Characterization of Heterojunctions via X-Ray and UV Photoemission Spectroscopy: Energy Level Implications for Single and Mixed Monolayer SAMs, CdSe Nanoparticle Films, and Organic Semiconductor Depositions.

Graham, Amy L.

January 2010

This work has centered on the interface dipoles arising at heterojunctions between metals, semiconductor nanoparticles, self-assembled monolayers, and organic semiconductor materials. Alkanethiol self-assembled monolayers, CdSe nanocrystals, and the organic semiconductors zinc phthalocyanine (ZnPc) and Buckminster fullerene (C60) were the basis of these investigations. UV photoemission spectroscopy has proven to be an invaluable tool to observe the vacuum level shifts for these analyses while using XPS to corroborate surface structure. With a full evaluation of these surfaces, the shifts in the vacuum level, valence ionizations, and core ionizations, the impact of these interfaces, as well as their influence on the subsequent deposition of organic semiconductor layers is established.Alkanethiols possessing varying dipole moments were examined on gold and silver substrates. The viability of these alkanethiols was demonstrated to predictively adjust the work function of these metals as a function of their intrinsic dipole moments projected to surface normal, and established differences between Ag--S and Au--S bonds. The capability of the SAMs to modify the work function of gold provided an opportunity for mixed monolayers of the alkanethiols to produce a precise range of work functions by minimal adjustments of solution concentration, which were examined with a simple point dipole model.Photoemission spectroscopy offers a thorough analysis of CdSe nanoparticle films. Despite a plethora of research on these nanocrystals, there still is controversy on the magnitude of the shift in the valence band with diameter. In our research we found the majority of the valence band shift could be attributed to the interface dipole, ignored previously. Meanwhile, the valence band tethered films was obscured by the sulfur of the thiol tether.Finally, organic semiconductor layers deposited on SAMs on gold exhibited various interface dipole effects at these heterojunctions. Charge transfer states of ZnPc did not favor energy level alignment on the SAM/Au substrates used; C60 demonstrated vacuum level shifts on C15 and C12ph alkanethiol monolayers consistent with the interface charge transfer (ICT) model. These results provide credibility to models recently demonstrated in the literature for other passivated metal surfaces, and include the viability of SAMs in these discussions.

interface dipole

nanocrystals

photoemission spectroscopy

self-assembled monolayers

Molecular Electronics : A Theoretical Study of Electronic Structure of Bulk and Interfaces

Unge, Mikael

January 2006

This thesis deals with theoretical studies of the electronic structure of molecules used in the context of molecular electronics. Both studies with model Hamiltonians and first principle calculations have been performed. The materials studied include molecular crystals of pentacene and DNA, which are used as active material in field-effect transistors and as tentative molecular wires, respectively. The molecular magnet compound TCNE and surface modification by means of chemisorption of TDAE on gold are also studied. Molecular crystals of pentacene are reported to have the highest field-effect mobility values for organic thin film field-effect transistors. The conduction process in field-effect transistors applications occurs in a single layer of the molecular crystal. Hence, in studies of transport properties molecular crystals of pentacene can be considered as a two dimensional system. An open question of these system is if the charge transport is bandlike or if as a result of disorder is a hopping process. We address this question in two of the included papers, paper I and paper II. The conducting properties of DNA are of interest for a broad scientific community. Biologist for understanding of oxidatively damaged DNA and physicist and the electronics community for use as a molecular wire. Some reports on the subject classifies DNA as a conductor while other report insulating behavior. The outcome of the investigations are heavily dependent on the type of DNA being studied, clearly there is a big difference between the natural and more or less random sequence in, e.g., λ-DNA and the highly ordered syntethic poly(G)-poly(C) DNA. It has been suggested that long-range correlation would yield delocalized states, i.e., bandlike transport, in natural DNA, especially in the human chromosome 22. In paper III we show that this is not the case. In general our results show that DNA containing an approximately equal amount of the four basis is an insulator in a static picture. An emerging research field is spintronics. In spintronic devices the spin of the charge carrier is as important as the charge. One can envision a device where spin alone is the carrier of information. In realizing spintronic devices, materials that are both magnetic and semiconducting are needed. Systems that exhibit both these properties are organic-based magnets. In paper IV the electronic structure of the molecular magnet compound TCNE is studied, both experimentally and theoretically. The injection of carriers from metal contacts to organic semiconductors is central to the performance of organic based devices. The interface between the metal contact and the organic material has been pointed out to be one of the device parameters that most significantly influences the device performance. This relates to the process of injection of charge carriers in to the organic material. In some contact and organic material combinations the energy barrier for charge injection can be very high. The barrier can be reduced by modify the interface dipole, this is achieved by a monolayer of adsorbed molecules at the interface. The molecule TDAE chemisorbed on gold is studied in paper V.

molecular electronics

electron transport

disorder

localization

long-range correlation

organometallic magnets

interface dipole

Computational physics

Beräkningsfysik

Functional heterointerfaces via electromodulation spectroscopy

Khong, Siong-Hee

January 2010

Functional heterojunctions in organic electronic devices are interfaces formed either between a conducting electrode and an organic semiconductor or between two different organic semiconductors in blended and multilayered structures. This thesis is primarily concerned with the energy level alignment and the interfacial electronic structures at functional heterojunctions encountered in electronic devices made with solution-processable semiconducting polymers. Investigations on the electronic structures across these heterointerfaces are performed with the combined use of electromodulation and photoemission spectroscopic techniques. Electromodulation and ultraviolet photoemission spectroscopic techniques enable direct determination of the surface work functions of electrodes at the electrode/semiconducting polymer interfaces. We overcame the inherent problems faced by electromodulation spectroscopy, which undermine accurate determination of interfacial electronic structures, by performing electroabsorption (EA) measurements at reduced temperatures. We showed in this thesis that low-temperature EA spectroscopy is a surface sensitive technique that can determine the interface electronic structures in electrode/polymer semiconductor/electrode diodes. Using this technique, we demonstrated that the energy level alignments in these solution-processed organic electronic devices are determined by the surface work functions of passivated metals rather than by those of clean metals encountered in ultrahigh vacuum. This thesis also discloses our studies on the electronic structures in polymeric diodes with type II donor-acceptor heterojunctions using the EA spectroscopy. We showed that minimising meausurement temperature and attenuating EA illumination intensity enable accurate determinations of the electronic structures in these devices. We demonstrated that the electronic structures and the performance characteristics of multilayered polymer light-emitting diodes are also determined by the surface work functions of passivated metals. Our investigations confirm that electronic doping of the organic active layers, rather than minimisation of the Schottky barriers at electrode/polymer contacts, holds the key in realising high-performance organic light-emitting devices.

621.381045

The Electronic Structure of Biomolecular Self-Assembled Monolayers

Wolak, Matthaeus Anton

01 January 2012

The studies presented here address the characterization of the electronic structure of various self-assembled monolayers (SAMs) of peptide nucleic acid (PNA) and tetraphenylporphyrin (TPP) SAMs and arrays, formed on gold substrates. PNA is a promising alternative to DNA for bio-sensing applications, as well as for strategies for self-assembly based on nucleic acid hybridization. In recent years charge transfer through PNA molecules was a focus of research due to possible applications in self-assembled molecular circuits and molecular tools. In light of this research it is interesting to investigate the electronic structure of PNA interfaces to gold, a potential electrode material. TPP is, due to its electronic structure, an organic p-type molecular semiconductor. Such a material can provide an alternative to standard micro- and optoelectronic devices and in recent years more attention was paid to semiconducting polymers and organic compounds offering these low-cost and flexible alternatives. Therefore, it is of high importance to investigate the prospect of using modified TPP molecules for the formation of interconnected molecular networks on metallic surfaces. All investigated monolayers were formed from solution in a nitrogen atmosphere inside a homemade glove box. This process allowed for PNA SAM and TPP SAM and array formation on clean Au substrates without the exposure to the ambient atmosphere. Ultraviolet and X-ray photoemission spectroscopy (UPS and XPS) measurements on the resulting PNA SAMs and TPP SAMs and arrays, which were performed in a to the glove box attached vacuum chamber containing a photoemission spectrometer, revealed the hole injection barriers at the interfaces and the interface dipoles. In addition to the UPS and XPS measurements on PNA, electronic structure calculations based on molecular dynamics sampling of the PNA structure were obtained, yielding the HOMO-LUMO gap and the electronic density of states for PNA. Combined with the UPS data, the theoretical calculations enabled estimation of the charge injection barriers for the PNA SAMs at the interface, as well as the assignment of individual UP-spectral features to specific molecular orbitals. The orbital line-up at the interface between the Au substrate and the PNA indicated a significant interface dipole resulting in the alignment of the Au Fermi level near the center of the PNA HOMO-LUMO gap. This alignment causes large charge injection barriers for both holes and electrons, and thus impedes charge transfer from Au into the PNA SAM. The study of PNA molecules with ferrocene termini showed that this hole injection barrier is shifted to lower energies at the PNA/ferrocene interface. This shift was explained with a molecular orbital reconfiguration through the presence of the ferrocene terminus. The further investigation of the dependence of the electronic structure of PNA SAMs, based on their orientation, showed that incomplete films containing flat lying molecules can have a significant impact on the charge injection barriers. The close proximity of the nucleobases to the Au surface offers new ways for charge transfer between the substrate and the PNA molecule through its nitrogen sites, leading to a lowering of the hole injection barrier at the interface. The TPP arrays were formed by depositing AgNO3 on the Au substrate prior to TPP incubation using the electrospray technique. The interaction of AgNO3 with the TPP promoted the formation of an interconnected thin film forming a network on the Au substrate. The line-up at the Au/TPP interface without AgNO3 exposure showed an interface dipole formation with injection barriers that would potentially obstruct charge injection into the molecule. However, the addition of AgNO3 to the process resulted in the formation of fine structures, and lead to a lower hole injection barrier due to an induced dipole, which would ultimately improve charge transfer between the substrate and the thin film. A separate thiolated TPP derivative was used to form SAMs on a gold substrate. The SAM exhibited an even lower injection barrier than the mentioned TPP thin film with AgNO3 exposure, leading to the conclusion that a mix of both TPP derivatives could potentially lead to a SAM with long range interconnectivity and a low hole injection barrier towards the substrate.

charge injection barrier

interface dipole

peptide nucleic acid

tetraphenylporphyrin

work function

XPS

American Studies

Arts and Humanities

Electrical and Computer Engineering

Materials Science and Engineering

Modeling of charge transport processes in supra-molecular architectures and at organic-organic interfaces / Modélisation des processus de transport dans les architectures supramoléculaires et les interfaces organiques

Ide, Julien

28 November 2011

L’optimisation de cellules solaires organiques repose sur l’amélioration de différents paramètres électroniques et structuraux. En particulier, les processus de séparation et de transport de charge doivent être optimisés pour obtenir des rendements élevés. Les processus de séparation de charge dans ces dispositifs s’effectuent aux interfaces donneur/accepteur suite à un décalage entre les niveaux électroniques de ces deux matériaux. Suivant leur nature, des interactions aux interfaces peuvent conduire à l’apparition d’un dipôle pouvant favoriser ou défavoriser la génération de charges libres ; toutefois, l’origine de ce dipôle d’interface est très mal connue. Ainsi, la première partie de cette thèse s’est attaché à une meilleure compréhension de l’origine de ce dipôle en appliquant une approche théorique multi-échelle sur un système D/A typique : l’interface pentacène/C60. L’amélioration des cellules solaires organiques repose également sur l’augmentation des longueurs de diffusion d’exciton et de la mobilité des porteurs de charge dans les couches actives. Ainsi, l’extension de l’ordre structural au sein d’une hétérojonction constituée de deux cristaux liquides colonnaires électroniquement complémentaires pourrait aider à améliorer ces paramètres. En deuxième partie, nous avons donc analysé l’impact du désordre structural présent au sein d’un auto-assemblage monodimensionnel de perylène diimide sur les paramètres électroniques gouvernant le transport de charge en couplant des calculs de dynamique moléculaire à des calculs de chimie quantique. Les mobilités des porteurs de charge ont été estimées en simulant des mesures de mobilité en temps de vol calculées dans le cadre du formalisme de Marcus puis comparées à l’expérience. Des résultats préliminaires issus de simulations de dynamique moléculaire sur une hétérojonction entre deux cristaux liquides électroniquement complémentaire récemment synthétisés ont été reportés en dernière partie. / The development of efficient organic solar cells relies on the optimization of different correlated electronic and structural parameters. In particular, efficient charge separation and charge transport processes are essential to get high conversion yields. The charge separation processes in these devices occur at the donor/acceptor interfaces due to the energetic mismatch between the electronic structures of the two materials. Depending on the nature of these materials, interfacial interactions may lead to the appearance of a significant dipole that can help or disadvantage the generation of free charges. However, the origin of this interface dipole is still unclear. Thus, the first part of this thesis presents a multiscale theoretical approach to address the origin of the interface dipole at a prototypical D/A interface: the pentacene/C60 interface. Improving of the conversion efficiency of organic solar cells also relies on the increase of both the exciton diffusion length and of the charge carrier mobilities. For this purpose, a possible route is to expand the structural order inside the heterojunction via the self-organization of two electronically complementary columnar liquid crystals. This point is investigated in the second part of this thesis. First, we address the impact of the structural disorder on the electronic parameters mediating the charge transport properties in a one-dimensional self-assembly of perylene diimides by coupling molecular dynamics simulations to quantum-chemical calculations. The charge carrier mobilities are evaluated by means of time-of-flight numerical simulations in the framework of the Marcus formalism and compared to the experience. Then, we present preliminary results issued from atomistic molecular dynamics simulations on the heterojunction between two recently synthesized electronically complementary discotic liquid crystals.

Cellules solaires organiques

Dipôle d’interface

Pentacène

Fullérene

Transport de charge

Cristal liquide

Dynamique moléculaire

Théorie de Marcus

Organic solar cells

Interface dipole

Pentacene

Fullrene

Charge transport

Liquid crystal

Molecular dynamics

Marcus theory

Μελέτη διεπιφανειών οργανικών ημιαγωγών με ανόργανα υποστρώματα με εφαρμογή σε οργανικά ηλεκτρονικά

Τσικριτζής, Δημήτρης

13 January 2015

Το ερευνητικό ενδιαφέρον για τους οργανικούς ημιαγωγούς είναι συνεχώς αυξανόμενο τα τελευταία χρόνια, καθώς η αγορά των οργανικών ηλεκτρονικών είναι από τις πιο αναπτυσσόμενες. Για την καλή απόδοση των διατάξεων αυτών σημαντικός είναι ο ρόλος των διεπιφανειών. Οι οικογένειες των n-type οργανικών ημιαγωγών naphthalene bisimides και perylene bisimides έχουν δείξει καλές αποδόσεις σε οργανικά τρανζίστορ. Στην παρούσα εργασία μελετήθηκαν οι διεπιφάνειες νέων οργανικών ημιαγωγών από τις παραπάνω οι οικογένειες οργανικών πάνω σε ανόργανα υποστρώματα με φασματοσκοπίες φωτοηλεκτρονίων. Μελετήθηκε ο σχηματισμός λεπτών υμενίων, πάχους έως τα 10 nm, τριών naphthalene οργανικών ημιαγωγών με διαφορετικό ενεργειακό χάσμα πάνω στον χρυσό και ενός perylene πάνω σε χρυσό και SiO2. Σκοπός ήταν να προσδιοριστεί η επίδραση των διαφορετικών υποκαταστατών του κεντρικού πυρήνα των naphthalene bisimides, στα ενεργειακά χαρακτηριστικά του ημιαγωγού και τα φράγματα έγχυσης των φορέων στην διεπιφάνεια με τον χρυσό. Ο τρόπος ανάπτυξης των όλων των οργανικών ημιαγωγών προσδιορίστηκε ως πολλαπλά στρώματα. Σε μια περίπτωση εντοπίστηκε ότι αλλάζει από οριζόντιο σε κάθετο ο προσανατολισμός των μορίων. Προσδιορίστηκαν όλα τα μεγέθη που χαρακτηρίσουν ενεργειακά την διεπιφάνεια. Συγκεκριμένα, σε όλες τις διεπιφάνειες εμφανίζεται ένα διεπιφανειακό δίπολο λόγω της αναδιάταξης του ηλεκτρονιακού νέφους της επιφάνειας του χρυσού από τα μόρια του οργανικού. Επίσης, οι τιμές των φραγμάτων έγχυσης των ηλεκτρονίων που υπολογίστηκαν είναι αρκετά μικρές που δείχνουν το n-type χαρακτήρα των οργανικών. Οι τιμές του δυναμικού ιονισμού που υπολογίστηκαν ήταν όλες μεγαλύτερες του 5, που είναι προϋπόθεση για τα τρανζίστορ να είναι σταθερά στον αέρα, ενώ σε μια περίπτωση η τιμή ήταν αρκετά μικρή, που δείχνει ότι ο συγκεκριμένος οργανικός ημιαγωγός μπορεί να έχει ambipolar χαρακτηριστικά. Τα αποτελέσματα έδειξαν ότι ο χρυσός μπορεί να χρησιμοποιηθεί αποτελεσματικά ως ηλεκτρόδιο σε τρανζίστορ με n-type οργανικούς ημιαγωγούς. Τέλος, από τα αποτελέσματα τονίστηκε ότι με την υποκατάσταση χημικών ομάδων στον κεντρικό πυρήνα του naphthalene, μια εύκολη διαδικασία, είναι δυνατόν να οδηγηθεί ενεργειακά η διεπιφάνεια προς την επιθυμητή κατεύθυνση. / In the recent years the interest on organic semiconductors is increased as the market of organic electronics is one of most promising. The interfaces between the organic semiconductors with metals or other materials are crucial for the performance of the devices. The study of interfaces by surface sensitive techniques could give useful information for the physics of metal-organic contacts and therefore it is possible the tuning and the improvement of the device performance. The n-type organic semiconductors derivatives of naphthalene bisimides and perylene bisimides, have shown good performance in OFETs. In this work, the interfaces of new synthesized naphthalene bisimides and perylene bisimides molecules with inorganic substrates have been studied by photoelectron spectroscopies. Thin films up to 10 nm thickness of three naphthalene organic semiconductors of different energy gap on Au substrates have been studied. The aim was to investigate the effect of the different substituents of the naphthalene core on the energy characteristics of the organic semiconductors and on the charge injection barriers at the interface. Moreover, the interface of one perylene n-type semiconductor deposited on Au and SiO2 was studied in order to examine the influence of the substrate on the growth mode and the electronic properties. The growth mode of all the organic semiconductors was characterized as simultaneous multilayers. In one case, the orientation of the organic molecules was changed from horizontal to vertical to the surface. In all the interfaces an interface dipole is formed during the early stage of deposition which is attributed to the reorganization of the electron cloud of the Au surface by the organic molecules when they are deposited on Au. The hole and electron injection barriers were also determined. The electron injection barriers were found to be small which indicates the n-type character of these organic molecules. In addition, the results displayed that the Au can be used efficiently as electrode in devices with these organic semiconductors. The ionization potentials of the organic semiconductors were measured and found to be above 5 eV for all and therefore, they are suitable for air-stable transistors. In the case of one organic semiconductor the ionization potential was measured close to the value of five. Thus, this organic semiconductor is suitable for ambipolar transistors. The valance band characteristics near the HOMO, as detected by the UPS spectra, showed that they are affected by the different substituents on the side groups of the imide. These results have shown that changing the substituents of the organic core, which is an easy process; it is possible to tune the energy levels and the electronic characteristics of the interface.

Οργανικοί ημιαγωγοί

Επιστήμη επιφανειών

Επιφανειακό δίπολο

Επιφάνειες

537.622

XPS

UPS

Organic semiconductors

Metal-organic interface

Photoelectron spectroscopies

Surface science

PDI-8CN2

Perylene bisimide

Naphthalene bisimides

Energy level alignment

Interface dipole

Charge injection barriers

Interfaces

HOMO