Co-reporter:Rakesh Kumar Behera, N. Rajesh Goud, Adam J. Matzger, Jean-Luc Brédas, and Veaceslav Coropceanu
The Journal of Physical Chemistry C October 26, 2017 Volume 121(Issue 42) pp:23633-23633
Publication Date(Web):October 1, 2017
DOI:10.1021/acs.jpcc.7b08360
We have investigated the electronic properties of four charge-transfer cocrystals involving 1,5-diaminonaphthalene (DAN) as donor and fluoranil (FA), chloranil (CA), bromanil (BA), and iodanil (IA) as acceptors. While DAN-FA, DAN-CA, and DAN-BA crystallized in a mixed-stack fashion, DAN-IA crystallized with segregated stacks. For the mixed-stack cocrystals, electronic-structure calculations using density functional theory predict large electron–hole couplings with small effective masses, which strongly suggests that these DAN-XA cocrystals are suitable for charge-transport applications. Among the four cocrystals, DAN-CA crystallized in a noncentrosymmetric space group; according to our computational analysis, it is predicted to be weakly ferroelectric with a second-order electrical susceptibility (χ(2)) similar to that of urea. The ionicities (ρ) of the cocrystals calculated using Mulliken population compare well with the experimental results. The couplings between donor and acceptor molecules in DAN-IA are very small, leading to a very small ρ. This is not typical for a system with a segregated-stack packing motif, indicating that hydrogen and halogen bondings can have a strong impact on the structure–property relations in cocrystals.
Co-reporter:Dongwook Kim, Veaceslav Coropceanu, and Jean-Luc Brédas
Journal of the American Chemical Society November 9, 2011 Volume 133(Issue 44) pp:17895-17900
Publication Date(Web):September 25, 2011
DOI:10.1021/ja207554h
Density functional theory calculations were carried out to investigate the electronic structures of representative ambipolar hosts for blue electroluminescence, based on two carbazole end groups and meta-terphenyl (mTP)-like bridges. The bridge molecular segments include mTP, 2,6-bisphenylpyridine, 3,5-bisphenylpyridine, and 2,6-bisphenylpyrimidine. While the ionization potentials and electron affinities of these molecules are mainly determined by their hole- and electron-transport subunits, respectively, each subunit impacts the electronic properties of the other upon their binding, mainly in an inductive way. Importantly, the lowest triplet state of the hosts is determined to be confined into the mTP-like bridges since these are the subunits with lowest individual triplet energy. Extension of the phenyl-based π-conjugated system via meta linkages is found to be effective in modulating the electron affinity value while maintaining a high triplet energy.
Co-reporter:Haoyuan Li, Anton D. Chavez, Huifang Li, Hong Li, William R. Dichtel, and Jean-Luc Bredas
Journal of the American Chemical Society November 15, 2017 Volume 139(Issue 45) pp:16310-16310
Publication Date(Web):October 23, 2017
DOI:10.1021/jacs.7b09169
The preparation of two-dimensional covalent organic frameworks (2D COFs) with large crystalline domains and controlled morphology is necessary for realizing the full potential of their atomically precise structures and uniform, tailorable porosity. Currently 2D COF syntheses are developed empirically, and most materials are isolated as insoluble and unprocessable powders with typical crystalline domain sizes smaller than 50 nm. Little is known about their nucleation and growth processes, which involve a combination of covalent bond formation, degenerate bond exchange, and noncovalent stacking processes. A deeper understanding of the chemical processes that lead to COF polymerization and crystallization is key to achieving improved materials quality and control. Here, we report a kinetic Monte Carlo (KMC) model that describes the formation of a prototypical boronate-ester linked 2D COF known as COF-5 from its 2,3,6,7,10,11-hexahydroxytriphenylene and 1,4-phenylene bis(boronic acid) monomers in solution. The key rate parameters for the KMC model were derived from experimental measurements when possible and complemented with reaction pathway analyses, molecular dynamics simulations, and binding free-energy calculations. The essential features of experimentally measured COF-5 growth kinetics are reproduced well by the KMC simulations. In particular, the simulations successfully captured a nucleation process followed by a subsequent growth process. The nucleating species are found to be relatively small, multilayer structures that form through multiple pathways. During the growth of COF-5, extensions in the lateral (in-plane) and vertical (stacking) directions are both seen to be linear with respect to time and are dominated by monomer addition and oligomer association, respectively. Finally, we show that the experimental observations of increased average crystallite size with the addition of water are modeled accurately by the simulations. These results will inform the rational development of 2D COF polymerizations by controlling the rate of nucleation, thereby increasing their materials quality.
Co-reporter:Jean-Luc Brédas (Associate Editor), Kristin Persson (Associate Editor), and Ram Seshadri (Associate Editor)
Chemistry of Materials March 28, 2017 Volume 29(Issue 6) pp:2399-2399
Publication Date(Web):March 28, 2017
DOI:10.1021/acs.chemmater.7b00990
Co-reporter:Veaceslav Coropceanu;Roel S. Sánchez-Carrera;Jean-Luc Brédas;Pavel Paramonov;Graeme M. Day
The Journal of Physical Chemistry C March 19, 2009 Volume 113(Issue 11) pp:4679-4686
Publication Date(Web):Publication Date (Web): February 20, 2009
DOI:10.1021/jp900157p
Recent theoretical studies suggest that the modulation of the electronic couplings (transfer integrals) between adjacent molecules by lattice vibrations, i.e., the so-called nonlocal electron−phonon coupling, plays a key role in the charge-transport properties of molecular organic semiconductors. However, a detailed understanding of this mechanism is still missing. Here, we combine density functional theory calculations and molecular mechanics simulations and use a chemistry-based insight to derive the nonlocal electron−phonon coupling constants due to the interaction of charge carriers with the optical lattice vibrations in the naphthalene crystal. The results point to a very strong coupling to both translational and librational intermolecular vibrational modes as well as to intramolecular modes. Along some crystal directions, the nonlocal interactions are found to be dominated by nontotally symmetric vibrational modes which lead to an alternation (Peierls-type dimerization) pattern. Importantly, we introduce two parameters that can be used: (i) to quantify the total strength of the nonlocal electron−vibration mechanism in the form of a reorganization energy term; and (ii) to define the extent of the thermal fluctuations of the electronic couplings. Interestingly, zero-point fluctuations are seen to be very significant.
Co-reporter:Haoyuan Li and Jean-Luc Brédas
The Journal of Physical Chemistry Letters June 1, 2017 Volume 8(Issue 11) pp:2507-2507
Publication Date(Web):May 18, 2017
DOI:10.1021/acs.jpclett.7b01161
Kinetic Monte Carlo (KMC) simulations have emerged as an important tool to help improve the efficiency of organic electronic devices by providing a better understanding of their device physics. In the KMC simulation of an organic device, the reliability of the results depends critically on the accuracy of the chosen charge-transfer rates, which are themselves strongly influenced by the site-energy differences. These site-energy differences include components coming from the electrostatic forces present in the system, which are often evaluated through electric potentials described by the Poisson equation. Here we show that the charge-carrier self-interaction errors that appear when evaluating the site-energy differences can lead to unreliable simulation results. To eliminate these errors, we propose two approaches that are also found to reduce the impact of finite-size effects. As a consequence, reliable results can be obtained at reduced computational costs. The proposed methodologies can be extended to other device simulation techniques as well.
Co-reporter:Stephen B. Shiring, Rebecca L. Gieseking, Chad Risko, and Jean-Luc Brédas
The Journal of Physical Chemistry C July 6, 2017 Volume 121(Issue 26) pp:14166-14166
Publication Date(Web):June 2, 2017
DOI:10.1021/acs.jpcc.7b03471
Cyanine dyes in dilute solution have demonstrated the required third-order nonlinear optical properties necessary for all-optical switching (AOS) applications. However, in the solid state, interactions between the cyanine and its counterion typically induce significant geometric and electronic changes. When the counterion localizes toward one end of the cyanine, symmetry is broken and the figure-of-merit for AOS is dramatically reduced. Here, we use quantum-chemical methods to assess zwitterionic cyanines based on the heptamethine thiopyrylium dye as a means to eliminate untethered counterion interactions. In these zwitterionic systems, rigid π-conjugated substituents oppositely charged to the cyanine backbone are added to the thiopyrylium central carbon atom. For substituents that are unable to retain their anionic charge, and thus have a lower degree of zwitterionic character, electronic coupling between the substituent and cyanine backbone leads to profound geometry modifications and the thiopyrylium excited-state properties advantageous for AOS are lost. The presence of strong electron withdrawing groups on the substituent allows it to retain more charge, which maintains the favorable cyanine character of the backbone. This improved understanding of the relationship between the zwitterionic cyanine chemical structure and molecular properties can pave the way to better materials for AOS devices.
Co-reporter:Jean-Luc Brédas
Chemistry of Materials 2017 Volume 29(Issue 2) pp:
Publication Date(Web):January 24, 2017
DOI:10.1021/acs.chemmater.6b04947
Co-reporter:Xian-Kai Chen;Tonghui Wang;Jean-Luc Brédas
Advanced Energy Materials 2017 Volume 7(Issue 15) pp:
Publication Date(Web):2017/08/01
DOI:10.1002/aenm.201602713
In the most efficient solar cells based on blends of a conjugated polymer (electron donor) and a fullerene derivative (electron acceptor),ultrafast formation of charge-transfer (CT) electronic states at the donor-acceptor interfaces and efficient separation of these CT states into free charges, lead to internal quantum efficiencies near 100%. However, there occur substantial energy losses due to the non-radiative recombinations of the charges, mediated by the loweset-energy (singlet and triplet) CT states; for example, such recombinations can lead to the formation of triplet excited electronic states on the polymer chains, which do not generate free charges. This issue remains a major factor limiting the power conversion efficiencies (PCE) of these devices. The recombination rates are, however, difficult to quantify experimentally. To shed light on these issues, here, an integrated multi-scale theoretical approach that combines molecular dynamics simulations with quantum chemistry calculations is employed in order to establish the relationships among chemical structures, molecular packing, and non-radiative recombination losses mediated by the lowest-energy charge-transfer states.
Co-reporter:Xian-Kai Chen;Youichi Tsuchiya;Yuma Ishikawa;Cheng Zhong;Chihaya Adachi;Jean-Luc Brédas
Advanced Materials 2017 Volume 29(Issue 46) pp:
Publication Date(Web):2017/12/01
DOI:10.1002/adma.201702767
AbstractIn the traditional molecular design of thermally activated delayed fluorescence (TADF) emitters composed of electron-donor and electron-acceptor moieties, achieving a small singlet–triplet energy gap (ΔEST) in strongly twisted structures usually translates into a small fluorescence oscillator strength, which can significantly decrease the emission quantum yield and limit efficiency in organic light-emitting diode devices. Here, based on the results of quantum-chemical calculations on TADF emitters composed of carbazole donor and 2,4,6-triphenyl-1,3,5-triazine acceptor moieties, a new strategy is proposed for the molecular design of efficient TADF emitters that combine a small ΔEST with a large fluorescence oscillator strength. Since this strategy goes beyond the traditional framework of structurally twisted, charge-transfer type emitters, importantly, it opens the way for coplanar molecules to be efficient TADF emitters. Here, a new emitter, composed of azatriangulene and diphenyltriazine moieties, is theoretically designed, which is coplanar due to intramolecular H-bonding interactions. The synthesis of this hexamethylazatriangulene-triazine (HMAT-TRZ) emitter and its preliminary photophysical characterizations point to HMAT-TRZ as a potential efficient TADF emitter.
Co-reporter:Thomas Körzdörfer and Jean-Luc Brédas
Accounts of Chemical Research 2014 Volume 47(Issue 11) pp:3284
Publication Date(Web):April 30, 2014
DOI:10.1021/ar500021t
ConspectusDensity functional theory (DFT) and its time-dependent extension (TD-DFT) are powerful tools enabling the theoretical prediction of the ground- and excited-state properties of organic electronic materials with reasonable accuracy at affordable computational costs. Due to their excellent accuracy-to-numerical-costs ratio, semilocal and global hybrid functionals such as B3LYP have become the workhorse for geometry optimizations and the prediction of vibrational spectra in modern theoretical organic chemistry. Despite the overwhelming success of these out-of-the-box functionals for such applications, the computational treatment of electronic and structural properties that are of particular interest in organic electronic materials sometimes reveals severe and qualitative failures of such functionals. Important examples include the overestimation of conjugation, torsional barriers, and electronic coupling as well as the underestimation of bond-length alternations or excited-state energies in low-band-gap polymers.In this Account, we highlight how these failures can be traced back to the delocalization error inherent to semilocal and global hybrid functionals, which leads to the spurious delocalization of electron densities and an overestimation of conjugation. The delocalization error for systems and functionals of interest can be quantified by allowing for fractional occupation of the highest occupied molecular orbital. It can be minimized by using long-range corrected hybrid functionals and a nonempirical tuning procedure for the range-separation parameter.We then review the benefits and drawbacks of using tuned long-range corrected hybrid functionals for the description of the ground and excited states of π-conjugated systems. In particular, we show that this approach provides for robust and efficient means of characterizing the electronic couplings in organic mixed-valence systems, for the calculation of accurate torsional barriers at the polymer limit, and for the reliable prediction of the optical absorption spectrum of low-band-gap polymers. We also explain why the use of standard, out-of-the-box range-separation parameters is not recommended for the DFT and/or TD-DFT description of the ground and excited states of extended, pi-conjugated systems. Finally, we highlight a severe drawback of tuned range-separated hybrid functionals by discussing the example of the calculation of bond-length alternation in polyacetylene, which leads us to point out the challenges for future developments in this field.
Co-reporter:Paul Winget;Laura K. Schirra;David Cornil;Hong Li;Veaceslav Coropceanu;Paul F. Ndione;Ajaya K. Sigdel;David S. Ginley;Joseph J. Berry;Jaewon Shim;Hyungchui Kim;Bernard Kippelen;Jean-Luc Brédas;Oliver L. A. Monti
Advanced Materials 2014 Volume 26( Issue 27) pp:4711-4716
Publication Date(Web):
DOI:10.1002/adma.201305351
Co-reporter:Rebecca L. Gieseking;Sukrit Mukhopadhyay;Chad Risko;Seth R. Marder;Jean-Luc Brédas
Advanced Materials 2014 Volume 26( Issue 1) pp:68-84
Publication Date(Web):
DOI:10.1002/adma.201302676
All-optical switching—controlling light with light—has the potential to meet the ever-increasing demand for data transmission bandwidth. The development of organic π-conjugated molecular materials with the requisite properties for all-optical switching applications has long proven to be a significant challenge. However, recent advances demonstrate that polymethine dyes have the potential to meet the necessary requirements. In this review, we explore the theoretical underpinnings that guide the design of π-conjugated materials for all-optical switching applications. We underline, from a computational chemistry standpoint, the relationships among chemical structure, electronic structure, and optical properties that make polymethines such promising materials.
Co-reporter:Sean M. Ryno ; Chad Risko ;Jean-Luc Brédas
Journal of the American Chemical Society 2014 Volume 136(Issue 17) pp:6421-6427
Publication Date(Web):April 11, 2014
DOI:10.1021/ja501725s
Polarization energy corresponds to the stabilization of the cation or anion state of an atom or molecule when going from the gas phase to the solid state. The decrease in ionization energy and increase in electron affinity in the solid state are related to the (electronic and nuclear) polarization of the surrounding atoms and molecules in the presence of a charged entity. Here, through a combination of molecular mechanics and quantum mechanics calculations, we evaluate the polarization energies in two prototypical organic semiconductors, pentacene and 6,13-bis(2-(tri-isopropylsilyl)ethynyl)pentacene (TIPS-pentacene). Comparison of the results for the two systems reveals the critical role played by the molecular packing configurations in the determination of the polarization energies and provides physical insight into the experimental data reported by Lichtenberger and co-workers (J. Amer. Chem. Soc. 2010, 132, 580; J. Phys. Chem. C 2010, 114, 13838). Our results underline that the impact of packing configurations, well established in the case of the charge-transport properties, also extends to the polarization properties of π-conjugated materials.
Co-reporter:Hong Li;Erin L. Ratcliff;Ajaya K. Sigdel;Anthony J. Giordano;Seth R. Marder;Joseph J. Berry;Jean-Luc Brédas
Advanced Functional Materials 2014 Volume 24( Issue 23) pp:3593-3603
Publication Date(Web):
DOI:10.1002/adfm.201303670
Gallium-doped zinc oxide (GZO) surfaces, both bare and modified with chemisorbed phosphonic acid (PA) molecules, are studied using a combination of density functional theory calculations and ultraviolet and X-ray photoelectron spectroscopy measurements. Excellent agreement between theory and experiment is obtained, which leads to an understanding of: i) the core-level binding energy shifts of the various oxygen atoms belonging to different surface sites and to the phosphonic acid molecules; ii) the GZO work-function change upon surface modification, and; iii) the energy level alignments of the frontier molecular orbitals of the PA molecules with respect to the valence band edge and Fermi level of the GZO surface. Importantly, both density of states calculations and experimental measurements of the valence band features demonstrate an increase in the density of states and changes in the characteristics of the valence band edge of GZO upon deposition of the phosphonic acid molecules. The new valence band features are associated with contributions from surface oxygen atoms near a defect site on the oxide surface and from the highest occupied molecular orbitals of the phosphonic acid molecules.
Co-reporter:Yao-Tsung Fu;Demetrio A. da Silva Filho;Gjergji Sini;Abdullah M. Asiri;Saadullah Gary Aziz;Chad Risko;Jean-Luc Brédas
Advanced Functional Materials 2014 Volume 24( Issue 24) pp:3790-3798
Publication Date(Web):
DOI:10.1002/adfm.201303941
Organic solar cells based on the combination of squaraine dyes (as electron donors) and fullerenes (as electron acceptors) have recently garnered much attention. Here, molecular dynamics simulations are carried out to investigate the evolution of a squaraine–C60 bilayer interface as a function of the orientation and order of the underlying squaraine layer. Electronic couplings between the main electronic states involved in exciton dissociation and charge (polaron pair) recombination are derived for donor–acceptor complexes extracted from the simulations. The results of the combined molecular-dynamics−quantum-mechanics approach provide insight into how the degree of molecular order and the dynamics at the interface impact the key processes involved in the photovoltaic effect.
Co-reporter:Hong Li, Paul Winget, and Jean-Luc Brédas
Chemistry of Materials 2014 Volume 26(Issue 1) pp:631
Publication Date(Web):October 4, 2013
DOI:10.1021/cm402113k
Transparent conducting oxides (TCO) are a critical component of many organic electronic devices including organic solar cells and light-emitting diodes. In this Perspective, we discuss what we have learned from our theoretical investigations, at the density functional theory (DFT) level, of the electronic structures of several technologically relevant transparent conducting oxides and their interfaces with organic layers. In particular, we describe how DFT calculations can be used to provide a detailed understanding of (i) the impact of surface modification by an organic monolayer on the interfacial electronic structure and the work function; (ii) the electronic characteristics of TCO surfaces as a function of surface hydroxylation and the presence of various intrinsic and extrinsic defects; and (iii) the nature of the charge transfer taking place between an organic semiconducting layer and a TCO electrode when considering the physisorption of a monolayer of π-conjugated organic molecules on the TCO surfaces.Keywords: density functional theory; hybrid organic−inorganic interfaces; organic electronics; surface modification; transparent conducting oxides; work-function modification;
Co-reporter:Cai-Rong Zhang, John S. Sears, Bing Yang, Saadullah G. Aziz, Veaceslav Coropceanu, and Jean-Luc Brédas
Journal of Chemical Theory and Computation 2014 Volume 10(Issue 6) pp:2379-2388
Publication Date(Web):April 28, 2014
DOI:10.1021/ct500259m
The characteristics of the electronic excited states and the charge-transfer processes at organic–organic interfaces play an important role in organic electronic devices. However, charge-transfer excitations have proven challenging to describe with conventional density functional theory (DFT) methodologies due to the local nature of the exchange-correlation potentials often employed. Here, we examine the excited states of model pentacene-C60 complexes using time-dependent DFT with, on one hand, one of the most popular standard hybrid functionals (B3LYP) and, on the other hand, several long-range corrected hybrid functionals for which we consider both default and nonempirically tuned range-separation parameters. The DFT results based on the tuned functionals are found to agree well with the available experimental data. The results also underline that the interface geometry of the complex has a strong effect on the energies and ordering of the singlet and triplet charge-transfer states.
Co-reporter:Xian-Kai Chen;Yao-Tsung Fu;Hong Li
Advanced Materials Interfaces 2014 Volume 1( Issue 9) pp:
Publication Date(Web):
DOI:10.1002/admi.201400362
Co-reporter:Theodoros A. Papadopoulos;Hong Li;Eung-Gun Kim;Jie Liu;James A. Cella;Christian M. Heller;Andrew Shu;Antoine Kahn;Anil Duggal;Jean-Luc Brédas
Israel Journal of Chemistry 2014 Volume 54( Issue 5-6) pp:779-788
Publication Date(Web):
DOI:10.1002/ijch.201400041
Abstract
At metal/organic interfaces, the insertion of an organic monolayer can significantly modify the surface properties of the substrate, especially in terms of charge injection across the interface. Herein, we study the formation of an insulating monolayer of morpholine or amine-functionalized polystyrene on Al(111) and Au(111) surfaces and its impact on surface work-function and charge injection. First-principles calculations based on Density Functional Theory have been carried out and point to a significant decrease in the work-function of modified metal surfaces; this is in very good agreement with ultraviolet photoemission spectroscopy measurements performed on the Au(111) surface. In addition, a bilayer cathode, consisting of a thin film of high-work-function metal, such as Al and Au, and a layer of amine-functionalized polystyrene, was also fabricated and tested in organic light-emitting diodes. Such bilayer structures exhibit substantially enhanced efficiency when compared with controls without the functionalized polymers. Our combined theoretical and experimental investigation gives insight into how a thin layer of a commodity polymer can be used to transform rather high-work-function metals into high-performance cathodes to provide efficient electron injection.
Co-reporter:Christopher Sutton ; Thomas Körzdörfer ; Veaceslav Coropceanu ;Jean-Luc Brédas
The Journal of Physical Chemistry C 2014 Volume 118(Issue 8) pp:3925-3934
Publication Date(Web):January 10, 2014
DOI:10.1021/jp410461v
The electronic coupling between redox sites in mixed-valence systems has attracted the interest of the chemistry community for a long time. Many computational studies have focused on trying to determine its magnitude as a function of the nature of the redox sites and of the bridge(s) between them. However, in most instances, the quantum-chemical methodologies that have been employed suffer from intrinsic errors that lead to either an overlocalized or an overdelocalized character of the electronic structure. These deficiencies prevent an accurate depiction of the degree of charge (de)localization in the system and, as a result, of the extent of electronic coupling. Here we use nonempirically tuned long-range corrected density functional theory and show that it provides a robust, efficient approach to characterize organic mixed-valence systems. We first demonstrate the performance of this approach via a study of representative Robin–Day class-II (localized) and class-III (delocalized) complexes. We then examine a borderline class-II/class-III complex, which had proven difficult to describe accurately with standard density functional theory and Hartree–Fock methods.
Co-reporter:Lingyun Zhu ; Yuanping Yi ; Alexandr Fonari ; Nathan S. Corbin ; Veaceslav Coropceanu ;Jean-Luc Brédas
The Journal of Physical Chemistry C 2014 Volume 118(Issue 26) pp:14150-14156
Publication Date(Web):June 11, 2014
DOI:10.1021/jp502411u
The electronic structures of a series of donor–acceptor mixed-stack crystals have been investigated by means of density functional theory calculations. The results highlight that a number of the donor–acceptor crystals under consideration are characterized by wide valence and conduction bands, large hole and electron electronic couplings, and as a result very low hole and electron effective masses. The fact that the effective masses and electronic couplings for holes and electrons are nearly equal along the stacking directions implies that the hole and electron mobilities in these systems are also similar. In addition, in several of these crystals, charge transport has a two-dimensional character. The impact on the charge transport properties of the electronic couplings between donor and acceptor frontier orbitals and of the related energy gaps is also discussed.
Co-reporter:Yao-Tsung Fu;YuanPing Yi;Veaceslav Coropceanu;Chad Risko
Science China Chemistry 2014 Volume 57( Issue 10) pp:1330-1339
Publication Date(Web):2014 October
DOI:10.1007/s11426-014-5184-x
We review some of the computational methodologies used in our research group to develop a better understanding of the geometric and electronic structures of organic-organic interfaces present in the active layer of organic solar cells. We focus in particular on the exciton-dissociation and charge-transfer processes at the pentacene-fullerene interface. We also discuss the local morphology at this interface on the basis of molecular dynamics simulations.
Co-reporter:Lucas Viani, Chad Risko, Michael F. Toney, Dag W. Breiby, and Jean-Luc Brédas
ACS Nano 2014 Volume 8(Issue 1) pp:690
Publication Date(Web):December 26, 2013
DOI:10.1021/nn405399n
Charge-carrier transport in thin-film organic field-effect transistors takes place within the first (few) molecular layer(s) of the active organic material in contact with the gate dielectric. Here, we use atomistic molecular dynamics simulations to evaluate how interactions with bare amorphous silica surfaces that vary in terms of surface potential influence the molecular packing and dynamics of a monolayer pentacene film. The results indicate that the long axis of the pentacene molecules has a non-negligible tilt angle away from the surface normal. Grazing-incidence X-ray diffraction patterns for these models are calculated, and we discuss notable differences in the shapes of the Bragg rods as a function of the molecular packing, also in relation to previously published experimental reports. Intermolecular electronic couplings (transfer integrals) evaluated for the monolayers show marked differences compared to bulk crystal calculations, a result that points to the importance of fully considering the molecular packing environment in charge-carrier mobility models for organic electronic materials.Keywords: charge-carrier transport; organic−inorganic interface; X-ray scattering simulations
Co-reporter:Cai-Rong Zhang, Veaceslav Coropceanu, John S. Sears, and Jean-Luc Brédas
The Journal of Physical Chemistry C 2014 Volume 118(Issue 1) pp:154-158
Publication Date(Web):December 10, 2013
DOI:10.1021/jp4095326
Oligoacenes such as naphthalene, anthracene, tetracene, and pentacene are among the best hole-transport organic semiconductors. An important parameter in the determination of the hole mobility is the coupling between the charge carrier and the vibrational modes. Here, we have evaluated the hole–vibration coupling constants in the radical-cation ground state of these molecules by means of the range-separated LC-ωPBE and ωB97 density functionals, with non-empirical optimization of the range-separation parameter ω. Our results indicate that both ω-tuned functionals yield similar relaxation energies and coupling constants. A comparison of the simulated vibrational structures of the first ionization band to the gas-phase ultraviolet photoelectron spectroscopy data underlines that the hole–vibration coupling constants derived by means of the non-empirically tuned LC-ωPBE and ωB97 functionals are in excellent agreement with experiment and superior to those derived from B3LYP calculations.
Co-reporter:Rebecca L. Gieseking, Sukrit Mukhopadhyay, Chad Risko, and Jean-Luc Brédas
ACS Photonics 2014 Volume 1(Issue 3) pp:261
Publication Date(Web):February 24, 2014
DOI:10.1021/ph4001444
Designing molecular materials with the figures-of-merit needed for all-optical switching applications requires that, at the wavelengths of interest, the molecules have large real components |Re(γ)| of the third-order polarizability (γ) while at the same time maintaining small imaginary components Im(γ). Polymethines have the potential to meet these conditions, though to date only a few polymethines exhibit large enough |Re(γ)/Im(γ)| for device applications. From the sum-over-states expression for γ, it can be deduced that when the transition dipole moment (μee′) between the polymethine first and second excited states is minimized, Im(γ) decreases and |Re(γ)| increases. Here, focusing on a series of streptocyanines, we decompose μee′ into the transition dipole components of the constituent electronic transitions and investigate how variations in chain length and substitution patterns alter μee′. The second, two-photon-allowed, excited state is shown to be composed primarily of three excitations, two of which contribute to μee′ in an additive fashion, while the third reduces the magnitude of μee′. As the conjugation path length growths, the competition between two factors, (i) the increased wave function overlap in each constituent transition vs (ii) the increased influence of the electronic configuration with a negative contribution to μee′, results in a weak dependence of μee′ on length. Electron-donating and -withdrawing substituents are shown to affect μee′ by influencing the energetic spacing of the first few frontier molecular orbitals, which offers a path for further tuning of μee′; in particular, it is found that a large energetic spacing between the HOMO–1 and HOMO levels and between the LUMO and LUMO+1 levels is a critical feature to achieve small μee′ values.Keywords: all-optical switching; cyanines/polymethines; nonlinear optics; transition dipole moment
Co-reporter:Yao-Tsung Fu;Chad Risko;Jean-Luc Brédas
Advanced Materials 2013 Volume 25( Issue 6) pp:878-882
Publication Date(Web):
DOI:10.1002/adma.201203412
Co-reporter:Naga Rajesh Tummala;Shafigh Mehraeen;Yao-Tsung Fu;Chad Risko;Jean-Luc Brédas
Advanced Functional Materials 2013 Volume 23( Issue 46) pp:5800-5813
Publication Date(Web):
DOI:10.1002/adfm.201300918
Abstract
The ability to detail how molecules pack in the bulk and at the various materials interfaces in the active layer of an organic solar cell is important to further understanding overall device performance. Here, [6,6]-phenyl-C61-butyric acid methyl ester (PCBM), a preferred electron-acceptor material in organic solar cells, is studied through molecular dynamics (MD) simulations; the goal is to examine the effects of temperature and trace solvents on the packing and morphological features of bulk PCBM. Solubility (miscibility) parameters, melting and order-disorder transitions, surface energies, and orientational distributions as a function of different starting configurations are discussed. On the basis of the derived morphologies, electronic structure calculations and a kinetic Monte Carlo approach are combined to evaluate the parameters impacting electron mobility in crystalline and amorphous PCBM structures.
Co-reporter:Theodoros A. Papadopoulos;Jens Meyer;Hong Li;Zelei Guan;Antoine Kahn;Jean-Luc Brédas
Advanced Functional Materials 2013 Volume 23( Issue 48) pp:6091-6099
Publication Date(Web):
DOI:10.1002/adfm.201301466
Abstract
A combination of density functional theory and experimental measurements via ultraviolet and X-ray photoelectron spectroscopies is used to explore the nature of the interface between the stoichiometric molybdenum trioxide (MoO3) or its under-stoichiometric counterpart with oxygen vacancies, and an organic hole-transport layer represented by 4,4′-N,N′-dicarbazole-biphenyl (CBP). Upon adsorption of CBP, special attention is paid to i) the appearance of gap states and the reduction of the molybdenum oxide surface, and ii) the evolution of the work function. Very good agreement is found between theory and experiment. The near alignment of the CBP highest occupied molecular orbital with the Fermi level and the conduction band edge of molybdenum oxide points to facile hole collection or injection.
Co-reporter:Kathryn A. McGarry, Wei Xie, Christopher Sutton, Chad Risko, Yanfei Wu, Victor G. Young Jr., Jean-Luc Brédas, C. Daniel Frisbie, and Christopher J. Douglas
Chemistry of Materials 2013 Volume 25(Issue 11) pp:2254
Publication Date(Web):May 28, 2013
DOI:10.1021/cm400736s
Correlations among the molecular structure, crystal structure, electronic structure, and charge-carrier transport phenomena have been derived from six congeners (2–7) of rubrene (1). The congeners were synthesized via a three-step route from known 6,11-dichloro-5,12-tetracenedione. After crystallization, their packing structures were solved using single-crystal X-ray diffraction. Rubrenes 5–7 maintain the orthorhombic features of the parent rubrene (1) in their solid-state packing structures. Control of the packing structure in 5–7 provided the first series of systematically manipulated rubrenes that preserve the π-stacking motif of 1. Density functional theory calculations were performed at the B3LYP/6-31G(d,p) level of theory to evaluate the geometric and electronic structure of each derivative and reveal that key properties of rubrene (1) have been maintained. Intermolecular electronic couplings (transfer integrals) were calculated for each derivative to determine the propensity for charge-carrier transport. For rubrenes 5–7, evaluations of the transfer integrals and periodic electronic structures suggest these derivatives should exhibit transport characteristics equivalent to, or in some cases improved on, those of the parent rubrene (1), as well as the potential for ambipolar behavior. Single-crystal field-effect transistors were fabricated for 5–7, and these derivatives show ambipolar transport as predicted. Although device architecture has yet to be fully optimized, maximum hole (electron) mobilities of 1.54 (0.28) cm2 V–1 s–1 were measured for rubrene 5. This work lays a foundation to improve our understanding of charge-carrier transport phenomena in organic single-crystal semiconductors through the correlation of designed molecular and crystallographic changes to electronic and transport properties.Keywords: ambipolar transport; crystal engineering; electronic band structure; rubrene derivatives; single-crystal field-effect transistors;
Co-reporter:Bruno Grimm, Chad Risko, Jason D. Azoulay, Jean-Luc Brédas and Guillermo C. Bazan
Chemical Science 2013 vol. 4(Issue 4) pp:1807-1819
Publication Date(Web):06 Feb 2013
DOI:10.1039/C3SC22188A
We discuss donor–acceptor conjugated polymers where the acceptor moieties are orthogonal to the donor-based backbone direction through the synthesis and study of a new class of materials (including six oligomers and three polymers) based on 4H-cyclopentadithiophene (CPDT) with an imine functionality introduced at the CPDT bridgehead position. Absorption spectroscopy provides information on the influence of structure on the optical properties. We paid special attention to the energies and oscillator strengths of the low-energy transitions and how they correlate with chain length. When the orthogonally conjugated materials are compared to a more traditional polymer, where the donor and acceptor fragments are in series along the backbone direction, fundamental differences in the optical properties are observed. Quantum-mechanical studies of the geometric structure, electronic structure, and excited-state vertical transitions using density functional theory unravel the interplay of structural design and resulting optoelectronic properties. Our findings underline that the magnitude and orientation relative to the backbone long axis of the transition dipole moment is key in designing narrow optical-gap materials with large absorption cross-sections and oscillator strengths.
Co-reporter:Demetrio A. da Silva Filho, Veaceslav Coropceanu, Nadine E. Gruhn, Pedro Henrique de Oliveira Neto and Jean-Luc Brédas
Chemical Communications 2013 vol. 49(Issue 54) pp:6069-6071
Publication Date(Web):22 May 2013
DOI:10.1039/C3CC42003E
We report a high-resolution gas-phase UPS spectrum of zinc phthalocyanine (ZnPc) together with a detailed analysis of the vibronic structure of the first ionization band, showing that ZnPc presents the lowest value of the intramolecular reorganization energy experimentally reported for a molecular organic semiconductor.
Co-reporter:Huifang Li, Paul Winget, Chad Risko, John S. Sears and Jean-Luc Brédas
Physical Chemistry Chemical Physics 2013 vol. 15(Issue 17) pp:6293-6302
Publication Date(Web):26 Feb 2013
DOI:10.1039/C3CP50631B
The development and application of phosphorescent emitters in organic light-emitting diodes (OLEDs) have played a critical role in the push to commercialization of OLED-based display and lighting technologies. Here, we use density functional theory methods to study how modifying the ancillary ligand influences the electronic and photophysical properties of heteroleptic bis(4,6-difluorophenyl) pyridinato-N,C [dfppy] iridium(III) complexes. We examine three families of bidentate ancillary ligands based on acetylacetonate, picolinate, and pyridylpyrazolate. It is found that the frontier molecular orbitals of the heteroleptic complexes can be substantially modulated both as a function of the bidentate ligand family and of the substitution patterns within a family. As a consequence, considerable control over the first absorption and phosphorescence emission transitions, both of which are dominated by one-electron transitions between the HOMO and LUMO, is obtained. Tuning the nature of the ancillary ligand, therefore, can be used to readily modulate the photophysical properties of the emitters, providing a powerful tool in the design of the emitter architecture.
Co-reporter:Eung-Gun Kim, Jean-Luc Brédas
Organic Electronics 2013 Volume 14(Issue 2) pp:569-574
Publication Date(Web):February 2013
DOI:10.1016/j.orgel.2012.11.028
We propose a new structural model for the Al(1 1 1)/Al2O3(0 0 0 1) interface based on density functional theory calculations. The ultrathin interface structure is shown to consist of two Al layers, one that is oxide-like and the other metal-like. Our model interface reproduces the barrier height to the oxide conduction band edge and predicts the oxide overlayer to lower the metal work function by 0.49 eV.Graphical abstract.Highlights► Determination at the density functional theory level of a new structural model for the Al(1 1 1)/Al2O3(0 0 0 1) interface. ► Determination of an ultrathin interface consisting of a metal-like layer and an oxide-like layer. ► Reproduction of a barrier height of 3.2 eV at the interface. ► Prediction of a work function reduction of 0.49 eV in passing through the oxide.
Co-reporter:Lingyun Zhu, Veaceslav Coropceanu, Yuanping Yi, Bhaskar Chilukuri, Thomas R. Cundari, and Jean-Luc Brédas
The Journal of Physical Chemistry Letters 2013 Volume 4(Issue 13) pp:2186-2189
Publication Date(Web):June 18, 2013
DOI:10.1021/jz400950v
Density functional theory was used to investigate the electronic and charge-transport properties of the trinuclear gold Au3(CH3N═COCH3)3 crystal. Hole transport is found to be anisotropic and characterized by a very small effective mass of about 0.21 m0 along the stacking direction of the Au3 molecules. Interestingly, the calculations suggest an isotropic character of electron transport, for which the effective mass is about 1 m0. We show that while the interstack interactions facilitate electron transport in the directions perpendicular to the stacks, they act to diminish this transport along the stacking directions. Overall, the present results indicate that this compound is a promising ambipolar material for application in electronic devices.Keywords: ambipolar charge transport; density functional theory; gold-trimer complexes; organic electronics; organo-metallic complexes;
Co-reporter:Dr. Karl J. Thorley;Dr. Joel M. Hales;Hyeongeu Kim;Dr. Shino Ohira; Jean-Luc Brédas; Joseph W. Perry; Harry L. Anderson
Chemistry - A European Journal 2013 Volume 19( Issue 31) pp:10370-10377
Publication Date(Web):
DOI:10.1002/chem.201300609
Abstract
Herein, the synthesis and properties of alkyne-bridged carbocations, which are analogous in structure to cyanine dyes, are reported. An alkene-bridged dye, linked at the third position of the indole, was also synthesized as a reference compound. These new carbocations are stable under ambient conditions, allowing characterization by UV/Vis and NMR (1H and 13C) spectroscopies. These techniques revealed a large degree of delocalization of the positive charge, similar to a previously reported porphyrin carbocation. The linear and nonlinear optical properties are compared with cyanine dyes and triarylmethyl cations, to investigate the effects of the bond-length alternation and the overall molecular geometry. The value of Re(γ), the real part of the third-order microscopic polarizability, of −1.3×10−33 esu for the alkyne-linked cation is comparable to that of a cyanine dye of similar length. Nondegenerate two-photon absorption spectra showed that the alkene-bridged dye exhibited characteristics of cyanines, whereas the alkyne-bridged dye is reminiscent of octupolar chromophores, such as the triarylmethyl carbocation brilliant green. Such attributes were confirmed and rationalized by quantum chemical calculations.
Co-reporter:Christopher Sutton, John S. Sears, Veaceslav Coropceanu, and Jean-Luc Brédas
The Journal of Physical Chemistry Letters 2013 Volume 4(Issue 6) pp:919-924
Publication Date(Web):March 1, 2013
DOI:10.1021/jz3021292
We present an analysis of the magnitude of density functional theory (DFT)-calculated intermolecular electronic couplings (transfer integrals) in organic semiconductors to give insight into the impact that the choice of functional has on the value of this parameter, which is particularly important in the context of charge transport. The major factor determining the magnitude of the calculated transfer integrals is the amount of nonlocal Hartree–Fock (HF) exchange within a given functional, with the transfer integrals increasing by up to a factor of 2 when going from 0 to 100% HF exchange for a series of conventional functionals. We underline that these variations in the transfer integrals are in fact to be expected, with the computed transfer integrals evolving linearly with the amount of HF exchange. We also use a long-range corrected functional to tune the contributions of (semi)local and nonlocal HF exchanges and highlight their respective roles as a function of intermolecular separation.Keywords: charge transport; exchange; hybrid functional; long-range corrected functional; organic semiconductor; transfer integral;
Co-reporter:Sean M. Ryno, Stephen R. Lee, John S. Sears, Chad Risko, and Jean-Luc Brédas
The Journal of Physical Chemistry C 2013 Volume 117(Issue 27) pp:13853-13860
Publication Date(Web):June 14, 2013
DOI:10.1021/jp402991z
Understanding the nature and magnitude of the electronic polarization due to the presence of a charge carrier in organic molecular solids is of fundamental importance in the description of charge-carrier transport. We present an approach to study these effects based on a polarizable force field that accounts for charge, dipole, quadrupole, and induced-dipole interactions. To demonstrate its general applicability, the method is applied to the oligoacene crystal series (naphthalene through pentacene) and perfluorinated derivatives of naphthalene and pentacene. Very good qualitative agreement with experimental results is achieved in terms of both the magnitude and asymmetry of the polarization as a function of the sign of the injected charge, with improved quantitative agreement versus previous theoretical assessments.
Co-reporter:Hong Li;Paul Winget
Advanced Materials 2012 Volume 24( Issue 5) pp:687-693
Publication Date(Web):
DOI:10.1002/adma.201103009
Co-reporter:Eunkyung Cho ; Chad Risko ; Dongwook Kim ; Roman Gysel ; Nichole Cates Miller ; Dag W. Breiby ; Michael D. McGehee ; Michael F. Toney ; R. Joseph Kline
Journal of the American Chemical Society 2012 Volume 134(Issue 14) pp:6177-6190
Publication Date(Web):February 29, 2012
DOI:10.1021/ja210272z
We use a systematic approach that combines experimental X-ray diffraction (XRD) and computational modeling based on molecular mechanics and two-dimensional XRD simulations to develop a detailed model of the molecular-scale packing structure of poly(2,5-bis (3-tetradecylthiophene-2-yl)thieno[3,2-b]thiophene) (PBTTT-C14) films. Both uniaxially and biaxially aligned films are used in this comparison and lead to an improved understanding of the molecular-scale orientation and crystal structure. We then examine how individual polymer components (i.e., conjugated backbone and alkyl side chains) contribute to the complete diffraction pattern, and how modest changes to a particular component orientation (e.g., backbone or side-chain tilt) influence the diffraction pattern. The effects on the polymer crystal structure of varying the alkyl side-chain length from C12 to C14 and C16 are also studied. The accurate determination of the three-dimensional polymer structure allows us to examine the PBTTT electronic band structure and intermolecular electronic couplings (transfer integrals) as a function of alkyl side-chain length. This combination of theoretical and experimental techniques proves to be an important tool to help establish the relationship between the structural and electronic properties of polymer thin films.
Co-reporter:Sukrit Mukhopadhyay, Chad Risko, Seth R. Marder and Jean-Luc Brédas
Chemical Science 2012 vol. 3(Issue 10) pp:3103-3112
Publication Date(Web):17 Jul 2012
DOI:10.1039/C2SC20861J
Polymethine dyes have recently demonstrated promise for all-optical switching applications at telecommunications wavelengths as they can combine large refractive optical nonlinearities with low single-photon and two-photon optical losses. Here, we use density functional theory and symmetry-adapted cluster configuration interaction calculations to characterize model streptocyanine molecules. We first consider the isolated, closed-shell cationic molecules and then complexes formed by the molecules with chloride counter-ions and a series of aggregates. Our goal is to examine the influence of: (i) the presence of counter-ions and (ii) aggregation on the electronic structure and nonlinear optical properties. We find that the counter-ions increase the degree of bond-length alternation along the cyanine backbone, while aggregation significantly reduces the energy window between the lowest one-photon and two-photon excited states. Our results provide insight toward the design of new polymethine derivatives that could maintain large figures-of-merit for all-optical switching applications in the solid state.
Co-reporter:Dongwook Kim, Lingyun Zhu, and Jean-Luc Brédas
Chemistry of Materials 2012 Volume 24(Issue 13) pp:2604
Publication Date(Web):June 13, 2012
DOI:10.1021/cm301416n
We report the results of Density Functional Theory calculations on a series of carbazole-based phosphine oxides that experimental data have shown to be promising ambipolar host molecules for deep blue electrophosphorescence. The hosts under investigation contain either 1, 2, or 3 carbazole subunits attached to the phenyl rings of a triphenylphosphoryl group, with the carbazoles acting as hole transporters/acceptors and the triphenylphosphoryl groups as electron transporters/acceptors. The results underline that, in addition to the strong inductive effect of the phosphoryl groups, the LUMO of these hosts is further stabilized by the molecular orbital interactions among the phenyl rings of the triphenylphosphoryl group, which is modulated by the electron-withdrawing inductive effects of the carbazole subunits. The lowest triplet state of the hosts correspond to localized transitions within the carbazole units, which leads to a high triplet energy on the order of 3 eV. We describe the important buffer role of the phenyl rings in preventing the phosphoryl moiety from negatively affecting the hole-accepting characteristics and high triplet energies of the carbazole units.Keywords: ambipolar hosts; deep blue OLED; DFT calculation; electroluminescence; phosphine oxides;
Co-reporter:Hong Li, Laura K. Schirra, Jaewon Shim, Hyeunseok Cheun, Bernard Kippelen, Oliver L. A. Monti, and Jean-Luc Bredas
Chemistry of Materials 2012 Volume 24(Issue 15) pp:3044
Publication Date(Web):June 29, 2012
DOI:10.1021/cm301596x
The technology-relevant zinc-terminated zinc oxide (0002) polar surface has been studied at the density-functional theory level using both Perdew–Burke–Ernzerhof (PBE) and hybrid Heyd–Scuseria–Ernzerhof (HSE06) functionals. We have considered a number of surface conditions to better understand the impact of surface hydroxylation and intrinsic and extrinsic surface defects, including zinc vacancies, oxygen vacancies, zinc interstitials, and aluminum dopants on the surface electronic properties. Our calculations point to large variations in surface work function and energy band gap as a function of the surface model; these variations can be attributed to changes in surface charge carrier density and to additional surface states induced by the defects. The calculated shifts in O(1s) core-level binding energy of the surface oxygens in different bonding configurations are in good agreement with experimental X-ray photoelectron spectroscopy data and point to the presence of two distinct OH-species on the ZnO surface. Our results also show that the electron-compensation centers induced by zinc vacancies can be stabilized by intrinsic and/or extrinsic n-type doping near the surface; such n-type doping can lead to better performance of organic opto-electronic devices in which zinc oxide is used as an electron-selective interlayer.Keywords: conducting oxide; DFT slab calculations; surface defects; work-function determination; zinc oxide;
Co-reporter:Laxman Pandey, Curtis Doiron, John S. Sears and Jean-Luc Brédas
Physical Chemistry Chemical Physics 2012 vol. 14(Issue 41) pp:14243-14248
Publication Date(Web):09 Aug 2012
DOI:10.1039/C2CP41724C
Polymers with low optical gaps are of importance to the organic photovoltaics community due to their potential for harnessing a large portion of the solar energy spectrum. The combination along their backbones of electron-rich and electron-deficient fragments contributes to the presence of low-lying excited states that are expected to display significant charge-transfer character. While conventional hybrid functionals are known to provide unsatisfactory results for charge-transfer excitations at the time-dependent DFT level, long-range corrected (LRC) functionals have been reported to give improved descriptions in a number of systems. Here, we use such LRC functionals, considering both tuned and default range-separation parameters, to characterize the absorption spectra of low-optical-gap systems of interest. Our results indicate that tuned LRC functionals lead to simulated optical-absorption properties in good agreement with experimental data. Importantly, the lowest-lying excited states (excitons) are shown to present a much more localized nature than initially anticipated.
Co-reporter:Laxman Pandey, Chad Risko, Joseph E. Norton, and Jean-Luc Brédas
Macromolecules 2012 Volume 45(Issue 16) pp:6405-6414
Publication Date(Web):July 30, 2012
DOI:10.1021/ma301164e
We systematically investigate at the density functional theory level how changes to the chemical structure of donor–acceptor copolymers used in a number of organic electronics applications influences the intrinsic geometric, electronic, and optical properties. We consider the combination of two distinct donors, where a central five-membered ring is fused on both sides by either a thiophene or a benzene ring, with 12 different acceptors linked to the donor either directly or through thienyl linkages. The interplay between the electron richness/deficiency of the subunits as well as the evolution of the frontier electronic levels of the isolated donors/acceptors plays a significant role in determining the electronic and optical properties of the copolymers.
Co-reporter:Christopher Wood, Hong Li, Paul Winget, and Jean-Luc Brédas
The Journal of Physical Chemistry C 2012 Volume 116(Issue 36) pp:19125-19133
Publication Date(Web):August 8, 2012
DOI:10.1021/jp3050725
The interfaces formed between a zinc-terminated polar zinc oxide (0002) surface and a series of chemisorbed fluorinated benzylphosphonic acids have been studied at the density functional theory level. The results indicate that there occur substantial changes in the adsorption energy and surface work function whether the binding mode is bidentate or tridentate. Also, the trends and magnitude of the various factors that determine the total modifications in work function markedly vary between the two binding modes. We have also calculated the oxygen core-level binding energy shifts of the PO3 moiety with respect to the oxygen atoms in bulk ZnO; good agreement is obtained between the calculated values of the core-level binding energy shifts for the tridentate binding mode and available X-ray photoelectron spectroscopy data.
Co-reporter:Yuan Li, Veaceslav Coropceanu, and Jean-Luc Brédas
The Journal of Physical Chemistry Letters 2012 Volume 3(Issue 22) pp:3325-3329
Publication Date(Web):October 26, 2012
DOI:10.1021/jz301575u
We report on electronic-structure calculations for the pentacene and rubrene crystals, based on experimental crystal geometries measured at different temperatures. The results are in very good agreement with angle-resolved photoelectron spectroscopy data that indicate that the widths of the valence and conduction bands in both materials become narrower at higher temperatures. Our findings strongly suggest that the thermal bandwidth narrowing in the pentacene and rubrene crystals is primarily caused by the thermal expansion of the lattice rather than by a renormalization of the transfer integrals induced by a polaron effect. The effect of thermal expansion on the charge-transport properties is also discussed.Keywords: band narrowing; charge transport; electron−phonon coupling; organic semiconductor crystals; polaron effect;
Co-reporter:Yuanping Yi ; Lingyun Zhu ;Jean-Luc Brédas
The Journal of Physical Chemistry C 2012 Volume 116(Issue 8) pp:5215-5224
Publication Date(Web):February 1, 2012
DOI:10.1021/jp210778w
The charge-transport parameters in a series of naphthodithiophene (NDT) and anthradithiophene (ADT) derivatives are investigated by means of density functional theory and molecular dynamics calculations. In the case of unsubstituted and alkylated NDT and ADT crystals, the results point to small effective masses for the charge carriers along either essentially one dimension (π-stacks) or two dimensions (within the molecular layers), i.e., where large electronic couplings or band widths are present. Interestingly, diphenyl substitutions can lead to small effective masses for both holes and electrons along the three dimensions. This implies that one-, two-, or three-dimensional charge-transport mechanisms can be realized in the alkyl and phenyl NDT and ADT crystals. In particular, the smallest effective mass (and, as a result, the largest expected charge-carrier mobility) is obtained in the diphenyl NDT and ADT crystals along the direction perpendicular to the herringbone molecular layers. Our calculations also point to large nonlocal vibrational couplings along the π-stacks in the unsubstituted and dimethylated ADT crystals.
Co-reporter:Seyhan Salman, Dongwook Kim, Veaceslav Coropceanu, and Jean-Luc Brédas
Chemistry of Materials 2011 Volume 23(Issue 23) pp:5223
Publication Date(Web):November 7, 2011
DOI:10.1021/cm2022449
We have investigated the electronic structure of triscarbazole derivatives used as host materials in blue phosphorescent organic light-emitting diodes. The results of density functional theory calculations show that, in the case of triscarbazole derivatives where the carbazole units are linked via C–C bonds, the frontier molecular orbital energies are modulated by strong molecular orbital interactions between the central and side carbazole units. On the other hand, in the case of triscarbazoles linked via C–N bonds, the combination of inductive effects and molecular orbital interactions tunes the frontier level energies and, interestingly, gives rise to an ambipolar character. In the C–N linked systems, the lowest triplet states are characterized mainly by an electronic transition localized within the central carbazole, while in the C–C linked compounds it is the longest oligo-para-phenyl segment to be found in the chemical structure that defines the lowest triplet transition. When the N–H group of the central carbazole unit is replaced by other groups [O, S, CH2, C(CH3)2, C(CH3)(CF3), and C(CF3)2], the HOMO/LUMO energies fluctuate substantially in the absence of the side carbazoles, but these variations are significantly reduced in their presence; also, the singlet–triplet energy differences decrease substantially when going from the isolated central unit to the triscarbazole-like derivatives.Keywords: ambipolar hosts; blue OLEDs; density functional theory (DFT) calculations; singlet−triplet energy differences; triscarbazoles;
Co-reporter:Lingyun Zhu, Eung-Gun Kim, Yuanping Yi, and Jean-Luc Brédas
Chemistry of Materials 2011 Volume 23(Issue 23) pp:5149
Publication Date(Web):November 8, 2011
DOI:10.1021/cm201798x
Molecular doping is a charge-transfer process intended to improve the electrical properties of organic semiconductors and the efficiency of organic electronic devices, by incorporation of a complex-forming, strong molecular electron acceptor or donor. Using density functional theory methods with dispersion corrections, we seek to monitor charge transfer and estimate its amount via calculations of experimental observables. With 2,3,5,6-tetrafluoro-7,7,8,8-tetracyanoquinodimethane (F4-TCNQ) as a p-dopant (electron acceptor) and an array of π-conjugated molecules as hole-transport materials (donors), the amount of charge transfer is seen to be a non-monotonic function of the offset defined by the donor ionization potential (IP) and the acceptor electron affinity (EA), IP – |EA|. Interestingly, a well-defined, linear relationship between the amount of charge transfer and IP – |EA| is obtained when the IP and EA values are adjusted to reflect intramolecular geometric changes in the final form of the complex. This study offers a straightforward way to match donor–acceptor pairs with desired doping effects and to estimate the resulting charge density in organic semiconductors.Keywords: charge transfer; DFT; IP−EA offset; molecular complexes; molecular doping; organic semiconductors;
Co-reporter:Yuanping Yi, Veaceslav Coropceanu and Jean-Luc Brédas
Journal of Materials Chemistry A 2011 vol. 21(Issue 5) pp:1479-1486
Publication Date(Web):06 Jan 2011
DOI:10.1039/C0JM02467H
The exciton-dissociation and charge-recombination processes in donor–acceptor complexes found in α-sexithienyl/C60 and α-sexithienyl/perylenetetracarboxydiimide (PDI) solar cells are investigated by means of quantum-chemical methods. The electronic couplings and exciton-dissociation and charge-recombination rates have been evaluated for various configurations of the complexes. The results suggest that the decay of the lowest charge-transfer state to the ground state in the PDI-based devices: (i) is faster than that in the fullerene-based devices and (ii) in most cases, can compete with the dissociation of the charge-transfer state into mobile charge carriers. This faster charge-recombination process is consistent with the lower performance observed experimentally for the devices using PDI derivatives as the acceptor.
Co-reporter:Gjergji Sini, John S. Sears, and Jean-Luc Brédas
Journal of Chemical Theory and Computation 2011 Volume 7(Issue 3) pp:602-609
Publication Date(Web):January 18, 2011
DOI:10.1021/ct1005517
We have evaluated the performance of several density functional theory (DFT) functionals for the description of the ground-state electronic structure and charge transfer in donor/acceptor complexes. The tetrathiafulvalene−tetracyanoquinodimethane (TTF−TCNQ) complex has been considered as a model test case. Hybrid functionals have been chosen together with recently proposed long-range corrected functionals (ωB97X, ωB97X-D, LRC-ωPBEh, and LC-ωPBE) in order to assess the sensitivity of the results to the treatment and magnitude of exact exchange. The results show an approximately linear dependence of the ground-state charge transfer with the HOMOTTF−LUMOTCNQ energy gap, which in turn depends linearly on the percentage of exact exchange in the functional. The reliability of ground-state charge transfer values calculated in the framework of a monodeterminantal DFT approach was also examined.
Co-reporter:Paul Winget ;Jean-Luc Brédas
The Journal of Physical Chemistry C 2011 Volume 115(Issue 21) pp:10823-10835
Publication Date(Web):May 12, 2011
DOI:10.1021/jp200666p
The geometries, binding energies, and amounts of charge transferred in the ground state for a series of donor/acceptor organic π–π complexes have been characterized at the density functional theory level. We find that these compounds exhibit important changes in geometry upon complexation that is accompanied by a large binding energy. The amount of charge transferred from the donor to the acceptor depends highly on the substitution of the donor and can be roughly described by the electron donating or withdrawing ability of the substituent. Interestingly, there is a significant difference in the behavior of carbazoles and diarylamines upon substitution.
Co-reporter:John S. Sears ; Ronald R. Chance ;Jean-Luc Brédas
Journal of the American Chemical Society 2010 Volume 132(Issue 38) pp:13313-13319
Publication Date(Web):September 8, 2010
DOI:10.1021/ja103769j
The optoelectronic properties of polydiacetylenes can be strongly modulated by torsions along the polymer chains. These as well as other distortions of the nominally coplanar polydiacetylene backbones result in the major color changes observed for these materials in response to a variety of external, low-energy stimuli; such color changes form the basis for the many applications of polydiacetylenes as sensor materials. There has been little theoretical work related to backbone distortions in polydiacetylenes; actually, previous estimates of the torsional barriers in these systems differ by an order of magnitude. Understanding the impact that polymer torsions have upon the properties of polydiacetylenes necessitates accurate estimates of the torsion potentials. Here, by using computationally efficient, wave-function-based electronic structure methods on increasingly larger oligomers, we present reliable estimates of the torsional barriers in model diacetylene oligomers and provide an accurate extrapolation of these values to the polymer limit.
Co-reporter:Roel S. Sánchez-Carrera ; Pavel Paramonov ; Graeme M. Day ; Veaceslav Coropceanu ;Jean-Luc Brédas
Journal of the American Chemical Society 2010 Volume 132(Issue 41) pp:14437-14446
Publication Date(Web):September 24, 2010
DOI:10.1021/ja1040732
A key feature of organic π-conjugated materials is the strong connection between their electronic and geometric structures. In particular, it has been recently demonstrated that nonlocal electron−vibration (electron−phonon) interactions, which are related to the modulation of the electronic couplings (transfer integrals) between adjacent molecules by lattice vibrations, play an important role in the charge-transport properties of organic semiconductors. Here, we use density functional theory calculations and molecular mechanics simulations to estimate the strength of these nonlocal electron−vibration couplings in oligoacene crystals as a function of molecular size from naphthalene through pentacene. The effect of each optical vibrational mode on the electronic couplings is evaluated quantitatively. The results point to a very strong coupling to both intermolecular vibrational modes and intramolecular (including high-frequency) modes in all studied systems. Importantly, our results underline that the amount of relaxation energy associated with nonlocal electron−phonon coupling decreases as the size of the molecule increases. This work establishes an original relationship between chemical structure and nonlocal vibrational coupling in the description of charge transport in organic semiconductor crystals.
Co-reporter:Dongwook Kim, Seyhan Salman, Veaceslav Coropceanu, Eric Salomon, Asanga B. Padmaperuma, Linda S. Sapochak, Antoine Kahn and Jean-Luc Brédas
Chemistry of Materials 2010 Volume 22(Issue 1) pp:247
Publication Date(Web):December 10, 2009
DOI:10.1021/cm9029616
We report on a joint theoretical and experimental investigation of the electronic structure of a series of bis(diphenylphosphine oxide) derivatives containing a central aromatic core with high triplet energy. Such molecules can serve as host material in the emissive layer of blue electro-phosphorescent organic devices. The aromatic cores considered in the theoretical study consist of biphenyl, fluorene, dibenzofuran, dibenzothiophene, dibenzothiophenesulfone, or carbazole, linked to the two phosphoryl groups in either para or meta positions. With respect to the isolated core molecules, it is found that addition of the diphenylphosphine oxide moieties has hardly any impact on the core geometry and only slightly reduces the energy of the lowest triplet state (by, at most, ∼0.2 eV). However, the diphenylphosphine oxide functionalities significantly impact the ionization potential and electron affinity values, in a way that is different for para and meta substitutions. Excellent comparison is obtained between the experimental UPS and IPES spectra of the para biphenyl and meta dibenzothiophene and dibenzothiophenesulfone compounds and the simulated spectra. In general, the phosphine oxide derivatives present triplet energies that are calculated to be at least 0.2 eV higher than those of currently widely used blue phosphorescent emitters.
Co-reporter:Roel S. Sánchez-Carrera, Susan A. Odom, Tiffany L. Kinnibrugh, Tissa Sajoto, Eung-Gun Kim, Tatiana V. Timofeeva, Stephen Barlow, Veaceslav Coropceanu, Seth R. Marder and Jean-Luc Brédas
The Journal of Physical Chemistry B 2010 Volume 114(Issue 2) pp:749-755
Publication Date(Web):December 23, 2009
DOI:10.1021/jp909164w
The electronic properties of the 2,6-diiododithieno[3,2-b:2′,3′-d] thiophene molecule and crystal are investigated by means of UV−vis spectroscopy, cyclic voltammetry, X-ray crystallography, and density functional theory. The experimental and calculated properties of the compound are compared to those exhibited by the parent molecule, dithieno[3,2-b:2′,3′-d]thiophene. Quantum-chemical studies of the 2,6-diiododithieno[3,2-b:2′,3′-d]thiophene crystal suggest uniaxial hole-transport character with an effective mass of about 2m0, comparable to that in the pentacene single crystal.
Co-reporter:Jean-Luc Brédas, Joseph E. Norton, Jérôme Cornil and Veaceslav Coropceanu
Accounts of Chemical Research 2009 Volume 42(Issue 11) pp:1691
Publication Date(Web):August 4, 2009
DOI:10.1021/ar900099h
Our objective in this Account is 3-fold. First, we provide an overview of the optical and electronic processes that take place in a solid-state organic solar cell, which we define as a cell in which the semiconducting materials between the electrodes are organic, be them polymers, oligomers, or small molecules; this discussion is also meant to set the conceptual framework in which many of the contributions to this Special Issue on Photovoltaics can be viewed. We successively turn our attention to (i) optical absorption and exciton formation, (ii) exciton migration to the donor−acceptor interface, (iii) exciton dissociation into charge carriers, resulting in the appearance of holes in the donor and electrons in the acceptor, (iv) charge-carrier mobility, and (v) charge collection at the electrodes. For each of these processes, we also describe the theoretical challenges that need to be overcome to gain a comprehensive understanding at the molecular level. Finally, we highlight recent theoretical advances, in particular regarding the determination of the energetics and dynamics at organic−organic interfaces, and underline that the right balance needs to be found for the optimization of material parameters that often result in opposite effects on the photovoltaic performance.
Co-reporter:Shino Ohira ; Joel M. Hales ; Karl J. Thorley ; Harry L. Anderson ; Joseph W. Perry ;Jean-Luc Brédas
Journal of the American Chemical Society 2009 Volume 131(Issue 17) pp:6099-6101
Publication Date(Web):April 8, 2009
DOI:10.1021/ja9007003
Cyanines, which represent a class of charged chromophores with an odd number of π-conjugated carbons, display unique electronic and optical properties attributed to the strong electronic delocalization and the absence of any significant carbon−carbon bond-length alternation (BLA) along their backbones. The flatness of the corresponding electronic potential makes cyanine dyes the compounds to which simple free-electron theory can be applied in the most relevant way. Recently, cations of porphyrin dimers linked by a π-conjugated bridge with an odd number of carbons and presenting alternating single and triple bonds were shown to possess linear and nonlinear optical properties analogous to those of cyanines. Here, by using a joint theoretical and experimental approach, we demonstrate the correspondence between cyanines and the new class of alkyne carbocations, in spite of their marked difference in BLA.
Co-reporter:Yuanping Yi ; Veaceslav Coropceanu ;Jean-Luc Brédas
Journal of the American Chemical Society 2009 Volume 131(Issue 43) pp:15777-15783
Publication Date(Web):October 7, 2009
DOI:10.1021/ja905975w
The exciton-dissociation and charge-recombination processes in organic solar cells based on pentacene/C60 heterojunctions are investigated by means of quantum-mechanical calculations. The electronic couplings and the rates of exciton dissociation and charge recombination have been evaluated for several geometrical configurations of the pentacene/C60 complex, which are relevant to bilayer and bulk heterojunctions. The results suggest that, irrespective of the actual pentacene−fullerene orientation, both pentacene-based and C60-based excitons are able to dissociate efficiently. Also, in the case of parallel configurations of the molecules at the pentacene/C60 interface, the decay of the lowest charge-transfer state to the ground state is calculated to be very fast; as a result, it can compete with the dissociation process into mobile charge carriers. Since parallel configurations are expected to be found more frequently in bulk heterojunctions than in bilayer heterojunctions, the performance of pentacene/C60 bulk-heterojunction solar cells is likely to be more affected by charge recombination than that of bilayer devices.
Co-reporter:Seyhan Salman, M. Carmen Ruiz Delgado, Veaceslav Coropceanu and Jean-Luc Brédas
Chemistry of Materials 2009 Volume 21(Issue 15) pp:3593
Publication Date(Web):July 20, 2009
DOI:10.1021/cm901128j
The charge-transport parameters of fluorine- and alkyl/alkoxy-substituted tetracene crystals have been investigated by means of density functional theory calculations. The intramolecular reorganization energy (vibronic coupling) is found to increase upon partial fluorination of tetracene and upon further alkoxy substitution, whereas alkyl substitution has a lesser impact. The calculated ionization energies are in agreement with electrochemical measurements and confirm that the electron injection barrier from conventional cathodes into partially fluorinated, alkyl/alkoxy-substituted tetracenes is expected to be smaller than into tetracene. Calculations of the intermolecular electronic couplings and of the crystal band structures have been performed to understand the role of packing on the charge-transport properties. A tight binding model with two sites per unit cell has been used to rationalize the results of the band-structure calculations. The largest electron mobility is predicted for the material where alkyl substitution of the partially fluorinated tetracene leads to a simple π-stacking motif; substitution resulting in dimerization along the π-stacks is found to significantly increase the charge-carrier effective mass and thus to adversely affect the carrier mobility.
Co-reporter:Shino Ohira and Jean-Luc Brédas
Journal of Materials Chemistry A 2009 vol. 19(Issue 40) pp:7545-7550
Publication Date(Web):01 Jul 2009
DOI:10.1039/B906337D
Many porphyrin oligomers exhibit large two-photon absorptions (TPA) at fundamental photon energies around 1.5 eV, while the corresponding monomers have negligible TPA cross-sections in that energy range. In general, our understanding of nonlinear absorption in these compounds is rather limited compared to that of linear absorption. Here, we seek to provide insight into this issue by examining various structural aspects of porphyrin dimers and analyzing how they lead to either “pure” or double resonance-enhanced TPA cross-sections. To do so, we have carried out highly correlated quantum-chemical calculations on model chromophores which differ by their central π-conjugated bridges or acceptor moieties. In a number of such dimers, the calculated energies of the lowest two-photon active states are stabilized and display significant cross-sections as the electronic coupling strength between the two porphyrin moieties becomes significant; in these instances, the lowest electronic TPA-active state is located in an energy range preventing contributions from double resonance effects. On the other hand, in dimers in which the porphyrin moieties are either very strongly or very weakly electronically coupled, the TPA cross-sections are mainly due to double resonance effects.
Co-reporter:Hong Li, Yiqun Duan, Pavel Paramonov, Veaceslav Coropceanu, Jean-Luc Brédas
Journal of Electron Spectroscopy and Related Phenomena 2009 Volume 174(1–3) pp:70-77
Publication Date(Web):August 2009
DOI:10.1016/j.elspec.2009.05.010
We report the results of a density-functional theory study on a series of metal/organic interfaces consisting of self-assembled monolayers (SAMs) of methylthiol and mono-, di-, and tri-fluoromethylthiols, chemisorbed on the Au(1 1 1) surface. The effects of coverage density and extent of fluorination are examined. Both are found to strongly impact: (i) the component of the SAM dipole moment perpendicular to the surface; (ii) the SAM-induced work-function modification of the gold surface; and (iii) the energy-level alignments of both the highest occupied molecular levels and the molecular-signature states of the SAM with respect to the Fermi level of gold and, as a result, the ionization potential of the SAM when deposited on gold. Saturations of the effects are observed at the higher levels of fluorination and coverage.
Co-reporter:Hong Li, Yiqun Duan, Veaceslav Coropceanu, Jean-Luc Bredas
Organic Electronics 2009 10(8) pp: 1571-1578
Publication Date(Web):
DOI:10.1016/j.orgel.2009.09.003
Co-reporter:Georg Heimel, Lorenz Romaner, Egbert Zojer and Jean-Luc Bredas
Accounts of Chemical Research 2008 Volume 41(Issue 6) pp:721
Publication Date(Web):May 29, 2008
DOI:10.1021/ar700284q
Self-assembled monolayers (SAMs) of organic molecules generally modify the surface properties when covalently linked to substrates. In organic electronics, SAMs are used to fine-tune the work functions of inorganic electrodes, thereby minimizing the energy barriers for injection or extraction of charge carriers into or out of an active organic layer; a detailed understanding of the interface energetics on an atomistic scale is required to design improved interfaces. In the field of molecular electronics, the SAM itself (or, in some cases, one or a few molecules) carries the entire device functionality; the interface then essentially becomes the device and the alignment of the molecular energy levels with those of the electrodes defines the overall charge-transport characteristics. This Account provides a review of recent theoretical studies of the interface energetics for SAMs of π-conjugated molecules covalently linked to noble metal surfaces. After a brief description of the electrostatics of dipole layers at metal/molecule interfaces, the results of density functional theory calculations are discussed for SAMs of representative conjugated thiols on Au(111). Particular emphasis is placed on the modification of the work function of the clean metal surface upon SAM formation, the alignment of the energy levels within the SAM with the metal Fermi level, and the connection between these two quantities. To simplify the discussion, we partition the description of the metal/SAM system into two parts by considering first an isolated free-standing layer of molecules and then the system obtained after molecule−metal bond formation. From an electrostatic standpoint, both the isolated monolayer and the metal−molecule bonds can be cast in the form of dipole layers, which lead to steps in the electrostatic potential energy at the interface. While the step due to the isolated molecular layer impacts only the work function of the SAM-covered surface, the step arising from the bond formation influences both the work function and the alignment of the electronic levels in the SAM with respect to the metal Fermi energy. Interestingly, headgroup substitutions at the far ends of the molecules forming the SAM are electrostatically decoupled from the metal−thiol interface in densely packed SAMs; as a result, the nature of these substituents and the binding chemistry between the metal and the molecules are two largely unrelated handles with which to independently tune the work function and the level alignment. The establishment of a comprehensive atomistic picture regarding the impact of the individual components of a SAM on the interface energetics at metal/organic junctions paves the way for clear guidelines to design improved functional interfaces in organic and molecular electronics.
Co-reporter:Eung-Gun Kim ;Jean-Luc Brédas
Journal of the American Chemical Society 2008 Volume 130(Issue 50) pp:16880-16889
Publication Date(Web):November 19, 2008
DOI:10.1021/ja806389b
Poly(3,4-ethylenedioxythiophene) (PEDOT) is the prototypical conjugated polymer used in the doped state as the hole injection/transport layer in organic (opto)electronic devices. Numerous experimental studies have been successful only in drawing a partial microscopic picture of PEDOT due to its complex morphology, which has also hampered application of theoretical approaches. Using density functional theory methods, combined with refined structural models built upon crystallographic data of PEDOT and other substituted polythiophenes, our work seeks to establish a comprehensive understanding of the electronic and geometric structures of PEDOT, as an isolated chain and in the pristine and doped bulk phases. We find that ethylenedioxy substitution planarizes the polythiophene backbone but the experimentally observed bandgap reduction is caused mainly by a stronger destabilization of the valence band than the conduction band via donor-type substitution. The calculated crystal of pristine PEDOT has a monoclinic lamellar structure consisting of inclined π-stacks. The impact of interchain interactions on the charge carrier effective masses is greater than that of the ethylenedioxy substitution and leads to the reversal of the relative masses; the electrons are lighter than the holes in the pristine crystal. The small interchain electron effective mass is comparable to the hole effective masses found in high mobility organic crystals. Tosylic acid-doped PEDOT (PEDOT:Tos), which is receiving renewed interest as an anode material to replace indium tin oxide, is calculated to be a two-dimensional-like metal. The PEDOT:Tos crystal is found to have an embedded mirror plane in the tosylate monolayer that is sandwiched between PEDOT stacks, and thus to have twice the size of the unit cell proposed earlier. Doping is seen to remove the intrastack inclination of the PEDOT chains.
Co-reporter:S. E. Koh;C. Risko;D. A. da Silva Filho;O. Kwon;A. Facchetti;J.-L. Brédas;T. J. Marks;M. A. Ratner
Advanced Functional Materials 2008 Volume 18( Issue 2) pp:332-340
Publication Date(Web):
DOI:10.1002/adfm.200700713
Abstract
A theoretical study using density functional theory is undertaken to gain insight into how the structural, electronic, and electron-transfer characteristics of three Fluoroarene-oligothiophene semiconductors influence the preferred transport of electrons versus holes in field-effect transistor applications. The intermolecular electronic coupling interactions are analyzed through both a simplified energy-splitting in dimer (ESID) model and as a function of the entire dimer Hamiltonian in order to understand the impact of site energy differences; our results indicate that these differences are generally negligible for the series and, hence, use of the ESID model is valid. In addition, we also investigate the reduction and oxidation processes to understand the magnitudes of the intramolecular reorganization energy for the charge-hopping process and expected barrier heights for electron and hole injection into these materials. From the electronic coupling and intramolecular reorganization energies, estimates of the nearest-neighbor electron-transfer hopping rate constant for electrons are obtained. The ionization energetics suggest favored electron injection for the system with perfluoroarene groups at the end of the thiophene core, in agreement with experiments. The combined analyses of the electron-transfer properties and ionization processes suggest possible ambipolar behavior for these materials under favorable device conditions.
Co-reporter:Roel S. Sánchez-Carrera, Veaceslav Coropceanu, Eung-Gun Kim and Jean-Luc Brédas
Chemistry of Materials 2008 Volume 20(Issue 18) pp:5832
Publication Date(Web):August 20, 2008
DOI:10.1021/cm801108c
The 1,4-diiodobenzene (DIB) crystal stands out among molecular organic semiconducting crystals because of its remarkable room-temperature hole mobility (>10 cm2/(V s)). Here, on the basis of a density functional theory study, we demonstrate that the high mobility in DIB is primarily associated with the heavy iodine atoms. We find that along specific crystal directions, both electrons and holes are characterized by a very small effective mass of about 0.5 m0. Interestingly, iodine substitution also leads to a significant decrease in the local hole-vibration coupling compared to benzene; as a result, the electronic coupling for holes is calculated to be much larger than the hole-vibration coupling, which is consistent with the observation of large hole mobility. In marked contrast, the polaron binding energy in the case of electrons is found to be significantly higher than the electronic coupling; this implies that electrons in DIB are strongly localized even at room temperature.
Co-reporter:Chad Risko, Veaceslav Coropceanu, Stephen Barlow, Victor Geskin, Karin Schmidt, Nadine E. Gruhn, Seth R. Marder and Jean-Luc Brédas
The Journal of Physical Chemistry C 2008 Volume 112(Issue 21) pp:7959-7967
Publication Date(Web):April 24, 2008
DOI:10.1021/jp711954j
By using gas-phase ultraviolet photoelectron spectroscopy, vis/NIR spectroscopy, and electronic-structure calculations, we have investigated the electron-vibration and electronic interactions in a series of bisdimethylamino mixed-valence systems: N,N,N′,N′-tetramethyl-p-phenylenediamine, N,N,N′,N′-tetramethylbenzidine, and N,N,N′,N′-tetramethyltolane-4,4′-diamine. Experiment and theory concur to indicate that the electron-vibration coupling in these systems is dominated by interactions with symmetric modes. The results reveal that the strength of both electronic and electron-vibration couplings decreases as the molecular bridge lengthens. The parameters derived for the present compounds have been compared to those of diarylamino-based structural analogs. This comparison underlines that the replacement of the methyl terminal groups with p-anisyl groups has a significant effect on the electronic and electron-vibrational interactions.
Co-reporter:Shino Ohira;Indranil Rudra Dr.;Karin Schmidt Dr.;Stephen Barlow Dr.;Sung-Jae Chung Dr.;Qing Zhang Dr.;Jon Matichak;SethR. Marder ;Jean-Luc Brédas
Chemistry - A European Journal 2008 Volume 14( Issue 35) pp:11082-11091
Publication Date(Web):
DOI:10.1002/chem.200801055
Abstract
Many squaraines have been observed to exhibit two-photon absorption at transition energies close to those of the lowest energy one-photon electronic transitions. Here, the electronic and vibronic contributions to these low-energy two-photon absorptions are elucidated by performing correlated quantum-chemical calculations on model chromophores that differ in their terminal donor groups (diarylaminothienyl, indolenylidenemethyl, dimethylaminopolyenyl, or 4-(dimethylamino)phenylpolyenyl). For squaraines with diarylaminothienyl and dimethylaminopolyenyl donors and for the longer examples of 4-(dimethylamino)phenylpolyenyl donors, the calculated energies of the lowest two-photon active states approach those of the lowest energy one-photon active (1Bu) states. This is consistent with the existence of purely electronic channels for low-energy two-photon absorption (TPA) in these types of chromophores. On the other hand, for all squaraines containing indolinylidenemethyl donors, the calculations indicate that there are no low-lying electronic states of appropriate symmetry for TPA. Actually, we find that the lowest energy TPA transitions can be explained through coupling of the one-photon absorption (OPA) active 1Bu state with bu vibrational modes. Through implementation of Herzberg–Teller theory, we are able to identify the vibrational modes responsible for the low-energy TPA peak and to reproduce, at least qualitatively, the experimental TPA spectra of several squaraines of this type.
Co-reporter:E.-G. Kim;K. Schmidt;T. Kreouzis;W. R. Caseri;N. Stingelin-Stutzmann;J.-L. Brédas
Advanced Materials 2006 Volume 18(Issue 15) pp:2039-2043
Publication Date(Web):6 JUL 2006
DOI:10.1002/adma.200600252
Magnus' green salt is the prototype of a class of organic–inorganic hybrid semiconducting materials that combine attractive charge-transport properties and processability. By using density-functional-theory methods, the electronic structure of Magnus' green salt is investigated, in particular the nature of the interplatinum interactions (see figure). In conjunction with time-of-flight measurements of the carrier mobilities, key structure–property relationships for these materials are re-established.
Co-reporter:Veaceslav Coropceanu, Sergei I. Boldyrev, Chad Risko, Jean-Luc Brédas
Chemical Physics 2006 Volume 326(Issue 1) pp:107-114
Publication Date(Web):11 July 2006
DOI:10.1016/j.chemphys.2006.01.002
Abstract
We have generalized the Hush equations developed for the analysis of intervalence charge-transfer bands by including into the model the interaction with symmetric vibrations. Our results indicate that in symmetric class-II systems the maximum of the intervalence charge-transfer band is equal to the reorganization energy λ related to the antisymmetric vibrations as is the case in the conventional Hush model. In contrast, the corresponding transition dipole moment and the activation barrier for thermal electron transfer, in addition to their dependence on λ, also depend on the reorganization energy L related to symmetric vibrational modes. We show that the interaction with symmetric vibrational modes reduces the activation barrier and that the thermal electron-transfer rates derived on the basis of a Hush-type analysis of the optical data are generally underestimated.
Co-reporter:Veaceslav Coropceanu Dr.;Ohyun Kwon Dr.;Brigitte Wex Dr.;Bilal R. Kaafarani Dr.;Nadine E. Gruhn Dr.;Jason C. Durivage;Douglas C. Neckers ;Jean-Luc Brédas
Chemistry - A European Journal 2006 Volume 12(Issue 7) pp:
Publication Date(Web):10 JAN 2006
DOI:10.1002/chem.200500879
The nature of vibronic coupling in fused polycyclic benzene–thiophene structures has been studied using an approach that combines high-resolution gas-phase photoelectron spectroscopy measurements with first-principles quantum-mechanical calculations. The results indicate that in general the electron–vibrational coupling is stronger than the hole–vibrational coupling. In acenedithiophenes, the main contributions to the hole–vibrational coupling arise from medium- and high-frequency vibrations. In thienobisbenzothiophenes, however, the interaction of holes with low-frequency vibrations becomes significant and is larger than the corresponding electron–vibrational interaction. This finding is in striking contrast with the characteristic pattern in oligoacenes and acenedithiophenes in which the low-frequency vibrations contribute substantially only to the electron–vibrational coupling. The impact of isomerism has been studied as well.
Co-reporter:D. A. da Silva Filho;E.-G. Kim;J.-L. Brédas
Advanced Materials 2005 Volume 17(Issue 8) pp:
Publication Date(Web):7 APR 2005
DOI:10.1002/adma.200401866
Rubrene has recently attracted much attention in the field of organic semiconductors because of its very high mobilities at room temperature. These observations are a priori surprising, since the tetraphenyl substitution of the tetracene backbone (see Figure) is expected to lead to weak intermolecular interactions and, as a result, low carrier mobilities. This theoretical work provides a clear explanation for the origin of the high mobilities.
Co-reporter:V.M. Geskin, J. Cornil, J.L. Brédas
Chemical Physics Letters 2005 Volume 403(1–3) pp:228-231
Publication Date(Web):14 February 2005
DOI:10.1016/j.cplett.2004.12.101
Abstract
L. Zuppiroli et al. [Chem. Phys. Lett. 374 (2003) 7] have theoretically studied polaron formation in oligo(phenylene vinylene) radical ions. In particular, they obtained with the AM1/UHF method a stepwise increase of the relaxation energy with increasing chain length. In this Comment, we suggest that this result is likely to be an artifact. We argue that UHF is particularly inappropriate for studying energies of open-shell pi-conjugated systems because of inherent spin contamination leading to wrong molecular structures. We show that, within the AM1 methodology, relaxation energies are rather insensitive to chain length and discuss the origin of this behavior.
Co-reporter:J. C. Sancho-García;L. Poulsen;J. Gierschner;R. Martínez-Alvárez;E. Hennebicq;M. Hanack;H.-J. Egelhaaf;D. Oelkrug;D. Beljonne;J.-L. Brédas;J. Cornil
Advanced Materials 2004 Volume 16(Issue 14) pp:
Publication Date(Web):2 AUG 2004
DOI:10.1002/adma.200400354
Quantum-chemical calculations have been performed to characterize the potentiality of recently synthesized end-substituted oligophenylenevinylenes (OPVs) as excitation shuttles and to design more efficient derivatives. The approach provides quantitative estimates of the parameters controlling the exciton transfer rates and strategies to promote directional energy transfer.
Co-reporter:D. Beljonne;A. Ye;Z. Shuai;J.-L. Brédas
Advanced Functional Materials 2004 Volume 14(Issue 7) pp:
Publication Date(Web):22 JUL 2004
DOI:10.1002/adfm.200305176
The operation and efficiencies of molecular or polymer organic light-emitting diodes depend on the nature of the excited species that are formed. The lowest singlet and triplet excitons display different characteristics that impact on the quantum yields achievable in the devices. Here, by performing correlated quantum-chemical calculations that account for both the electronic couplings and energetics of the charge-recombination process from a pair of positive and negative polarons into singlet and triplet excitons, we show that the formation rates for singlet over triplet excitons vary with chain length and favor singlet excitons in longer chains. Thus, in polymer devices, the resulting singlet/triplet fraction can significantly exceed the spin-statistical limit.
Co-reporter:Demetrio A. da Silva Filho, Rainer Friedlein, Veaceslav Coropceanu, Gunnar Öhrwall, Wojciech Osikowicz, Christian Suess, Stacey L. Sorensen, Svante Svensson, William R. Salaneck and Jean-Luc Brédas
Chemical Communications 2004 (Issue 15) pp:1702-1703
Publication Date(Web):24 Jun 2004
DOI:10.1039/B403828B
The hole–vibrational coupling in naphthalene is studied using high-resolution gas-phase photoelectron spectroscopy and density functional theory calculations (DFT), and a remarkable increase of the coupling with low-frequency vibrations is observed in the excited states.
Co-reporter:Y. Karzazi, X. Crispin, O. Kwon, J.L. Brédas, J. Cornil
Chemical Physics Letters 2004 Volume 387(4–6) pp:502-508
Publication Date(Web):1 April 2004
DOI:10.1016/j.cplett.2004.02.054
Self-assembled monolayers made of thiolated conjugated wires attached on gold surfaces currently attract a considerable interest in the field of nanoelectronics. The interactions taking place at the metal/molecule interface govern the electronic structure of the complex, and hence the barriers for charge injection from the electrodes to the molecules. Considering benzenethiol as a prototype molecule, we investigate here the way the electronic structure is affected by the nature of the anchoring site of the sulfur atom on the gold surface and by the relative orientation of the molecule with respect to the surface. We also assess whether the changes in the molecular electronic properties upon substitution are similar for the isolated molecule and for the molecule attached on the gold surface. Our results provide strong evidences that, in order to introduce functionalities and/or improve charge injection in molecular devices, the electronic properties of conjugated molecular wires can be tailored by derivatization independently of the metal electrodes.
Co-reporter:Yan Fang, Shengli Gao, Xia Yang, Z Shuai, D Beljonne, J.L Brédas
Synthetic Metals 2004 Volume 141(1–2) pp:43-49
Publication Date(Web):18 March 2004
DOI:10.1016/j.synthmet.2003.09.022
Efficient white light emission has been recently reported in an electroluminescent device where the active material is a complex made of N,N′-bis(α-naphthyl)-N,N′-diphenyl-1,1′-biphenyl-4,4′-diamine (NPB) and a boron–fluorine derivative of 1,6-bis(2-hydroxy-5-methylphenyl)pyridine ((mdppy)BF). Here, we investigate theoretically the intermolecular charge transfer in the materials. The interfacial layer is modeled on the basis of a simple dimer structure, for which the lowest excited states are described in the framework of a correlated quantum-chemical semiempirical technique. From the analysis of the calculated excited-state wavefunctions, we find that the lowest excited state possesses significant contributions from charge-transfer excitations from the donor (NPB) to the acceptor ((mdppy)BF). The influence of intermolecular distance and medium polarization are also explored.
Co-reporter:Egbert Zojer ;David Beljonne Dr.;Peter Pacher;Jean-Luc Brédas
Chemistry - A European Journal 2004 Volume 10(Issue 11) pp:
Publication Date(Web):15 APR 2004
DOI:10.1002/chem.200305650
Quadrupolar-type substitution of π-conjugated chromophores with donor and acceptor groups has been shown to increase their two-photon absorption (TPA) response by up to two orders of magnitude. Here, we apply highly correlated quantum-chemical calculations to evaluate the impact of the nature of conjugated bridge and the charge-transfer distance on that enhancement. We compare chromophores with phenylenevinylene-, thienylenevinylene-, polyene-, and indenofluorene-type backbones substituted by dimethylamino and cyano groups. In all compounds, we find a strongly TPA-active Ag state (either 2Ag or 3Ag) in the low-energy region, as well as a higher lying TPA-active state (mAg) at close to twice the energy of the lowest lying one-photon allowed state; the smaller energy detuning in the mAg states results in very large TPA cross sections δ. We also investigate the influence of the degree of ground-state polarization on TPA. Independent of the nature of the backbone and the donor–acceptor separation, δ displays the same qualitative evolution with a maximum before the cyanine-like limit; the highest TPA cross sections are calculated for distirylbenzene- and polyene-based systems.
Co-reporter:R.D. Hreha;C.P. George;A. Haldi;B. Domercq;M. Malagoli;S. Barlow;J.-L. Brédas;B. Kippelen;S.R. Marder
Advanced Functional Materials 2003 Volume 13(Issue 12) pp:
Publication Date(Web):17 NOV 2003
DOI:10.1002/adfm.200304464
2,7-Bis(p-methoxyphenyl-m′-tolylamino)-9,9-dimethylfluorene (1′), 2,7-bis(phenyl-m′-tolylamino)-9,9-dimethylfluorene (2′) and 2,7-bis(p-fluorophenyl-m′-tolylamino)-9,9-dimethylfluorene (3′) have been synthesized using the palladium-catalyzed reaction of the appropriate diarylamines with 2,7-dibromo-9,9-dimethylfluorene. These molecules have glass-transition temperatures 15–20 °C higher than those for their biphenyl-bridged analogues, and are 0.11–0.14 V more readily oxidized. Fluorescence spectra and fluorescence quantum yields for dimethylfluorene-bridged and biphenyl-bridged species are similar, but the peaks of the absorption spectra of 1′–3′ are considerably red-shifted relative to those of their biphenyl-bridged analogues. Time-of-flight hole mobilities of 1′–3′/polystyrene blends are in a similar range to those of the biphenyl-bridged analogues. Analysis according to the disorder formalism yields parameters rather similar to those for the biphenyl species, but with somewhat lower zero-field mobility values. Density functional theory (DFT) calculations suggest that the enforced planarization of the fluorene bridge leads to a slightly larger reorganization energy for the neutral/cation electron-exchange reaction than in the biphenyl-bridged system. Organic light-emitting diodes have been fabricated using 1′–3′/polystyrene blends as the hole-transport layer and tris(8-hydroxy quinoline)aluminium as the electron-transport layer and lumophore. Device performance shows a correlation with the ionization potential of the amine materials paralleling that seen in biphenyl-based systems, and fluorene species show similar performance to biphenyl species with comparable ionization potential.
Co-reporter:M. Carmen Ruiz Delgado ; Eung-Gun Kim ; Demétrio A. da Silva Filho
Journal of the American Chemical Society () pp:
Publication Date(Web):February 18, 2010
DOI:10.1021/ja908173x
Perylene tetracarboxylic diimide (PTCDI) derivatives stand out as one of the most investigated families of air-stable n-type organic semiconductors for organic thin-film transistors. Here, we use density functional theory to illustrate how it is possible to control the charge-transport parameters of PTCDIs as a function of the type, number, and positions of the substituents. Specifically, two strategies of functionalization related to core and end substitutions are investigated. While end-substituted PTCDIs present the same functional molecular backbone, their molecular packing in the crystal significantly varies; as a consequence, this series of derivatives constitutes an ideal test bed to evaluate the models that describe charge-transport in organic semiconductors. Our results indicate that large bandwidths along with small effective masses can be obtained with the insertion of appropriate substituents on the nitrogens, in particular halogenated aromatic groups.
Co-reporter:Dongwook Kim ; Veaceslav Coropceanu ;Jean-Luc Brédas
Journal of the American Chemical Society () pp:
Publication Date(Web):September 25, 2011
DOI:10.1021/ja207554h
Density functional theory calculations were carried out to investigate the electronic structures of representative ambipolar hosts for blue electroluminescence, based on two carbazole end groups and meta-terphenyl (mTP)-like bridges. The bridge molecular segments include mTP, 2,6-bisphenylpyridine, 3,5-bisphenylpyridine, and 2,6-bisphenylpyrimidine. While the ionization potentials and electron affinities of these molecules are mainly determined by their hole- and electron-transport subunits, respectively, each subunit impacts the electronic properties of the other upon their binding, mainly in an inductive way. Importantly, the lowest triplet state of the hosts is determined to be confined into the mTP-like bridges since these are the subunits with lowest individual triplet energy. Extension of the phenyl-based π-conjugated system via meta linkages is found to be effective in modulating the electron affinity value while maintaining a high triplet energy.
Co-reporter:Demetrio A. da Silva Filho, Veaceslav Coropceanu, Nadine E. Gruhn, Pedro Henrique de Oliveira Neto and Jean-Luc Brédas
Chemical Communications 2013 - vol. 49(Issue 54) pp:NaN6071-6071
Publication Date(Web):2013/05/22
DOI:10.1039/C3CC42003E
We report a high-resolution gas-phase UPS spectrum of zinc phthalocyanine (ZnPc) together with a detailed analysis of the vibronic structure of the first ionization band, showing that ZnPc presents the lowest value of the intramolecular reorganization energy experimentally reported for a molecular organic semiconductor.
Co-reporter:Bruno Grimm, Chad Risko, Jason D. Azoulay, Jean-Luc Brédas and Guillermo C. Bazan
Chemical Science (2010-Present) 2013 - vol. 4(Issue 4) pp:NaN1819-1819
Publication Date(Web):2013/02/06
DOI:10.1039/C3SC22188A
We discuss donor–acceptor conjugated polymers where the acceptor moieties are orthogonal to the donor-based backbone direction through the synthesis and study of a new class of materials (including six oligomers and three polymers) based on 4H-cyclopentadithiophene (CPDT) with an imine functionality introduced at the CPDT bridgehead position. Absorption spectroscopy provides information on the influence of structure on the optical properties. We paid special attention to the energies and oscillator strengths of the low-energy transitions and how they correlate with chain length. When the orthogonally conjugated materials are compared to a more traditional polymer, where the donor and acceptor fragments are in series along the backbone direction, fundamental differences in the optical properties are observed. Quantum-mechanical studies of the geometric structure, electronic structure, and excited-state vertical transitions using density functional theory unravel the interplay of structural design and resulting optoelectronic properties. Our findings underline that the magnitude and orientation relative to the backbone long axis of the transition dipole moment is key in designing narrow optical-gap materials with large absorption cross-sections and oscillator strengths.
Co-reporter:Yuanping Yi, Veaceslav Coropceanu and Jean-Luc Brédas
Journal of Materials Chemistry A 2011 - vol. 21(Issue 5) pp:NaN1486-1486
Publication Date(Web):2011/01/06
DOI:10.1039/C0JM02467H
The exciton-dissociation and charge-recombination processes in donor–acceptor complexes found in α-sexithienyl/C60 and α-sexithienyl/perylenetetracarboxydiimide (PDI) solar cells are investigated by means of quantum-chemical methods. The electronic couplings and exciton-dissociation and charge-recombination rates have been evaluated for various configurations of the complexes. The results suggest that the decay of the lowest charge-transfer state to the ground state in the PDI-based devices: (i) is faster than that in the fullerene-based devices and (ii) in most cases, can compete with the dissociation of the charge-transfer state into mobile charge carriers. This faster charge-recombination process is consistent with the lower performance observed experimentally for the devices using PDI derivatives as the acceptor.
Co-reporter:Laxman Pandey, Curtis Doiron, John S. Sears and Jean-Luc Brédas
Physical Chemistry Chemical Physics 2012 - vol. 14(Issue 41) pp:NaN14248-14248
Publication Date(Web):2012/08/09
DOI:10.1039/C2CP41724C
Polymers with low optical gaps are of importance to the organic photovoltaics community due to their potential for harnessing a large portion of the solar energy spectrum. The combination along their backbones of electron-rich and electron-deficient fragments contributes to the presence of low-lying excited states that are expected to display significant charge-transfer character. While conventional hybrid functionals are known to provide unsatisfactory results for charge-transfer excitations at the time-dependent DFT level, long-range corrected (LRC) functionals have been reported to give improved descriptions in a number of systems. Here, we use such LRC functionals, considering both tuned and default range-separation parameters, to characterize the absorption spectra of low-optical-gap systems of interest. Our results indicate that tuned LRC functionals lead to simulated optical-absorption properties in good agreement with experimental data. Importantly, the lowest-lying excited states (excitons) are shown to present a much more localized nature than initially anticipated.
Co-reporter:Huifang Li, Paul Winget, Chad Risko, John S. Sears and Jean-Luc Brédas
Physical Chemistry Chemical Physics 2013 - vol. 15(Issue 17) pp:NaN6302-6302
Publication Date(Web):2013/02/26
DOI:10.1039/C3CP50631B
The development and application of phosphorescent emitters in organic light-emitting diodes (OLEDs) have played a critical role in the push to commercialization of OLED-based display and lighting technologies. Here, we use density functional theory methods to study how modifying the ancillary ligand influences the electronic and photophysical properties of heteroleptic bis(4,6-difluorophenyl) pyridinato-N,C [dfppy] iridium(III) complexes. We examine three families of bidentate ancillary ligands based on acetylacetonate, picolinate, and pyridylpyrazolate. It is found that the frontier molecular orbitals of the heteroleptic complexes can be substantially modulated both as a function of the bidentate ligand family and of the substitution patterns within a family. As a consequence, considerable control over the first absorption and phosphorescence emission transitions, both of which are dominated by one-electron transitions between the HOMO and LUMO, is obtained. Tuning the nature of the ancillary ligand, therefore, can be used to readily modulate the photophysical properties of the emitters, providing a powerful tool in the design of the emitter architecture.
Co-reporter:Shino Ohira and Jean-Luc Brédas
Journal of Materials Chemistry A 2009 - vol. 19(Issue 40) pp:NaN7550-7550
Publication Date(Web):2009/07/01
DOI:10.1039/B906337D
Many porphyrin oligomers exhibit large two-photon absorptions (TPA) at fundamental photon energies around 1.5 eV, while the corresponding monomers have negligible TPA cross-sections in that energy range. In general, our understanding of nonlinear absorption in these compounds is rather limited compared to that of linear absorption. Here, we seek to provide insight into this issue by examining various structural aspects of porphyrin dimers and analyzing how they lead to either “pure” or double resonance-enhanced TPA cross-sections. To do so, we have carried out highly correlated quantum-chemical calculations on model chromophores which differ by their central π-conjugated bridges or acceptor moieties. In a number of such dimers, the calculated energies of the lowest two-photon active states are stabilized and display significant cross-sections as the electronic coupling strength between the two porphyrin moieties becomes significant; in these instances, the lowest electronic TPA-active state is located in an energy range preventing contributions from double resonance effects. On the other hand, in dimers in which the porphyrin moieties are either very strongly or very weakly electronically coupled, the TPA cross-sections are mainly due to double resonance effects.
Co-reporter:Sukrit Mukhopadhyay, Chad Risko, Seth R. Marder and Jean-Luc Brédas
Chemical Science (2010-Present) 2012 - vol. 3(Issue 10) pp:NaN3112-3112
Publication Date(Web):2012/07/17
DOI:10.1039/C2SC20861J
Polymethine dyes have recently demonstrated promise for all-optical switching applications at telecommunications wavelengths as they can combine large refractive optical nonlinearities with low single-photon and two-photon optical losses. Here, we use density functional theory and symmetry-adapted cluster configuration interaction calculations to characterize model streptocyanine molecules. We first consider the isolated, closed-shell cationic molecules and then complexes formed by the molecules with chloride counter-ions and a series of aggregates. Our goal is to examine the influence of: (i) the presence of counter-ions and (ii) aggregation on the electronic structure and nonlinear optical properties. We find that the counter-ions increase the degree of bond-length alternation along the cyanine backbone, while aggregation significantly reduces the energy window between the lowest one-photon and two-photon excited states. Our results provide insight toward the design of new polymethine derivatives that could maintain large figures-of-merit for all-optical switching applications in the solid state.
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![Benzo[lmn][3,8]phenanthroline-1,3,6,8(2H,7H)-tetrone, 4,9-dibromo-2,7-bis(2-octyldodecyl)-](/data/chemimg/139000/1100243-35-3.png)
![Benzo[lmn][3,8]phenanthroline-1,3,6,8(2H,7H)-tetrone, 4,9-dibromo-2,7-bis(2-octyldodecyl)-](/data/chemimg/139000/1100243-35-3_b.png)
![4-Bromo-2,7-dihexylbenzo[lmn][3,8]phenanthroline-1,3,6,8(2H,7H)-tetraone](http://img.cochemist.com/ccimg/1315700/1315605-26-5.png)
![4-Bromo-2,7-dihexylbenzo[lmn][3,8]phenanthroline-1,3,6,8(2H,7H)-tetraone](http://img.cochemist.com/ccimg/1315700/1315605-26-5_b.png)
![Pentacene, 2-(trifluoromethyl)-6,13-bis[2-(tripropylsilyl)ethynyl]-](/data/chemimg/202200/1312313-48-6.png)
![Pentacene, 2-(trifluoromethyl)-6,13-bis[2-(tripropylsilyl)ethynyl]-](/data/chemimg/202200/1312313-48-6_b.png)
![Pentacene, 6,13-bis[2-(tricyclopentylsilyl)ethynyl]-2-(trifluoromethyl)-](/data/chemimg/202200/1312313-47-5.png)
![Pentacene, 6,13-bis[2-(tricyclopentylsilyl)ethynyl]-2-(trifluoromethyl)-](/data/chemimg/202200/1312313-47-5_b.png)
![2-Pentacenecarbonitrile, 6,13-bis[2-(tricyclopentylsilyl)ethynyl]-](/data/chemimg/202200/1167987-22-5.png)
![2-Pentacenecarbonitrile, 6,13-bis[2-(tricyclopentylsilyl)ethynyl]-](/data/chemimg/202200/1167987-22-5_b.png)
![9H-Carbazole, 9,9'-[1,1':3',1''-terphenyl]-3,3''-diylbis-](/data/chemimg/3776800/1116499-73-0.png)
![9H-Carbazole, 9,9'-[1,1':3',1''-terphenyl]-3,3''-diylbis-](/data/chemimg/3776800/1116499-73-0_b.png)
![Anthra[2,1,9-def:6,5,10-d'e'f']diisoquinoline-1,3,8,10(2H,9H)-tetrone, 5,6,12,13-tetrafluoro-](/data/chemimg/128700/946612-30-2.png)
![Anthra[2,1,9-def:6,5,10-d'e'f']diisoquinoline-1,3,8,10(2H,9H)-tetrone, 5,6,12,13-tetrafluoro-](/data/chemimg/128700/946612-30-2_b.png)
![Anthra[2,1,9-def:6,5,10-d'e'f']diisoquinoline-1,3,8,10(2H,9H)-tetrone, 5,6,12,13-tetrafluoro-2,9-bis(2,2,3,3,4,4,4-heptafluorobutyl)-](/data/chemimg/128700/946612-26-6.png)
![Anthra[2,1,9-def:6,5,10-d'e'f']diisoquinoline-1,3,8,10(2H,9H)-tetrone, 5,6,12,13-tetrafluoro-2,9-bis(2,2,3,3,4,4,4-heptafluorobutyl)-](/data/chemimg/128700/946612-26-6_b.png)
![Anthra[2,1,9-def:6,5,10-d'e'f']diisoquinoline-1,3,8,10(2H,9H)-tetrone, 5,12-difluoro-2,9-bis(2,2,3,3,4,4,4-heptafluorobutyl)-](/data/chemimg/128700/946612-19-7.png)
![Anthra[2,1,9-def:6,5,10-d'e'f']diisoquinoline-1,3,8,10(2H,9H)-tetrone, 5,12-difluoro-2,9-bis(2,2,3,3,4,4,4-heptafluorobutyl)-](/data/chemimg/128700/946612-19-7_b.png)
![Anthra[2,1,9-def:6,5,10-d'e'f']diisoquinoline-1,3,8,10(2H,9H)-tetrone, 5,12-difluoro-](/data/chemimg/128700/942294-90-8.png)
![Anthra[2,1,9-def:6,5,10-d'e'f']diisoquinoline-1,3,8,10(2H,9H)-tetrone, 5,12-difluoro-](/data/chemimg/128700/942294-90-8_b.png)
![Poly[2,6-(4,4-bis-(2-ethylhexyl)-4H-cyclopenta[2,1-b;3,4-b']dithiophene)-alt-4,7(2,1,3-benzothiadiazole)]](/data/chemimg/102300/920515-34-0.png)
![Poly[2,6-(4,4-bis-(2-ethylhexyl)-4H-cyclopenta[2,1-b;3,4-b']dithiophene)-alt-4,7(2,1,3-benzothiadiazole)]](/data/chemimg/102300/920515-34-0_b.png)
![Stannane, 1,1'-thieno[3,2-b]thiophene-2,5-diylbis[1,1,1-tributyl-](/data/chemimg/120600/909280-85-9.png)
![Stannane, 1,1'-thieno[3,2-b]thiophene-2,5-diylbis[1,1,1-tributyl-](/data/chemimg/120600/909280-85-9_b.png)
![Poly[2,5-bis(3-tetradecylthiophen-2-yl)thieno[3,2-b]thiophene]](http://img.cochemist.com/ccimg/888500/888491-19-8.png)
![Poly[2,5-bis(3-tetradecylthiophen-2-yl)thieno[3,2-b]thiophene]](http://img.cochemist.com/ccimg/888500/888491-19-8_b.png)
![2,6-Dibromo-4H-cyclopenta[1,2-b:5,4-b']dithiophen-4-one](http://img.cochemist.com/ccimg/636600/636588-79-9.png)
![2,6-Dibromo-4H-cyclopenta[1,2-b:5,4-b']dithiophen-4-one](http://img.cochemist.com/ccimg/636600/636588-79-9_b.png)
![Poly[(9,9-dihexylfluorenyl-2,7-diyl)-alt-(benzo[2,1,3]thiadiazol-4,7-diyl)]](http://img.cochemist.com/ccimg/579600/579505-53-6.png)
![Poly[(9,9-dihexylfluorenyl-2,7-diyl)-alt-(benzo[2,1,3]thiadiazol-4,7-diyl)]](http://img.cochemist.com/ccimg/579600/579505-53-6_b.png)
![BICYCLO[2.2.1]HEPT-2-ENE, 5-(5-BROMOPENTYL)-](http://img.cochemist.com/ccimg/511300/511243-82-6.png)
![BICYCLO[2.2.1]HEPT-2-ENE, 5-(5-BROMOPENTYL)-](http://img.cochemist.com/ccimg/511300/511243-82-6_b.png)
![1,4-Benzenedicarbonitrile, 2,5-bis[(1E)-2-[4-(diphenylamino)phenyl]ethenyl]-](/data/chemimg/1184100/308286-89-7.png)
![1,4-Benzenedicarbonitrile, 2,5-bis[(1E)-2-[4-(diphenylamino)phenyl]ethenyl]-](/data/chemimg/1184100/308286-89-7_b.png)
![Ethenetricarbonitrile, [5-[2-[4-(diphenylamino)phenyl]ethenyl]-2-thienyl]-](http://img.cochemist.com/ccimg/163700/163630-46-4.png)
![Ethenetricarbonitrile, [5-[2-[4-(diphenylamino)phenyl]ethenyl]-2-thienyl]-](http://img.cochemist.com/ccimg/163700/163630-46-4_b.png)
![2,9-Di(pyridin-4-yl)anthra[2,1,9-def:6,5,10-d'e'f']diisoquinoline-1,3,8,10(2H,9H)-tetraone](http://img.cochemist.com/ccimg/136900/136847-29-5.png)
![2,9-Di(pyridin-4-yl)anthra[2,1,9-def:6,5,10-d'e'f']diisoquinoline-1,3,8,10(2H,9H)-tetraone](http://img.cochemist.com/ccimg/136900/136847-29-5_b.png)
![Benzaldehyde, 4-[bis[4-(1,1-dimethylethyl)phenyl]amino]-](http://img.cochemist.com/ccimg/124600/124538-00-7.png)
![Benzaldehyde, 4-[bis[4-(1,1-dimethylethyl)phenyl]amino]-](http://img.cochemist.com/ccimg/124600/124538-00-7_b.png)
![Ferrocene, [(1E,3E)-4-(4-nitrophenyl)-1,3-butadien-1-yl]-](/data/chemimg/3750800/123857-24-9.png)
![Ferrocene, [(1E,3E)-4-(4-nitrophenyl)-1,3-butadien-1-yl]-](/data/chemimg/3750800/123857-24-9_b.png)
![PHOSPHONIC ACID, [[4-(1,1-DIMETHYLETHYL)PHENYL]METHYL]-, DIETHYL ESTER](http://img.cochemist.com/ccimg/118600/118578-89-5.png)
![PHOSPHONIC ACID, [[4-(1,1-DIMETHYLETHYL)PHENYL]METHYL]-, DIETHYL ESTER](http://img.cochemist.com/ccimg/118600/118578-89-5_b.png)
![Anthra[2,1,9-def:6,5,10-d'e'f']diisoquinoline-1,3,8,10(2H,9H)-tetrone,5,6,12,13-tetrachloro-](/data/chemimg/102600/115662-06-1.png)
![Anthra[2,1,9-def:6,5,10-d'e'f']diisoquinoline-1,3,8,10(2H,9H)-tetrone,5,6,12,13-tetrachloro-](/data/chemimg/102600/115662-06-1_b.png)
![Methanaminium, N-[11-(dimethylamino)-2,4,6,8,10-undecapentaenylidene]-N-methyl-](http://img.cochemist.com/ccimg/106600/106512-90-7.png)
![Methanaminium, N-[11-(dimethylamino)-2,4,6,8,10-undecapentaenylidene]-N-methyl-](http://img.cochemist.com/ccimg/106600/106512-90-7_b.png)
![Anthra[2,1,9-def:6,5,10-d'e'f']diisoquinoline-1,3,8,10(2H,9H)-tetrone, 2,9-bis(4-hydroxybutyl)-](http://img.cochemist.com/ccimg/105400/105315-83-1.png)
![Anthra[2,1,9-def:6,5,10-d'e'f']diisoquinoline-1,3,8,10(2H,9H)-tetrone, 2,9-bis(4-hydroxybutyl)-](http://img.cochemist.com/ccimg/105400/105315-83-1_b.png)
![Ferrocene, [(1E)-2-(4-nitrophenyl)ethenyl]-](/data/chemimg/3750800/98243-46-0.png)
![Ferrocene, [(1E)-2-(4-nitrophenyl)ethenyl]-](/data/chemimg/3750800/98243-46-0_b.png)
![2,9-bis[(4-methoxyphenyl)methyl]-Anthra[2,1,9-def:6,5,10-d',e',f'-]diisoquinoline-1,3,8,10(2H,9H)-tetrone](http://img.cochemist.com/ccimg/83600/83524-75-8.png)
![2,9-bis[(4-methoxyphenyl)methyl]-Anthra[2,1,9-def:6,5,10-d',e',f'-]diisoquinoline-1,3,8,10(2H,9H)-tetrone](http://img.cochemist.com/ccimg/83600/83524-75-8_b.png)
![Anthra[2,1,9-def:6,5,10-d'e'f']diisoquinoline-1,3,8,10(2H,9H)-tetrone, 2,9-dioctyl-](/data/chemimg/709500/78151-58-3.png)
![Anthra[2,1,9-def:6,5,10-d'e'f']diisoquinoline-1,3,8,10(2H,9H)-tetrone, 2,9-dioctyl-](/data/chemimg/709500/78151-58-3_b.png)
![Anthra[2,1,9-def:6,5,10-d'e'f']diisoquinoline-1,3,8,10(2H,9H)-tetrone, 2,9-bis(2,6-dimethylphenyl)-](/data/chemimg/673600/76372-76-4.png)
![Anthra[2,1,9-def:6,5,10-d'e'f']diisoquinoline-1,3,8,10(2H,9H)-tetrone, 2,9-bis(2,6-dimethylphenyl)-](/data/chemimg/673600/76372-76-4_b.png)
![Dithieno[3,2-b:2',3'-d]thiophene, 2,6-dibromo-](/data/chemimg/1590700/67061-69-2.png)
![Dithieno[3,2-b:2',3'-d]thiophene, 2,6-dibromo-](/data/chemimg/1590700/67061-69-2_b.png)
![2,9-bis(ethoxypropyl)anthra[2,1,9-def:6,5,10-d'e'f']diisoquinoline-1,3,8,10(2H,9H)-tetrone](http://img.cochemist.com/ccimg/59700/59642-64-7.png)
![2,9-bis(ethoxypropyl)anthra[2,1,9-def:6,5,10-d'e'f']diisoquinoline-1,3,8,10(2H,9H)-tetrone](http://img.cochemist.com/ccimg/59700/59642-64-7_b.png)
![2,9-bis(3-methoxypropyl)anthra[2,1,9-def:6,5,10-d'e'f']diisoquinoline-1,3,8,10(2H,9H)-tetrone](http://img.cochemist.com/ccimg/59000/58935-22-1.png)
![2,9-bis(3-methoxypropyl)anthra[2,1,9-def:6,5,10-d'e'f']diisoquinoline-1,3,8,10(2H,9H)-tetrone](http://img.cochemist.com/ccimg/59000/58935-22-1_b.png)
![2,9-Dibutylisoquinolino[4',5',6':6,5,10]anthra[2,1,9-def]isoquino line-1,3,8,10(2H,9H)-tetrone](http://img.cochemist.com/ccimg/52100/52000-75-6.png)
![2,9-Dibutylisoquinolino[4',5',6':6,5,10]anthra[2,1,9-def]isoquino line-1,3,8,10(2H,9H)-tetrone](http://img.cochemist.com/ccimg/52100/52000-75-6_b.png)
![5-BICYCLO[2.2.1]HEPT-2-ENYLMETHANOL;4-METHYLBENZENESULFONIC ACID](http://img.cochemist.com/ccimg/50700/50626-34-1.png)
![5-BICYCLO[2.2.1]HEPT-2-ENYLMETHANOL;4-METHYLBENZENESULFONIC ACID](http://img.cochemist.com/ccimg/50700/50626-34-1_b.png)
![Benzenamine, 4-[bis(2,4,6-trimethylphenyl)boryl]-N,N-diphenyl-](http://img.cochemist.com/ccimg/38200/38186-32-2.png)
![Benzenamine, 4-[bis(2,4,6-trimethylphenyl)boryl]-N,N-diphenyl-](http://img.cochemist.com/ccimg/38200/38186-32-2_b.png)
![Ethanone, 1-[4-[(1E)-2-phenylethenyl]phenyl]-](/data/chemimg/1785200/20488-42-0.png)
![Ethanone, 1-[4-[(1E)-2-phenylethenyl]phenyl]-](/data/chemimg/1785200/20488-42-0_b.png)
![Bis[(pentamethylcyclopentadienyl)dichloro-rhodium]](http://img.cochemist.com/ccimg/12400/12354-85-7.png)
![Bis[(pentamethylcyclopentadienyl)dichloro-rhodium]](http://img.cochemist.com/ccimg/12400/12354-85-7_b.png)
![Dibenzo[b,i]phenazine,6,13-dihydro-](http://img.cochemist.com/ccimg/10400/10350-06-8.png)
![Dibenzo[b,i]phenazine,6,13-dihydro-](http://img.cochemist.com/ccimg/10400/10350-06-8_b.png)
![[4,8-BIS(OCTYLOXY)THIENO[2,3-F][1]BENZOTHIENE-2,6-DIYL]BIS(TRIMET<WBR />HYLSTANNANE)](http://img.cochemist.com/ccimg/7400/7384-07-8.png)
![[4,8-BIS(OCTYLOXY)THIENO[2,3-F][1]BENZOTHIENE-2,6-DIYL]BIS(TRIMET<WBR />HYLSTANNANE)](http://img.cochemist.com/ccimg/7400/7384-07-8_b.png)
![1H,3H-benzo[1,2-c:4,5-c']difuran-1,3,5,7-tetrone, compd. with pyrene (1:1)](http://img.cochemist.com/ccimg/3500/3470-21-1.png)
![1H,3H-benzo[1,2-c:4,5-c']difuran-1,3,5,7-tetrone, compd. with pyrene (1:1)](http://img.cochemist.com/ccimg/3500/3470-21-1_b.png)
![Anthra[2,1,9-def:6,5,10-d'e'f']diisoquinoline-1,3,8,10(2H,9H)-tetrone,2,9-bis[4-(2-phenyldiazenyl)phenyl]-](http://img.cochemist.com/ccimg/3100/3049-71-6.png)
![Anthra[2,1,9-def:6,5,10-d'e'f']diisoquinoline-1,3,8,10(2H,9H)-tetrone,2,9-bis[4-(2-phenyldiazenyl)phenyl]-](http://img.cochemist.com/ccimg/3100/3049-71-6_b.png)
![1-(BENZENESULFONYL)-4-[4-(BENZENESULFONYL)PHENYL]BENZENE](http://img.cochemist.com/ccimg/1500/1433-00-7.png)
![1-(BENZENESULFONYL)-4-[4-(BENZENESULFONYL)PHENYL]BENZENE](http://img.cochemist.com/ccimg/1500/1433-00-7_b.png)
![6H-Benzo[b]naphtho[2,3-h]carbazole](http://img.cochemist.com/ccimg/1000/905-95-3.png)
![6H-Benzo[b]naphtho[2,3-h]carbazole](http://img.cochemist.com/ccimg/1000/905-95-3_b.png)
![1,4-Benzenediamine,N4-[4-(dimethylamino)phenyl]-N1,N1-dimethyl-](http://img.cochemist.com/ccimg/700/637-31-0.png)
![1,4-Benzenediamine,N4-[4-(dimethylamino)phenyl]-N1,N1-dimethyl-](http://img.cochemist.com/ccimg/700/637-31-0_b.png)
![Dibenzo[b,i]phenazine](http://img.cochemist.com/ccimg/300/258-76-4.png)
![Dibenzo[b,i]phenazine](http://img.cochemist.com/ccimg/300/258-76-4_b.png)
![Quinoxalino[2,3-b]phenazine](http://img.cochemist.com/ccimg/300/258-67-3.png)
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![5H-Naphtho[2,3-b]carbazole](http://img.cochemist.com/ccimg/300/248-96-4.png)
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