statistics (the most popular ones)
Gaussian DOS
Exponential DOS
Completely ignore the issue

38. What is the statistical Energy-Distribution?
Gaussian
Exponential

39. The two look very different
BUT – a single experiment (typically) samples only a small region of the DOS

40. Charge Mobility & Charge Density
For low enough density:
For high enough density:
(Nt=1020cm-3 -> n<5x1018)
(s=5kT, Nt=1020cm-3 -> n>1x1015)
Power Law
T0=450k  s=5.5kT
M. Vissenberg and M. Matters, "Theory of the field-effect mobility in amorphous organic transistors," Physical Review B, vol. 57, pp , 1998
Y. Roichman, Y. Preezant, and N. Tessler, "Analysis and modeling of organic devices," Physica Status Solidi a-Applied Research, vol. 201, pp , 2004

41. Electric Field Mobility (a.u.) s=7kT Empirical Typical numbers
Gaussian DOS
H. Bassler, Phys. Stat. Sol. (b) 175, (1993)
(The range of papers by H. Bassler provide deep insight of the transport)
Mobility (a.u.)
Y. Roichman, Y. Preezant, and N. Tessler, "Analysis and modeling of organic devices," Physica Status Solidi a-Applied Research, vol. 201, pp , 2004
s=7kT

42. Derivation of the Generalized Einstein Relation
Current continuity Eq.
In the absence of external force (J=0)
Equilibrium conditions
(existence of a Fermi level + constant temperature)
Generalized
Einstein-Relation
(Ashcroft, solid state physics)

43. Generalized Einstein Relation
Charge Diffusion & Charge Density
(A)
s=7kT
s=5kT
s=4kT
Enhancement of Einstein Relation
T0=600k
T0=500k
T0=400k
Y. Roichman and N. Tessler, "Generalized Einstein relation for disordered semiconductors - Implications for device performance," Applied Physics Letters, vol. 80, pp , 2002
Relative Charge Density

44. Diode
Or:
s=4kT  T0=450k

45. Extracting Mobility Analysis of LEDs Analysis of FETs
The disorder parameter s is an established important feature
Can we extract it?

46. LEDs Gaussian DOS at low density limit Average Density
H. Bassler, Phys. Stat. Sol. (b), vol. 175, pp , 1993
Average Density
Density at the exit contact
Need a formalism that accounts for both electric field and density

47. CIp-FET Drain Source Source Drain p - conjugated y x z L L W W W W L L
Insulator
SiO
Insulator
SiO 2 2 y x z Si
Conductor
Conductor Si Vg Vg Vg Vg

48. Charge Density & Electric Field Dependence
(Gaussian DOS)
s=4kT
s=7kT
Mobility (a.u.)
The exponential prefactor depends on s as well as Charge Density
Y. Roichman, Y. Preezant, N. Tessler, Phys. Stat. Sol

49. s/kT Exponential pre-factor
Mean Medium Approximation - Low & High Density + Electric field
only for LEDs thicker then 200nm (and limited voltage range)
AND
Exponential pre-factor
~1016÷1017cm-3
s/kT
Using Low density expression
The extracted s is always ≤130meV

50. k Use FETs to extract s At Low Electric Field: At Room Temp. Tasks:
1. Measure Mobility
2. Estimate charge density

51. Extracting Mobility - FETs
But 100% is not always critical

52. Deriving the expressions for charge density dependent mobility

53. This procedure does NOT (i.e. general procedure)
assume a given DOS
Shape
(i.e. general procedure)
By making the best fit one finds:
1. Density dependent mobility
2. Threshold voltage (+-)

55. To evaluate charge density:
transfer Vg to density in cm-2 and then to cm-3
Einstein relation is larger then 1 and depends on the charge density
Simple to implement
Accounting for it:
Charge Density can not exceed the DOS
Channel depth does not go below 1-2 monolayer
It is too fundamental to be ignored!

56. Threshold Voltage
Intrinsic E E C C E F E E V V
Gate
Voltage

57. E E E E E Threshold Voltage Intrinsic EF C C F V V VG Linear Gate

58. E E E E E Threshold Voltage – disordered material Intrinsic C C F V VEF E E C C
Linear E F
Exponent E E
Sub-
Threshold VG V V
Gate
Voltage

59. Models for Contact injection:
[1] V. I. Arkhipov, E. V. Emelianova, Y. H. Tak, and H. Bassler, "Charge injection into light-emitting diodes: Theory and experiment," Journal of Applied Physics, vol. 84, pp , 1998.
[2] V. I. Arkhipov, U. Wolf, and H. Bassler, "Current injection from metal to disordered hopping system. II. Comparison between analytic theory and simulation," Phys. Rev. B, vol. 59, pp , 1999
[3] M. A. Baldo and S. R. Forrest, "Interface-limited injection in amorphous organic semiconductors - art. no ," Physical Review B, vol. 6408, pp ,
[4] M. A. Baldo, Z. G. Soos, and S. R. Forrest, "Local order in amorphous organic molecular thin f ilms," Chemical Physics Letters, vol. 347, pp , 2001
[5] Y. Preezant and N. Tessler, "Self-consistent analysis of the contact phenomena in low- mobility semiconductors," Journal of Applied Physics, vol. 93, pp , 2003.
[6] Y. Preezant, Y. Roichman, and N. Tessler, "Amorphous Organic Devices - Degenerate Semiconductors," J. Phys. Cond. Matt., vol. 14, pp. 9913–9924,
[7] Y. Roichman, Y. Preezant, and N. Tessler, "Analysis and modeling of organic devices," Physica Status Solidi a-Applied Research, vol. 201, pp , 2004
[8] J. C. Scott and G. G. Malliaras, "Charge injection and recombination at the metal-organic interface," Chemical Physics Letters, vol. 299, pp , 1999.
[9] T. van Woudenbergh, P. W. M. Blom, M. Vissenberg, and J. N. Huiberts, "Temperature dependence of the charge injection in poly-dialkoxy-p-phenylene vinylene," Applied Physics Letters, vol. 79, pp , 2001
[10] J. H. Werner and H. H. Guttler, "Barrier Inhomogeneities at Schottky Contacts," Journal of Applied Physics, vol. 69, pp , 1991

60. Transport models
[1] W. D. Gill, "Drift mobilities in amorphous charge-transfer complexes of trinitrofluorenone and poly-n- vinylcarbazole," J. Appl. Phys., vol. 43, pp. 5033, 1972.
[2] M. Van der Auweraer, F. C. Deschryver, P. M. Borsenberger, and H. Bassler, "Disorder in Charge-Transport in Doped Polymers," Advanced Materials, vol. 6, pp , 1994.
[3] R. Richert, L. Pautmeier, and H. Bassler, "Diffusion and drift of charge-carriers in a random potential - deviation from einstein law," Phys. Rev. Lett., vol. 63, pp , 1989.
[4] V. I. Arkhipov, P. Heremans, E. V. Emelianova, G. J. Adriaenssens, and H. Bassler, "Weak-field carrier hopping in disordered organic semiconductors: the effects of deep traps and partly filled density-of-states distribution," Journal of Physics-Condensed Matter, vol. 14, pp , 2002.
[5] M. Vissenberg and M. Matters, "Theory of the field-effect mobility in amorphous organic transistors," Physical Review B, vol. 57, pp , 1998.
[6] D. Monroe, "Hopping in Exponential Band Tails," Phys. Rev. Lett., vol. 54, pp , 1985.
[7] H. Scher, M. F. Shlesinger, and J. T. Bendler, "TIME-SCALE INVARIANCE IN TRANSPORT AND RELAXATION," Physics Today, vol. 44, pp , 1991.
[8] H. Scher and E. M. Montroll, "Anomalous transit-time dispersion in amorphous solids," Phys. Rev. B, vol. 12, pp –2477, 1975.
[9] E. M. Horsche, D. Haarer, and H. Scher, "Transition from dispersive to nondispersive transport: Photoconduction of polyvinylcarbazole," Phys. Rev. B, vol. 35, pp , 1987.
[10] Y. Roichman, Y. Preezant, and N. Tessler, "Analysis and modeling of organic devices," Physica Status Solidi a- Applied Research, vol. 201, pp , 2004.
[11] Y. Roichman and N. Tessler, "Generalized Einstein relation for disordered semiconductors - Implications for device performance," Applied Physics Letters, vol. 80, pp , 2002.
[12] Y. N. Gartstein and E. M. Conwell, "High-Field Hopping Mobility in Molecular-Systems with Spatially Correlated Energetic Disorder," Chemical Physics Letters, vol. 245, pp , 1995.
[13] H. C. F. Martens, P. W. M. Blom, and H. F. M. Schoo, "Comparative study of hole transport in poly(p- phenylene vinylene) derivatives," Physical Review B, vol. 61, pp , 2000
[14] S. V. Rakhmanova and E. M. Conwell, "Electric-field dependence of mobility in conjugated polymer films," Applied Physics Letters, vol. 76, pp , 2000
[15] R. A. Marcus, "Chemical + Electrochemical Electron-Transfer Theory," Annual Review of Physical Chemistry, vol. 15, pp. 155-&, 1964.
[16] R. A. Marcus, "Theory of Oxidation-Reduction Reactions Involving Electron Transfer .5. Comparison and Properties of Electrochemical and Chemical Rate Constants," Journal of Physical Chemistry, vol. 67, pp &, 1963.
[17] D. Emin, "Small polarons," Phys. Today, vol. 35, pp , 1982

61. Transport in FETs
[1] S. M. Sze, Physics of Semiconductor Devices. New York: Wiley, 1981.
[2] A. A. Muhammad, A. Dodabalapur, and M. R. Pinto, "A two-dimensional simulation of organic transistors," IEEE trans. elect. dev., vol. 44, pp , 1997.
[3] G. Horowitz, P. Lang, M. Mottaghi, and H. Aubin, "Extracting parameters from the current-voltage characteristics of field-effect transistors," Advanced Functional Materials, vol. 14, pp , 2004.
[4] G. Horowitz, M. E. Hajlaoui, and R. Hajlaoui, "Temperature and gate voltage dependence of hole mobility in polycrystalline oligothiophene thin film transistors," J. Appl. Phys., vol. 87, pp , 2000.
[5] Y. Roichman and N. Tessler, "Structures of polymer field-effect transistor: Experimental and numerical analyses," Applied Physics Letters, vol. 80, pp , 2002.
[6] Y. Roichman, Y. Preezant, and N. Tessler, "Analysis and modeling of organic devices," Physica Status Solidi a- Applied Research, vol. 201, pp , 2004.
[7] S. Shaked, S. Tal, Y. Roichman, A. Razin, S. Xiao, Y. Eichen, and N. Tessler, "Charge density and film morphology dependence of charge mobility in polymer field-effect transistors," Advanced Materials, vol. 15, pp , 2003.
[8] N. Tessler and Y. Roichman, "Two-dimensional simulation of polymer field-effect transistor," Applied Physics Letters, vol. 79, pp , 2001.
[9] L. Burgi, R. H. Friend, and H. Sirringhaus, "Formation of the accumulation layer in polymer field-effect transistors," Applied Physics Letters, vol. 82, pp , 2003.
[10] L. Burgi, H. Sirringhaus, and R. H. Friend, "Noncontact potentiometry of polymer field-effect transistors," Applied Physics Letters, vol. 80, pp , 2002.
[11] S. Scheinert and G. Paasch, "Fabrication and analysis of polymer field-effect transistors," Physica Status Solidi a-Applied Research, vol. 201, pp , 2004.
[12] E. J. Meijer, C. Tanase, P. W. M. Blom, E. van Veenendaal, B. H. Huisman, D. M. de Leeuw, and T. M. Klapwijk, "Switch-on voltage in disordered organic field-effect transistors," Applied Physics Letters, vol. 80, pp , 2002.
[13] C. Tanase, E. J. Meijer, P. W. M. Blom, and D. M. de Leeuw, "Unification of the hole transport in polymeric field-effect transistors and light-emitting diodes," Physical Review Letters, vol. 91, pp , 2003.
[14] G. Paasch and S. Scheinert, "Scaling organic transistors: materials and design," Materials Science-Poland, vol. 22, pp , 2004

62. It is very important to measure down to very low charge density
Our Model (for low field limit):
In FETs:
It is very important to measure
down to very low charge density
AND not force a single power law -8 -4 -3 -2 -1
VDS
2k=0.85±0.1
s≈5kT=130meV

63. Q* A system that is made of two identical molecules Wa
(Room Temperature)
-1000
1000
2000
3000
4000
5000
6000 E Q*
Reactants
Products A B A B Wa
As the molecules are identical it will be symmetric (charge on 1 is equivalent to charge on 2)

64. Q Would the electron transfer rate still follow exp(-qWa/kT)
A system that is made of two identical molecules
(Low Temperature)
-1000
1000
2000
3000
4000
5000
6000 E Q A B A B Wa
At low temperature the probability to acquire enough energy to bring the two molecules to the top of the barrier is VERY low.
In this case the electron may be exchanged at “non-ideal” configuration of the atoms or in other words there would be tunneling in the atoms configuration (atoms tunnel!).
Would the electron transfer rate still follow exp(-qWa/kT)

65. Trans-Resistor = TransistorG S D
Assumed m is constant
Assumed channel depth is negligible compared to insulator thickness so that C=COX (and VDS is small).
Trans-Resistor = Transistor

66. Trans-Resistor = TransistorG S D B
IDS
VDS
Vg1>VT
Vg2>Vg1
Vg3>Vg2
Vg4>Vg3
Trans-Resistor = Transistor

67. y x (a) (b) - 5V - 5V Gate 0V 0V 0V - 3V 0V - 1.5V Source Drain (c)
Region with no charge where all voltage beyond VG drops upon.

68. IDS
VDS
Vg>VT
Ranges
Saturation
Linear