Interfaces in organic electronic devices: Surface characterization and modification and their effect on microstructure in molecular assemblies

Donley, Carrie Lynn

January 2003

This dissertation has focused on (i) the characterization and optimization of the near-surface region of indium-tin oxide (ITO) thin films, and (ii) the characterization of the microstructure and electrical properties of thin films of several new self-organizing liquid crystalline phthalocyanines (Pcs). Commercial ITO surfaces were explored through a combination of high resolution X-ray photoelectron spectroscopy and electrochemical techniques. It was determined that sputter-deposited ITO films undergo hydrolysis immediately upon exposure to atmosphere, creating InOOH and In(OH)₃ species, which appear to inhibit charge transfer reactions. The surface coverage of these InOOH and In(OH)₃-like species can be controlled by various solution and vacuum pretreatments, including etching with EDTA solutions, and RF-plasmas. Characterization of new discotic mesophase Pc materials has focused on modifications of the original Pc in this series, CuPc(OCH₂CH₂OBz)₈, including a polymerizable version, CuPc(OCH₂CH₂OCH₂CH=CH-Ph)₈, and the sulfur analogs of these molecules, CuPc(SCH₂CH₂OBz)₈ and CuPc(SCH₂CH₂OCH₂CH=CH-Ph)₈. The self-organizing properties of these new Pcs are altered by the changes in side chain composition, but still show the same "column-forming" tendencies as the parent Pc, with long range order. The polymerizable Pc materials can be photolithographically patterned with features as small as 2 microns. Electrical anisotropies in these films were measured with a conductive tip AFM and with OFETs, and anisotropies in current (j(∥)/j(⊥)) were ca. 10 on the micron scale, and up to 1000 on the submicron scale. OFET measurements showed low hole mobilities, which are attributed to poor contact between the Pc column and the Au electrodes. Chemical modification of these electrodes shows that considerable improvements in OFET performance result from this modification strategy. Understanding and controlling the microscopic structure of these Pc films is important for optimizing their electrical properties. A considerable effort was focused on developing a quantitative protocol to combine transmission and reflectance vibrational spectroscopic data to determine the three Euler angles that determine the orientation of these Pcs in an LB-deposited film on a planar substrate. Changes in orientation upon annealing and polymerization were observed, but in general these molecules display tilt angles away from the surface normal of <20° and twists about the surface normal of ca. 25°.

Chemistry, Analytical.

Structure-function relationships in chromatographic stationary phases: Characterization of existing phases and improved strategies for materials fabrication

Orendorff, Christopher Jay

January 2003

Raman spectroscopy is used to determine rotational and conformational order of a series of high-density octadecylsilane stationary phases as a function of numerous chromatographic parameters. The effect of these conditions on the conformational order of the alkylsilanes offers information about molecular interactions at the chromatographic interface, which can be used to gain insight to the mechanisms of solute retention in reversed-phase liquid chromatography. The use of Raman spectroscopy to investigate fundamental interactions of chromatographic systems is also extended to studying ion exchange systems. In addition to the characterization of existing phases, alkylsilane-based stationary phases are fabricated using a novel solution modifier approach. This simple approach allows for the synthesis of materials that vary in surface coverage using the same reaction chemistry. Phases have alkylsilane structure, architecture, and give chromatographic performance comparable to existing phases of similar coverage.

Chemistry, Analytical.

Effectiveness of low energy collisional activation methods for automated peptide sequencing by tandem mass spectrometry

Smith, Lori Lyn

January 2003

The relative efficiencies of low energy (< 100 eV) collisional activation techniques were determined for peptide sequencing by tandem mass spectrometry (MS/MS). Tryptic peptides were fragmented using either collision induced dissociation (CID) or surface induced dissociation (SID) to generate spectral databases. Statistical analysis of the resulting fragment ions and success rates for automated peptide sequencing by publicly available algorithms provided a measure of the value of sequencing information content of CID and SID MS/MS spectra. Typical success rates were determined for automated sequencing by SEQUEST¹⁻³, MS-Tag⁴, Mascot's⁵ MS/MS Ion Search and Sequence Query using low energy CID spectra. The ability of an algorithm to match peptide sequences to raw MS/MS data directly depended on various factors including the mass spectrometer from which the spectra were acquired, the precursor ion charge state, and the mass accuracy and resolution available in the spectra. Statistical analysis demonstrated the presence of similar fragment ions in SID and CID spectra. A lack of long contiguous ion series in SID spectra prevented automated sequencing using conventional approaches. Thus, "patchwork peptide sequencing"⁶, an unconventional method to derive specific sequence criteria for unknown peptides from SID spectra, was performed. Submitting this information to Mascot's Sequence Query allowed database searching strategies to achieve automated peptide sequencing with SID spectra. Some aspects of gas phase ion chemistry were explored for the unexpected formation of fragment ions from cleavage C-terminal to proline residues. Semi-empirical calculations suggest the most stable structure for valineprolyl-b₂ ion is a diketopiperazine, although the MS/MS/MS fragmentation pattern for VP-b₂ is indicative of an oxazalone structure. Support for a diketopiperazine structure is provided by similar fragmentation patterns for VP-b₂ and a synthetic diketopiperazine VP, and prevention of the formation of VP-b₂ by acetylation of the free N-terminus. Substitution of N-methyl alanine for proline produces a b₂ ion that fragments by loss of a portion of the valine residue, consistent with an oxazalone structure. However, theoretical calculations suggest the N-methyl alanine-containing b₂ ion is a diketopiperazine. The differences in fragmentation patterns indicate that the gas phase ion structures for the proline- and N-methyl alanine-containing b₂ ions are different, although stability calculations suggest otherwise.

Chemistry, Analytical.

Stabilized supported lipid bilayers from polymerizable phospholipid monomers

Ross, Eric E.

January 2003

Lipid films are often described as potential surface coatings for the 'biofunctionalization' of solid interfaces because of the ability to support tethered and integrated receptor protein activity and their ability to suppress the non-specific adsorption of soluble proteins. One significant shortcoming of lipid assemblies is the inherent lack of stability required for many technological applications because the non-covalent forces between the constituent lipids are relatively weak. In this work, polymerized, supported lipid bilayers ((poly)PSLBs) composed of diene functionalized lipids have been prepared and characterized. Several parameters relating (poly)PSLB structure and stability to observations made in studies of polymerized bilayer vesicles will be described, including a comparison of UV photopolymerization and redox-initiated radical polymerization, the number and location of the polymerizable moieties in the lipid monomer, and a comparison to PSLBs produced with diacetylene lipids. Redox-initiated polymerization of films composed of bis-substituted diene lipids with at least one polymerizable moiety located near the acyl terminus produces dried PSLBs that are highly uniform and stable. All other conditions yielded PSLBs that contained a high density of defects after drying, including those formed from diacetylene lipids. The nonspecific adsorption of bovine serum albumin (BSA) is used to further characterize the polymer films to fluid PC bilayers, which have been established as protein adsorption "inert" surfaces. The results show that the protein resistance of a cross-linked (poly)PSLB composed of bis-sorbyl phosphatidylcholine (bis-SorbPC) is equivalent to that of a fluid PSLB composed of 1-palmitoyl-2-oleoylphosphatidylcholine (POPC), even after the former has been dried and rehydrated. Furthermore, the (poly)PSLB films can be formed in patterns or patterned with immobilized proteins by microprinting techniques which may facilitate their use in microarray detection schemes.

Chemistry, Analytical.

Fabrication, analysis and patterning of sol-gel based silica ultrathin films

Robertson, Joseph William F.

January 2004

A novel approach to sol-gel thin film fabrication has been developed which leads to the production of ultrathin ∼2 nm to 100 nm thick silica and conductively-doped silica films on metal and semiconductor substrates. The research described herein focuses on the development, characterization and potential application of these thin films in current technology. These ultrathin films were fabricated by a sol-gel procedure, which utilized highly diluted silica precursor compounds. The [H₂O]:[Si] ratio ranged from 50 to 1000, far above the typical values (4-10) used in sol-gel film preparation. This dilution leads to highly densified silica when spin-cast onto an appropriately compatible surface. The surface examined included Si(111)/SiO₂; ITO; and 3-(mercaptopropyl)trimethoxysilane (3MPT) modified Au and Ag. These surfaces must act as wetting control agents for the sol-gel precursor, while simultaneously providing adhesion to the nm sized sol-gel aggregates. The 3MPT-Ag monolayer was examined in detail by Tl, Pb and Cd underpotential deposition electrochemistry, to understand the interfacial structure of the molecule. These results show that the 3MPT monolayer is very stable to outside influences (i.e. Tl and Pb reversibly deposit monolayers at the metal surface). The UPD of metal ions is highly size dependent with Tl depositing with fewer kinetic limitations than Pb and Cd not depositing at all. Raman spectral characterization shows that 3MPT undergoes some reversible rearrangement during the UPD process. The electronic properties of the pure silica films were examined in great detail. The results suggested that in solution, a solvated gel layer at the film-solution interface gives rise to an anomalously low capacitance <100 pF/cm², which has no comparison in the current literature. In the dry state, these silica films have a dielectric constant of ε = 3.5, which is close to that of thermally-grown silica on silicon (3.9). These films were doped with 1,1'-bistriethoxysilylferrocene, an electrochemically-active sol-gel material. The results suggest that under the proper precursor solution conditions, thin ( <10 nm), uniform films can be fabricated. By simply adjusting the ratio of the ferrocene moiety in solution, the film composition can be adjusted. XPS verifies that the atom ratio in solution is near to the observed atom ratio in the films, with some indication of surface segregation of the ferrocene moiety. Electrochemical analysis of these films suggests that electron hopping between the ferrocene centers drives the electrochemical response only when there are pinhole defects, to support counterion conduction to the surface. (Abstract shortened by UMI.)

Chemistry, Analytical.

Surface-enhanced Raman scattering and electrochemical characterization of metal electrode-electrolyte interfaces in nonaqueous systems

Shen, Aijin, 1965-

January 1996

Many important and interesting processes, which are essential components of electrochemical technologies, occur at the electrode/electrolyte interface. Using spectroscopic and electrochemical methods, this research elucidates the interfacial structure in nonaqueous solvents existing at metal electrodes. The behavior of trace interfacial H₂O and Li⁺ and Br⁻ ions at Ag electrodes in the normal alcoholic solvents methanol, ethanol, propanol, butanol and pentanol is examined using surface-enhanced Raman scattering (SERS) and differential capacitance measurements. SERS spectra in the ν(O-H) region exhibit four bands from interfacial H₂O molecules which are a sensitive function of the nature of the solvent, the residual H₂O concentration, and the electrode potential. The results of this study indicate that in the interface, H₂O molecules cluster around Li⁺ and Br⁻ ions and are not homogeneously dispersed. Br⁻ specific adsorption and interfacial solvent behavior in the series of alcohol solvents are interpreted quantitatively through differential capacitance and SERS experiments. Br⁻ surface coverage is calculated using the "Hurwitz-Parsons" analysis of differential capacitance-potential data in these media. These results indicate that almost a monolayer of Br⁻ adsorb on Ag electrodes, but much less Br⁻ ions adsorbs on Au electrodes at positive potentials. The potential of zero charge (pzc) is also quantitatively estimated from these measurements. The technique of "emersion" of an electrochemical interface from electrolyte has opened the door to new possibilities for fundamental electrochemical studies. The relationship between in-situ and emersed electrochemical systems is probed through the study of the interfacial structure of dimethyl sulfoxide (DMSO) on Ag electrodes. The results of this study indicate that pronounced restructuring of the DMSO in the interface is found in the vicinity of the pzc. The solvent orientation is generally retained upon emersion, but a negative emersion-induced potential shift in the interface is observed due to the reorientation of DMSO molecules at gas/solution boundary phase. These data represent the first spectroscopic evidence for the existence of this emersion-induced potential shift.

Chemistry, Analytical.

Investigation of the use of charge-injection-device detectors for multielement atomic absorption spectrometry

True, James Bruce, 1967-

January 1996

Graphite furnace atomic absorption spectrometry has excellent detection limits and accepts a wide variety of samples with little or no sample preparation. The method does, however, suffer from matrix interferences and a lack of highly capable multielement instrumentation. Continuum sources have been employed to GFAAS for multielement determinations, but the one dimensional array detectors used in these instruments can only observe a limited spectral range, limiting the multielement capabilities of these instruments. A continuum source, multielement graphite furnace atomic absorption spectrometer was developed here which employed a prototype echelle polychromator with charge injection device(CID) detection. The detection system employed a new device, the CID&sim;38, and camera control unit, the SCM5000E, with previously unavailable abilities. The camera system was developed and evaluated to determine its spectroscopic characteristics, and reprogrammed to provide rapid, continuous monitoring of many absorption signals simultaneously. A data acquisition and analysis scheme was developed for the prototype system, and the instrument demonstrated detection limits comparable to single-element line source GFAAS. The low ultraviolet throughput of the prototype echelle limited the spectral range that could be observed. Light scattering inside the spectrometer caused the sensitivity to decrease as the number of elements observed increased. A second echelle spectrometer system with higher wavelength resolution and increased throughput in the far ultraviolet was incorporated in to the instrument. The new system increased the spectral range which could be monitored, allowing more elements farther in the ultraviolet to be determined. The detection limits for the new system are comparable to single-element GFAAS, but degrade farther in the ultraviolet due largely to decreasing source output.

Chemistry, Analytical.

Factors affecting the selectivity and efficiency of solid phase extraction of ionizable compounds

Mann, Thierry Dominic

January 1996

Solid phase extraction (SPE) is an extension of conventional liquid chromatographic methods. In the case of SPE the desired separation is digital in nature. Under one solvent condition total retention occurs while under a second solvent condition total elution occurs. The role of SPE as a sample preparation tool is becoming more dominant in the field of analytical chemistry. The need for high throughput, decreased solvent usage, and automation makes SPE the method of choice over other extraction methods. Ionic interactions at modified silica sorbents are studied with respect to the impact on the isolation and purification of analytes. The interactions are characterized by quantitating absolute recoveries for a variety of analytes under different conditions, and qualitative analysis of analytical interferences. Extractions of ionizable compounds were found to be dependent on a myriad of factors. These factors include sample pH, buffer composition, solution concentration, and elution solvent composition. Selectivities for ionizable analytes can be increased by utilizing ionic interactions, particularly in a mixed-mode operation. The extraction of basic compound compounds is generally robust, while methods for the acidic analytes are more highly dependent on the type of counter-ion. Ion selectivities observed were different than those recorded for polymer-based ion-exchange sorbents. The organization of water in the near surface region of the silica-based sorbents is the reason for the disparity between the two types of materials. The utility of a polymeric polystyrene divinylbenzene sorbent for the analysis of analytes from biological matrices is demonstrated. It was shown that these sorbents can withstand harsh chemical environments that would preclude using a silica-based material. Analysis times were shortened and extraction efficiencies were comparable to the silica materials. The extractions were not as selective as those performed on mixed-mode sorbents however.

Chemistry, Analytical.

Indirect detection of selenium-77, tin-119, and tellurium-125 by nuclear magnetic resonance spectroscopy

Schroeder, Thomas Benjamin, 1965-

January 1997

Nuclear magnetic resonance experiments were performed on a series of selenium model compounds, tellurium model compounds, a tin model compound, a selenium metabolite that is an excretory product, and a selenoprotein. ¹H-{⁷⁷Se}, ¹H-{¹¹⁹Sn},¹H-{¹²⁵Te}, and ¹H-{¹²³Te} heteronuclear multiple quantum coherence experiments were performed for the first time on these compounds. In all cases the use of indirect detection substantially increased the sensitivity of observing these nuclei. Coupling constants between 9.4 and 54.2 Hz were successful on selenium compounds and coupling constants between 14.3 and 102.5 Hz were successful on model tellurium compounds. The increase in sensitivity for the observation of selenium compounds was 68 which is close to the theoretical value of 73 and for the observation of tellurium the increase in sensitivity was 46 which is close to the theoretical value of 50.7. These large gains in sensitivity allowed the detection of selenium present in trimethylselenonium iodide at levels below 1 mM. This could conceivably allow this methodology to be adopted as a non-invasive method for the detection of this selenium metabolite and as a means of measuring selenium toxicity levels in blood or urine. Indirect ¹H-{⁷⁷Se} HMQC experiments were also successful on protein A from the glycine reductase complex of Clostridium sticklandii. In addition to enhancing the sensitivity of detecting selenium in this protein, these indirect experiments greatly simplify the spectrum so that only protons that are scalar coupled to selenium are seen in the NMR spectrum. Work on the tin compound had the same aim but it involves using tin as a filter and then performing a NOESY experiment. In the appendices it is shown how selenium NMR was used to identify the presence of a selenite ester in a long chain fatty acid. A lanthanide shift experiment aided the assignment of both the major and minor diastereomer of the selenite ester. The design of a triple resonance box is shown. Finally, electrochemical oxidation data on selected dithiins, thiatellurins, selenothiins, dithiiranes, and thiophene derivatives are presented.

Chemistry, Analytical.

Molecular architecture of ordered thin films of crystalline organic dyes

Back, Andrew Scott

January 1997

The factors which determine the growth mode and molecular architecture of vacuum deposited organic thin films on single crystalline substrates were investigated. Specifically, the relative importance of layer planes in the bulk structure, lattice matching between the overlayer and substrate, topographic direction by the substrate, and specific molecule-substrate interactions, in determining the growth mode were examined. The majority of the molecules studied here (ClAlPc, F₁₆ZnPc, PTCDA, C4-PTCDI, and C5-PTCDI) exhibited layer planes in their bulk structures, however, the molecular plane is coincident with the layer plane only for PTCDA and ClAlPc. ClAlPc and F₁₆ZnPc were found to adopt different flat-lying commensurate square lattices on the Cu(100) surface. In both cases, the flat-lying orientation of the molecules was dictated by specific molecule-substrate interactions, while the orientation of the lattice was dictated by lattice matching with the substrate. ClAlPc was also able to adopt an incommensurate centered rectangular lattice whose orientation was directed by alignment along step edges. Fluorescence investigation of submonolayer PTCDA and PTCDI films on alkali halide substrates demonstrated the great potential of fluorescence spectroscopy as a means of monitoring film growth. PTCDA was found to adopt a flat-lying orientation on NaCl, KCl, and KBr, while a flat-lying orientation of the PTCDI molecules was determined by the strength of the molecule-substrate interactions. From these measurements, the relative interaction strengths of the substrates were determined to be KCl > KBr > NaCl. IR dichroism showed that the expected growth along the layer planes was found only to occur for PTCDA, due to the coincidence of the layer and molecular planes. IR spectroscopy also revealed that a new polymorph of C5-PTCDI had been formed on these surfaces. These studies showed that the relative importance of the factors in determining the molecular architecture adopted within the first 1-2 MLE of a film are: (1) molecule-substrate interaction, (2) lattice matching, (3) topographic direction, (4) layer planes in the bulk structure. In addition the use of fluorescence spectroscopy to probe the evolution of vacuum deposited films was significantly advanced.

Chemistry, Analytical.