Ion implantation of organic thin films and electronic devices

Scidà, Alessandra <1985>

21 February 2013

Organic semiconductors have great promise in the field of electronics due to their low cost in term of fabrication on large areas and their versatility to new devices, for these reasons they are becoming a great chance in the actual technologic scenery. Some of the most important open issues related to these materials are the effects of surfaces and interfaces between semiconductor and metals, the changes caused by different deposition methods and temperature, the difficulty related to the charge transport modeling and finally a fast aging with time, bias, air and light, that can change the properties very easily. In order to find out some important features of organic semiconductors I fabricated Organic Field Effect Transistors (OFETs), using them as characterization tools. The focus of my research is to investigate the effects of ion implantation on organic semiconductors and on OFETs. Ion implantation is a technique widely used on inorganic semiconductors to modify their electrical properties through the controlled introduction of foreign atomic species in the semiconductor matrix. I pointed my attention on three major novel and interesting effects, that I observed for the first time following ion implantation of OFETs: 1) modification of the electrical conductivity; 2) introduction of stable charged species, electrically active with organic thin films; 3) stabilization of transport parameters (mobility and threshold voltage). I examined 3 different semiconductors: Pentacene, a small molecule constituted by 5 aromatic rings, Pentacene-TIPS, a more complex by-product of the first one, and finally an organic material called Pedot PSS, that belongs to the branch of the conductive polymers. My research started with the analysis of ion implantation of Pentacene films and Pentacene OFETs. Then, I studied totally inkjet printed OFETs made of Pentacene-TIPS or PEDOT-PSS, and the research will continue with the ion implantation on these promising organic devices.

FIS/03 Fisica della materia

Predictability studies for Regions Of Freshwater Influence

Verri, Giorgia <1983>

January 1900

The aim of this study is to understand and to assess the effects of river freshwater inflow on the circulation and dynamics of our region of interest, the Central Mediterranean Sea, both on shelf and basin scales, over short-term as well as long-term range. As far as we know this study provides the first investigation on river role on the Central Mediterranean overturning circulation. On the same time we point to improve the hindcast/forecast capability of our regional hydrodynamics model both on shelf and basin scales through a consistent representation of river inflow into the Central Mediterranean Sea taking not account all the physical processes involved in the local water cycle of specific catchments. An integrated modelling system including the atmosphere, the hydrology and the estuary dynamics has been set up upstream the regional ocean model at the Ofanto river outlet. The Estuary Box Model developed by the University of Connecticut (UCONN) jointly with the National Centre for the Atmospheric Research (NCAR) Climate Global Division and the University of Washington (UW) has been implemented for the selected case study, the Ofanto river, downstream of the meteo-hydrological chain and upstream of the regional ocean model. The model performance has been evaluated by comparison with a highly simplified approach based on Knudsen’s relation (Knudsen, 1900). Finally we built up an intermediate modelling approach.

Conducting Polymers as Novel Tools for Biosensing and Tissue Engineering

Marzocchi, Marco <1987>

January 1900

The field of Bioelectronics deals with the integration of electronics and biology, and possesses a tremendous potential regarding the improvement of the quality of life of millions of people. Thanks to their favorable properties, conjugated polymers have proven to be very suitable materials for the bridging of such diverse worlds. In particular, poly(3,4-ethylenedioxythiophene) poly(styrenesulfonate), or PEDOT:PSS, is nowadays considered a benchmark material for bioelectronics applications. The aim of the present work is to give a detailed characterization of the physical and electrochemical properties of PEDOT:PSS thin films, and to prove the potentialities of this material both for the sensing of bioanalytes, through the development of innovative electrochemical sensors, and for tissue engineering applications, through the development of redox-active substrates that can control the replication of living cells. In this work, the development of all PEDOT:PSS-based organic electrochemical transistors (OECTs) is presented. The sensing efficiency of these devices was optimized in terms of sensitivity and limit of detection (LOD) through the investigation of the effect of device geometry, thickness, and operating voltages. An electrochemical characterization of these devices was carried out as well, in order to clarify the processes involved in the device operation. Furthermore, the operation of these devices as electrochemical sensors was tested on several analytes, obtaining in most cases a performance suitable for real applications. The development and characterization of a different kind of devices realized using the same material, redox-active substrates for applications in tissue engineering, is then presented. The effect of a change in the redox state of these PEDOT:PSS films on cell growth is assessed using two cell lines, human dermal fibroblasts (hDF) and human tumoral glioblastoma multiforme cells (T98G), finding that the cell proliferation rate has a clear dependence on the electrochemical state of its substrate.

FIS/03 Fisica della materia

Organic Bulk Heterojunction Solar Cells: Materials Properties Device Stability And Performance

Tessarolo, Marta <1985>

22 February 2016

In the field of Photovoltaic technologies the organic solar cells are particularly attractive because of their ease of processing, mechanical flexibility and potential low cost production techniques. So far, the reported efficiencies are not high enough to allow to be competitive in the market, however with the introduction of new photoactive materials, device architectures and light management structures, the power conversion efficiencies, at laboratory scale, has rapidly reached the 12%, showing a great potential and a bright future for organic solar cells. Nevertheless, in view of commercial products, two main problems are still unresolved: the relatively low performance of the modules and their lifetime. In sight of this, the present Ph.D thesis has a double goal: 1) a better understanding of the relationship between devices performance and photoactive materials structures 2) a deep investigation on device degradation processes, with particular attention on the effects induced by temperature and incident light. As a result, promising approaches to further optimize the polymer’s optoelectrial properties, and thus the corresponding device performance, are proposed. About the lifetime, first the thermal degradation mechanisms involved on the active layer was investigated and it has been demonstrated the role of the other layers and interfaces in the solar cell thermal stability. In this contest an innovative fast capacitance based thermal test has been developed in order to obtain information regarding the limit operating temperature above which the device becomes thermally unstable. In the end, a preliminary study on the photostability issue was carried out demostrating that the photodegradation of organic solar cells not depends just on the photostability of the donor polymer, but is connected also with the composition of the active layer solution and on the interaction with the adjacent layers. Solutions to limit or prevent the devices degradation processes are proposed.

FIS/03 Fisica della materia

Low-dimensional carbon allotropes: an electron microscopy investigation

Ortolani, Luca <1979>

25 May 2009

The research reported in this manuscript concerns the structural characterization of graphene membranes and single-walled carbon nanotubes (SWCNTs). The experimental investigation was performed using a wide range of transmission electron microscopy (TEM) techniques, from conventional imaging and diffraction, to advanced interferometric methods, like electron holography and Geometric Phase Analysis (GPA), using a low-voltage optical set-up, to reduce radiation damage in the samples. Electron holography was used to successfully measure the mean electrostatic potential of an isolated SWCNT and that of a mono-atomically thin graphene crystal. The high accuracy achieved in the phase determination, made it possible to measure, for the first time, the valence-charge redistribution induced by the lattice curvature in an individual SWCNT. A novel methodology for the 3D reconstruction of the waviness of a 2D crystal membrane has been developed. Unlike other available TEM reconstruction techniques, like tomography, this new one requires processing of just a single HREM micrograph. The modulations of the inter-planar distances in the HREM image are measured using Geometric Phase Analysis, and used to recover the waviness of the crystal. The method was applied to the case of a folded FGC, and a height variation of 0.8 nm of the surface was successfully determined with nanometric lateral resolution. The adhesion of SWCNTs to the surface of graphene was studied, mixing shortened SWCNTs of different chiralities and FGC membranes. The spontaneous atomic match of the two lattices was directly imaged using HREM, and we found that graphene membranes act as tangential nano-sieves, preferentially grafting achiral tubes to their surface.

FIS/03 Fisica della materia

Proprietà meccaniche ed elettromagnetiche in miscele Al-fase ferromagnetica

Amadori, Stefano <1978>

25 May 2009

No description available.

FIS/03 Fisica della materia

Advanced applications of X-ray Absorption Spectroscopy to the study of protein metal sites.

Veronesi, Giulia <1982>

04 May 2010

We present a study of the metal sites of different proteins through X-ray Absorption Fine Structure (XAFS) spectroscopy. First of all, the capabilities of XAFS analysis have been improved by ab initio simulation of the near-edge region of the spectra, and an original analysis method has been proposed. The method subsequently served ad a tool to treat diverse biophysical problems, like the inhibition of proton-translocating proteins by metal ions and the matrix effect exerted on photosynthetic proteins (the bacterial Reaction Center, RC) by strongly dehydrate sugar matrices. A time-resolved study of Fe site of RC with μs resolution has been as well attempted. Finally, a further step aimed to improve the reliability of XAFS analysis has been performed by calculating the dynamical parameters of the metal binding cluster by means of DFT methods, and the theoretical result obtained for MbCO has been successfully compared with experimental data.

FIS/03 Fisica della materia

Phosphorus ion implantation in SiC: influence of the annealing conditions on dopant activation and defects

Canino, Mariaconcetta <1980>

17 May 2007

No description available.

FIS/03 Fisica della materia

Mg for hydrogen storage: synthesis, nanostructure and thermodynamics properties

Callini, Elsa <1982>

06 June 2011

Nowadays alternative energies are an extremely important topic and the possibility of using hydrogen as an energy carrier must be explored. Many problems infer the technological application of this abundant and powerful resource, one of them the possibility of storage. In the framework of suitable materials for hydrogen storage, magnesium has been the center of this study because it is cheap and the amount of stored hydrogen that it achieves (7.6 wt%) is extremely appealing. Nanostructure helps to overcome the slow hydrogen diffusion and the functionalization of surfaces with transition metals or oxides favors the hydrogen molecule dissociation/recombination. The aim of this research is the investigation of the metal-hydride transformation in magnesium nanoparticles synthesized by inert-gas condensation, exploiting the fact that they are a simple model system. The so produced nanostructured powder has been analyzed in response to nanoparticles surface functionalization by transition metal clusters, specifically palladium, nickel and titanium, chosen on the basis of their completely different Mg-related phase diagrams. The role of the intermetallic phases formed upon heating and hydrogenation treatments will be presented to provide a comprehensive picture of hydrogen sorption in this class of nanostructured storage materials.

FIS/03 Fisica della materia

Theory of plastic and elastic properties of graphite and silicon carbide

Savini, Gianluca <1972>

17 May 2007

No description available.

FIS/03 Fisica della materia