Transcript Slide 1

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The organic (optoelectronic) revolution
What is optoelectronics?
The study and application of electronic devices that source, detect and control light
LEDs
CRT
lasers
solar cells
• the classical devices use inorganic materials: Si, GaN, Y2O2S:Eu, YAG:Nd
• 1987: Tang and van Slyke demonstrate the first organic optoelectronic device
• nowadays:
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PM
Advantages of organic versus inorganic LEDs
• synthetic flexibility
• tuning of chemical structure  different optical and electronic properties
• (potentially) very cheap production
- low temperature
- scalable to large area
• (potentially) very energy efficient
• new paradigm in the field
– ultra-thin and lightweight
– self-luminescent  no backlighting
– the substrates can be flexible or transparent
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Classes of organic emitters for OLEDs
• purely organic dyes
- fluorescent (limited to 25% efficiency)
- broad emission bands
- photo-bleaching
• organometallic complexes
- phosphorescent
(theoretical 100% efficiency)
- broad emission bands
- sensitivity to oxygen
• lanthanide complexes with organic ligands
- first example: Kido, 1990
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Properties of lanthanide ions
La
Ce
Pr
Nd Pm Sm Eu
Gd
Tb
Dy
Ho
Er
Tm
Shielding of 4f orbitals 
• similar chemical properties
• electrostatic bonding
• variable geometry and CNs
• hard acid behaviour
Yb
LnIII ground state
[Xe]4fn, n = 0..14
Lu
blue  NIR
Fascinating optical properties:
• luminescence from f-f transitions
• characteristic emission for each ion
• narrow emission bands
• long excited-states lifetimes
Applications in optoelectronics and bio-medicine
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Advantages of lanthanide complexes in optoelectronics
• sharp emission  pure colors (no filters)
• one ligand, different emission colors (even NIR)
• no oxygen sensitivity and no photo-bleaching
• easier coordination chemistry
f-f transitions are forbidden
the excited states cannot be efficiently populated directly
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Sensitization of lanthanide ions
Indirect excitation by energy transfer from a suitable antenna to the lanthanide ion
Antenna excitation
Light emission
Energy transfer
Antenna requirements:
• excellent energy harvester
• efficient inter-system crossing
• matching electronic levels
Deactivation:
• radiative processes (fluorescence, phosphorescence)
• non-radiative processes (vibration-induced)
• electronic processes (energy back-transfer)
1S
absorption
3T
Antenna
LnIII
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Antennas for lanthanides
organic chromophores (pyridines, phenantroline)
d-metal complexes (RuII, PtII, IrIII)
matrixes (PVK, CBP)
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The design of lanthanide complexes
Connecting the antenna to negatively charged groups (carboxylate)
Grenthe, J. Am. Chem. Soc. 1961
Bunzli, Spectrosc. Lett. 2007
Mazzanti, Angew. Chem. Int. Ed. 2005
Bunzli, Dalton Trans. 2000
Latva, J. Lumin. 1997
Associating the antenna to diketonate complexes
• low stability
• few structure-property relationships
• difficult optimization
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Luminescent lanthanide architectures for optoelectronics
• synthesize new stable lanthanide architectures
• tuned absorption and emission properties by ligand design
• investigate their potential for applications in optoelectronics
• high denticity ligands with negatively charged groups
• sensitizing antenna:
- organic chromophores
- d-metal complexes
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The tetrazole motif in coordination chemistry
• carboxylate often used for lanthanide coordination
• tetrazole - highly acidic, aromatic
• tetrazolate could replace carboxylate
• tuning of absorption wavelength
Tetrazole-based complexes of d-metals:
• high thermodynamic stability
• interesting properties
Very few examples in lanthanide coordination chemistry!
• no luminescent lanthanides
• no comparative studies
Aime, Tetrahedron Lett. 2002, 43, 783
Facchetti, Chem. Commun. 2004, 1770
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Lanthanide complexes based on pyridine-tetrazolates
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Design of tetrazole-based ligands
terpyridine ligands – pentadentate
bipyridine ligands – tetradentate
pyridine ligands – tridentate
• influence of tetrazolate on the properties of the complexes
• direct comparison with carboxylate analogues
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Organic synthesis of terpyridine-based ligands
Andreiadis et al, submitted; patent pending
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Organic synthesis of bipyridine-based ligands
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Organic synthesis of pyridine-based ligands
Easy access to tetrazole-based ligands
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Lanthanide complexes with terpyridine-based ligands
[Ln(L)2]-, Ln = Nd, Eu, Tb
the tetrazole-based ligands are well adapted to lanthanide complexation
Giraud, Inorg. Chem. 2008, 47, 3952-3954
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Lanthanide complexes with bipyridine-based ligands
[Ln(L)2]-, Ln = Eu, Tb
Andreiadis et al, submitted
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Lanthanide complexes with pyridine-based ligands
[Ln(L)3]3-, Ln = Nd, Eu, Tb
Andreiadis et al, submitted
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Increasing the solubility in chlorinated solvents
Solubility – strong advantage for the applications in OLED devices (wet process)
• ligand functionalization
• change of counterion
isolated as an oil
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Stability of tetrazolate-based complexes
• stable without dissociation in air and wet methanol solutions
• quantitative study by UV titration
L2-
L2-
[EuL2][EuL]+
[EuL2][EuL]+
logβ2 = 10.5(5)
logβ2 = 11.8(4)
Comparable stability to carboxylate analogues
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Absorption properties of pyridine-based complexes
[Ln(L)3]3-
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ε / 104 cm-1M-1
3
2
1
0
250
275
300
Wavelength / nm
325
350
aromatic tetrazolate  increase of absorption wavelength and intensity
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Absorption properties of bipyridine-based complexes
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[Ln(L)2]-
ε / 104 cm-1M-1
3
2
1
0
250
275
300
325
350
Wavelength / nm
375
400
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Absorption properties of terpyridine-based complexes
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ε / 104 cm-1M-1
8
6
4
[Ln(L)2]2
0
250
300
350
400
Wavelength / nm
450
500
substituents  tuning of absorption wavelength and intensity
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Photophysical properties of terpyridine-based complexes
Ligand triplet states
Modulation of ligand triplet state
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Photophysical properties of terpyridine-based complexes
Emission quantum yields
[Ln(L)2]Eu: 35%
Tb: 6%
Nd: 0.22%
Eu: 29%
Tb: 0.1%
Modulation of ligand triplet state
Eu: 36%
Tb: 35%
Nd: 0.09 %
Eu: 28%
Eu: 5%
Nd: 0.29%
Nd: 0.19%
 Tuning of emission quantum yields
Very good QY for Eu (35%) and Nd (0.29%)
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Photophysical properties of terpyridine-based complexes
Emission quantum yields
Terbium QY function of triplet state
[Ln(L)2]Eu: 35%
Tb: 6%
Nd: 0.22%
Eu: 29%
Tb: 0.1%
Eu: 36%
Tb: 35%
Nd: 0.09 %
Eu: 28%
Eu: 5%
Nd: 0.29%
Latva, J. Lumin. 1997
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Nd: 0.19%
Photophysical properties of bipyridine-based complexes
[Ln(L)2]-
Eu: 45%
Tb: 27%
Eu: 54%
Tb: 13%
Eu: 63%
Tb: 6%
Measured after drying
Similar tuning of emission quantum yields
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Photophysical properties of pyridine-based complexes
[Ln(L)3]3-
Eu: 61%
Tb: 65%
Nd: 0.21%
Eu: 39%
Eu: 24% *
Tb: 22% *
* Chauvin, Spectr. Lett. 2007, 40, 193
• excellent quantum yields
for pyridine-tetrazole complexes
• solubility in chlorinated solvents
Possible applications in OLEDs
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Neutral lanthanide diketonate complexes
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New approach towards neutral lanthanide complexes
Lanthanide complexes employed in optoelectronics
• neutral (vacuum processing)
• based on the β-diketonate motif
• additional soft, neutral ligands
• low stability
• dissociation during processing
Replacing neutral chromophores with negatively charged ones
for increasing the stability of the complex
Preliminary testing in OLED devices
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The terpyridine-monocarboxylate ligand
Terpyridine carboxylic acid leads to stable homoleptic mono- or poly-metallic complexes
Ln= Eu, Gd, Tb, Nd
Bretonnière, J. Am. Chem. Soc., 2002, 124, 9012
Chen, Inorg. Chem., 2007, 46, 625
[Ln
(LnL2)6](OTf)9
∩
[Ln(L)2](OTf)
formation of heteroleptic complexes with β-diketonate units:
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Synthesis and properties of the complexes
QY = 41%
• complexes stable in air and solution
• good quantum yields
QY = 13%
Investigate potential applications in OLED devices
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Preliminary testing in OLED devices
Excellent film-forming properties
(doping in PVK matrix)
Collaboration Dr. Pascal Viville (Univ. Mons)
• testing in OLED devices (spin-coating)
• classical device architecture
Al (cathode)
Cs2CO3
PVK : Ln complex
–
PEDOT:PPS
+
ITO (anode )
glass substrate
• the OLED devices display promising results
• rather low current intensities: 5.4 mA/cm2 at 25V (Eu)
45 mA/cm2 at 20V (Tb)
device optimization in progress
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Heterometallic iridium-europium complexes
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Sensitization of europium by d-metals
Indirect excitation using d-transitional metals by inter-metallic communication
• absorption at visible wavelength
• sensitization of NIR emitting lanthanides
• europium sensitization requires high energy
IrIII complexes - modulation of emission energy by the coordinated ligands
use blue-emitting Ir complexes
Thompson et al. Inorg Chem 2005, 44, 7992
Coppo, Angew. Chem. Int. Ed., 2005, 44, 1806
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Heterometallic complex - strategy and ligand design
Connecting the metal ions by a completely covalent structure (stability)
• terpyridine-tetrazolate motif for lanthanide complexation
• several target ligands investigated
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Synthesis of iridium-based ligand
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Synthesis of iridium-based ligand
• 1H NMR and X-ray diffraction studies prove the retention of Ir conformation during the synthesis
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Synthesis of the heterometallic complex
[Eu(L)2]1H
NMR indicates a similar structure
to the mono-metallic lanthanide complexes
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Protophysical properties of the heterometallic complex
QY = 0.96%
ex 400 nm
2,5
intensity / a.u.
2,0
ηIr-Eu = 85-90%
1,5
• iridium  europium energy transfer
• residual emission from iridium
1,0
• Eu emission due exclusively to Ir
• very good energy transfer efficiency
selective excitation of Ir moiety
0,5
0,0
300
400
500
600
wavelength / nm
700
800
promising architecture
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Final conclusions and perspectives
• tetrazole-based antennas for lanthanide
• combining stability with tuning
of absorption and emission properties
 extending the work to other architectures
(podates)
 applications in OLEDs
• improving the stability of neutral diketonate
complexes by using charged chromophores
 applications in OLEDs and surface grafting
• polyvalent stable heterometallic architecture
with very high Ir  Eu transfer efficiency
 improving europium emission efficiency
 extending the chemistry to other metals
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Acknowledgements
Prof. Luisa DE COLA, Prof. Jean WEISS, Prof. Muriel HISSLER, Dr. Guy ROYAL
Dr. Marinella MAZZANTI
Dr. Renaud DEMADRILLE
Dr. Daniel IMBERT
Dr. Jacques PECAUT
Yann KERVELLA, Dr. Bruno JOUSSELME, Prof. Alexander FISYUK
Colette LEBRUN, Pierre-Alain BAYLE
Dr. Pascal VIVILLE (Mons University), Prof. Jean-Claude BUNZLI (EPFL)
my colleagues and friends
European Community Marie Curie EST “CHEMTRONICS” MEST-CT-2005-020513
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