Electronic properties of metal-organic and organic-organic interfaces studied by photoemission and photoabsorption spectroscopy / Elektronische Eigenschaften von Metall/Organischen und Organik/Organischen Grenzflächen, untersucht mit Hilfe von Photoemissionsspektroskopie und Nahkantenröntgenfeinstrukturmessungen

Molodtsova, Olga

14 December 2007

In this work systematic studies of the organic semiconductor CuPc have been presented. In general the investigation can be devided in three parts. In the first one we have studied the electronic structure of clean CuPc thin film. The next two parts are devoted to organic-organic and metal–organic interface formation, where one of the interface components is CuPc thin film. The main results of this thesis are: - The electronic structure of the pristine organic semiconductor CuPc (valence band and empty states) has been obtained by a combination of conventional and resonant photoemission, near-edge X-ray absorption, as well as by theoretical ab initio quantum-chemical calculations. A qualitative assignment of different VB structures has been given, or in other words the contributions of different atomic species as well as sites of the CuPc molecule to the electronic DOS has been established. In particular, it was shown, that the HOMO is mainly comprised of the spectral weights from the orbitals of carbon pyrolle atoms. Additional contributions to the HOMO stems from the benzene atoms. A combined experimental and theoretical study of the unoccupied electronic density of states of CuPc was presented. Our study allows identifying the contributions from different parts of the molecule to the unoccupied DOS and the measured spectra, which lays grounds for future studies of the evolution of the CuPc electronic states upon e.g. functionalization or doping. Application of similar studies to other organic semiconductors will also provide significant insight into their unoccupied electronic states. - The electronic properties of the organic heterointerfaces between fullerite and pristine copper phthalocyanine were studied. Both interfaces, CuPc/C60 and C60/CuPc, were found to be non-reactive with pronounced shifts of the vacuum level pointing to the formation of an interfacial dipole mainly at the CuPc side of the heterojunctions. The dipole values are close to the difference of the work functions of the two materials. Important interface parameters and hole-injection barriers were obtained. The sequence of deposition does not influence the electronic properties of the interfaces. - CuPc doped with potassium was studied by means of photoemission and photoabsorption spectroscopy. A detailed analysis of the core-level PE spectra allows one to propose possible lattice sites, which harbor the potassium ions. Contrasting to a few results reported in the literature, the films prepared in this thesis showed no finite electronic density of states at the Fermi level. - Two stages of the In/CuPc interface formation have been distinguished. The low-coverage stage is characterized by a strong diffusion of the In atoms into the organic film. Metal ions occupy sites close to the pyrolle nitrogen and strongly interact with molecules transferring negative charge to CuPc. Indium diffusion into the organic films saturates at a stoichiometry of In2CuPc. Subsequently, in the second stage the formation of a metallic indium film occurs on the top of the In2CuPc film. - Upon deposition on CuPc film Sn and Ag atoms do not diffuse into the organic film forming metallic clusters and/or thin metallic overlayer. Sharp metal-organic film interface is formed, in contrast to indium and potassium deposition. Presented experimental results also give evidence for absence of noticeable chemical reaction of Sn and Ag with CuPc thin film. - The systematic investigation of interface formation between CuPc thin film and various metals gives us the possibility to summarize all results with demonstrating similarities and differences for all systems studied.

Photoemission

PES

photoabsorption

NEXAFS

Kelvin Probe

electronic structure

charge neutrality level

CNL

metal-organic interface

organic-organic interface

DFT calculations

Photoemissionsspektroskopie

PES

Röntgenabsorption

NEXAFS

Kelvin Probe

Elektronische Eigenschaften

CNL

Metall/Organische Grenzfläche

Organik/Organischen Grenzfläche

DFT Rechnungen

ddc:530

rvk:UP 7500

Verbindungen von Molybdän und Wolfram in den Oxidationsstufen IV - VI als Modelle für Molybdän- und Wolfram-Cofaktoren / Compounds of molybdenum and tungsten in the oxidation states IV-VI to mimic molybdenum and tungsten cofactors

Döring, Alexander

11 October 2010

No description available.

540 Chemie

Chemistry

Elektrochemie

Molybdän

Wolfram

Molybdopterin

Cofaktoren

Katalyse

DFT-Rechnungen

Redoxpotentiale

electrochemistry

molybdenum

tungsten

molybdopterin

cofactor

catalysis

DFT-calculation

redox potential

35.17

35.27

35.31

35.40

35.42

35.43

35.45

35.60

35.79

SHC 000: Elektrochemie

STO 500: Molybdän {Anorganische Chemie}

STO 550: Wolfram {Anorganische Chemie}

Electronic properties of metal-organic and organic-organic interfaces studied by photoemission and photoabsorption spectroscopy

Molodtsova, Olga

18 July 2007

In this work systematic studies of the organic semiconductor CuPc have been presented. In general the investigation can be devided in three parts. In the first one we have studied the electronic structure of clean CuPc thin film. The next two parts are devoted to organic-organic and metal–organic interface formation, where one of the interface components is CuPc thin film. The main results of this thesis are: - The electronic structure of the pristine organic semiconductor CuPc (valence band and empty states) has been obtained by a combination of conventional and resonant photoemission, near-edge X-ray absorption, as well as by theoretical ab initio quantum-chemical calculations. A qualitative assignment of different VB structures has been given, or in other words the contributions of different atomic species as well as sites of the CuPc molecule to the electronic DOS has been established. In particular, it was shown, that the HOMO is mainly comprised of the spectral weights from the orbitals of carbon pyrolle atoms. Additional contributions to the HOMO stems from the benzene atoms. A combined experimental and theoretical study of the unoccupied electronic density of states of CuPc was presented. Our study allows identifying the contributions from different parts of the molecule to the unoccupied DOS and the measured spectra, which lays grounds for future studies of the evolution of the CuPc electronic states upon e.g. functionalization or doping. Application of similar studies to other organic semiconductors will also provide significant insight into their unoccupied electronic states. - The electronic properties of the organic heterointerfaces between fullerite and pristine copper phthalocyanine were studied. Both interfaces, CuPc/C60 and C60/CuPc, were found to be non-reactive with pronounced shifts of the vacuum level pointing to the formation of an interfacial dipole mainly at the CuPc side of the heterojunctions. The dipole values are close to the difference of the work functions of the two materials. Important interface parameters and hole-injection barriers were obtained. The sequence of deposition does not influence the electronic properties of the interfaces. - CuPc doped with potassium was studied by means of photoemission and photoabsorption spectroscopy. A detailed analysis of the core-level PE spectra allows one to propose possible lattice sites, which harbor the potassium ions. Contrasting to a few results reported in the literature, the films prepared in this thesis showed no finite electronic density of states at the Fermi level. - Two stages of the In/CuPc interface formation have been distinguished. The low-coverage stage is characterized by a strong diffusion of the In atoms into the organic film. Metal ions occupy sites close to the pyrolle nitrogen and strongly interact with molecules transferring negative charge to CuPc. Indium diffusion into the organic films saturates at a stoichiometry of In2CuPc. Subsequently, in the second stage the formation of a metallic indium film occurs on the top of the In2CuPc film. - Upon deposition on CuPc film Sn and Ag atoms do not diffuse into the organic film forming metallic clusters and/or thin metallic overlayer. Sharp metal-organic film interface is formed, in contrast to indium and potassium deposition. Presented experimental results also give evidence for absence of noticeable chemical reaction of Sn and Ag with CuPc thin film. - The systematic investigation of interface formation between CuPc thin film and various metals gives us the possibility to summarize all results with demonstrating similarities and differences for all systems studied.

info:eu-repo/classification/ddc/530

ddc:530

Preparation and Reactions of Compounds with Heavier Group 14 Elements in Low Oxidation States / Synthese und Reaktionen von Verbindungen der Schweren Elemente der 14. Gruppe in niedrigen Oxidationsstufen

Sen, Sakya Singha

04 October 2010

No description available.

540 Chemie

Chemistry

N-Liganden

Reduktion

Silizium

Germanium

Zinn

DFT-Rechnungen

Alkine

Benzol

Cyclobutadien

Silylen

N-Ligands

Reduction

Silicon

Germanium

Tin

DFT Calculation

Alkyne

Benzene

Cyclobuatdiene

Silylene

35.40

35.41

35.42

35.43

35.49

35.60

STM 250: Silicium {Anorganische Chemie}

STM 300: Germanium {Anorganische Chemie}

STM 350: Zinn {Anorganische Chemie}

STN 250: Phosphor {Anorganische Chemie}