Transport Phenomena of CVD Few-Layer MoS2 As-grown on an Al2O3 Substrate

Poehler, Scott A.

January 2015

No description available.

Electrical Engineering

Materials Science

Structure and Carrier Transport in Amorphous Semiconductors

Abtew, Tesfaye Ayalew

26 July 2007

No description available.

Physics, Condensed Matter

semiconductors

electronic structure

light-induced effects

diffusion

carrier transport

DC-conductivity

Experimental Studies of Charge Transport in Single Crystal Diamond Devices

Majdi, Saman

January 2012

Diamond is a promising material for high-power, high-frequency and high- temperature electronics applications, where its outstanding physical properties can be fully exploited. It exhibits an extremely high bandgap, very high carrier mobilities, high breakdown field strength, and the highest thermal conductivity of any wide bandgap material. It is therefore an outstanding candidate for the fastest switching, the highest power density, and the most efficient electronic devices obtainable, with applications in the RF power, automotive and aerospace industries. Lightweight diamond devices, capable of high temperature operation in harsh environments, could also be used in radiation detectors and particle physics applications where no other semiconductor devices would survive. The high defect and impurity concentration in natural diamond or high-pressure-high-temperature (HPHT) diamond substrates has made it difficult to obtain reliable results when studying the electronic properties of diamond. However, progress in the growth of high purity Single Crystal Chemical Vapor Deposited (SC-CVD) diamond has opened the perspective of applications under such extreme conditions based on this type of synthetic diamond. Despite the improvements, there are still many open questions. This work will focus on the electrical characterization of SC-CVD diamond by different measurement techniques such as internal photo-emission, I-V, C-V, Hall measurements and in particular, Time-of-Flight (ToF) carrier drift velocity measurements. With these mentioned techniques, some important properties of diamond such as drift mobilities, lateral carrier transit velocities, compensation ratio and Schottky barrier heights have been investigated. Low compensation ratios (ND/NA) < 10-4 have been achieved in boron-doped diamond and a drift mobility of about 860 cm2/Vs for the hole transit near the surface in a lateral ToF configuration could be measured. The carrier drift velocity was studied for electrons and holes at the temperature interval of 80-460 K. The study is performed in the low-injection regime and includes low-field drift mobilities. The hole mobility was further investigated at low temperatures (10-80 K) and as expected a very high mobility was observed. In the case of electrons, a negative differential mobility was seen in the temperature interval of 100-150K. An explanation for this phenomenon is given by the intervally scattering and the relation between hot and cold conduction band valleys. This was observed in direct bandgap semiconductors with non-equivalent valleys such as GaAs but has not been seen in diamond before. Furthermore, first steps have been taken to utilize diamond for infrared (IR) radiation detection. To understand the fundamentals of the thermal response of diamond, Temperature Coefficient of Resistance (TCR) measurements were performed on diamond Schottky diodes which are a candidate for high temperature sensors. As a result, very high TCR values in combination with a low noise constant (K1/f) was observed.

Single crystal diamond

carrier transport

CVD diamond

time-of-flight

mobility

IR detector

compensation

diamond diode

drift velocity

thermal detector

Transport And Noise In GaAs-Based Devices

Choudhury, Palash Roy

07 1900

The objective of this work was to study the noise in semiconductors and relate the transport mechanisms in the devices with the noise from the devices. The main part of the work was to set up a system for the measurement of noise in semiconductor devices. To establish the sensitivity of the system, it was calibrated at different temperatures. Some of the results from GaAs pn-junction showed some anomaly from that available in the literature. But certain points are yet to be clarified. This requires certain developments in the measurement system. In the case of QWIPS structures, studies on some samples with varying number of wells are required and in order to study the GR noise spectra and other activated processes, we need to study the temperature dependence of the noise and a larger bias variation for studying the low frequency current noise.

Gallium Arsenide Semiconductors

Semiconductors

Electronic Transport

Carrier Transport

Transport

Noise

GaAs

Scattering

Electronic Engineering

Charge Transport in Organic Light-Emitting Diodes

Schober, Matthias

29 November 2012

This thesis is about the development and validation of a numerical model for the simulation of the current-voltage characteristics of organic thin-film devices. The focus is on the analysis of a white organic light-emitting diode (OLED) with fluorescent blue and phosphorescent red and green emitters. The simulation model describes the charge transport as a one-dimensional drift-diffusion current and is developed on the basis of the Scharfetter-Gummel method. It incorporates modern theories for the charge transport in disordered organic materials, which are considered by means of special functions for the diffusion coefficient and the charge-carrier mobility. The algorithm is designed such that it can switch between different models for mobility and calculates both transient and steady-state solutions. In the analysis of the OLED, electron and hole transport are investigated separately in series of single-carrier devices. These test devices incorporate parts of the layers in the OLED between symmetrically arranged injection layers that are electrically doped. Thereby, the OLED layer sequence is reconstructed step by step. The analysis of the test devices allows to obtain the numerous parameters which are required for the simulation of the complete OLED and reveals many interesting features of the OLED. For instance, it is shown how the accumulation of charge carriers in front of an interface barrier increases the mobility and the transfer rate across the interface. Furthermore, it is demonstrated how to identify charge-trapping states. This leads to the detection of deep trap states in the emission zone of the OLED -- an interesting aspect, since these states can function as recombination centers and may cause non-radiative losses. Moreover, various other effects such as interface dipoles and a slight freeze-out of active electric dopants in the injection layers are observed. In the simulations of the numerous test devices, the parameters are consistently applied. Thereby, the agreement between simulation and experiment is excellent, which demonstrates the correctness and applicability of the developed model. Finally, the complete OLED is successfully simulated on the basis of the parameters that have been obtained in the analysis of the single-carrier devices. The simulation of the OLED illustrates the transport levels of electrons and holes, and proofs that the OLED efficiency is low because of non-radiative recombination in the interlayer between the phosphorescent and fluorescent emission zones. In this context, many interesting issues are discussed, e.g. the applicability of the Langevin model in combination with the mobility models for the description of recombination and the relevance of interactions between free charge carriers and excitons.

Organische Halbleiter

OLED

Simulation

Ladungsträgertransport

organic semiconductors

OLED

simulation

charge-carrier transport

ddc:530

rvk:VE 6300

rvk:UP 3130

Charge Transport in Organic Light-Emitting Diodes: Experiments & Simulations

Schober, Matthias

01 November 2012

This thesis is about the development and validation of a numerical model for the simulation of the current-voltage characteristics of organic thin-film devices. The focus is on the analysis of a white organic light-emitting diode (OLED) with fluorescent blue and phosphorescent red and green emitters. The simulation model describes the charge transport as a one-dimensional drift-diffusion current and is developed on the basis of the Scharfetter-Gummel method. It incorporates modern theories for the charge transport in disordered organic materials, which are considered by means of special functions for the diffusion coefficient and the charge-carrier mobility. The algorithm is designed such that it can switch between different models for mobility and calculates both transient and steady-state solutions. In the analysis of the OLED, electron and hole transport are investigated separately in series of single-carrier devices. These test devices incorporate parts of the layers in the OLED between symmetrically arranged injection layers that are electrically doped. Thereby, the OLED layer sequence is reconstructed step by step. The analysis of the test devices allows to obtain the numerous parameters which are required for the simulation of the complete OLED and reveals many interesting features of the OLED. For instance, it is shown how the accumulation of charge carriers in front of an interface barrier increases the mobility and the transfer rate across the interface. Furthermore, it is demonstrated how to identify charge-trapping states. This leads to the detection of deep trap states in the emission zone of the OLED -- an interesting aspect, since these states can function as recombination centers and may cause non-radiative losses. Moreover, various other effects such as interface dipoles and a slight freeze-out of active electric dopants in the injection layers are observed. In the simulations of the numerous test devices, the parameters are consistently applied. Thereby, the agreement between simulation and experiment is excellent, which demonstrates the correctness and applicability of the developed model. Finally, the complete OLED is successfully simulated on the basis of the parameters that have been obtained in the analysis of the single-carrier devices. The simulation of the OLED illustrates the transport levels of electrons and holes, and proofs that the OLED efficiency is low because of non-radiative recombination in the interlayer between the phosphorescent and fluorescent emission zones. In this context, many interesting issues are discussed, e.g. the applicability of the Langevin model in combination with the mobility models for the description of recombination and the relevance of interactions between free charge carriers and excitons.

info:eu-repo/classification/ddc/530

ddc:530

Electron-Lattice Dynamics in pi-Conjugated Systems

Hultell (Andersson), Magnus

January 2007

In this thesis we explore in particular the dynamics of a special type of quasi-particle in pi-conjugated materials termed polaron, the origin of which is intimately related to the strong interactions between the electronic and the vibrational degrees of freedom within these systems. In order to conduct such studies with the particular focus of each appended paper, we simultaneously solve the time-dependent Schrödinger equation and the lattice equation of motion with a three-dimensional extension of the famous Su-Schrieffer-Heeger (SSH) model Hamiltonian. In particular, we demonstrate in Paper I the applicability of the method to model transport dynamics in molecular crystals in a region were neither band theory nor perturbative treatments such as the Holstein model and extended Marcus theory apply. In Paper II we expand the model Hamiltonian to treat the revolution of phenylene rings around the sigma-bonds and demonstrate the great impact of stochastic ring torsion on the intra-chain mobility in conjugated polymers using poly[phenylene vinylene] (PPV) as a model system. Finally, in Paper III we go beyond the original purpose of the methodology and utilize its great flexibility to study radiationless relaxations of hot excitons. / Report code: LiU-TEK-LIC-2007:4.

Polaron dynamics

Exciton dynamics

pi-conjugated systems

Su-Schrieffer-Heeger (SSH) model

Adiabaticity

Charge carrier transport

Organic electronics.

Computational physics

Beräkningsfysik

Graphene Hot-electron Transistors

Vaziri, Sam

January 2016

Graphene base transistors (GBTs) have been, recently, proposed to overcome the intrinsic limitations of the graphene field effect transistors (GFETs) and exploit the graphene unique properties in high frequency (HF) applications. These devices utilize single layer graphene as the base material in the vertical hot-electron transistors. In an optimized GBT, the ultimate thinness of the graphene-base and its high conductivity, potentially, enable HF performance up to the THz region.  This thesis presents an experimental investigation on the GBTs as well as integration process developments for the fabrication of graphene-based devices. In this work, a full device fabrication and graphene integration process were designed with high CMOS compatibility considerations. To this aim, basic process modules, such as graphene transfer, deposition of materials on graphene, and formation of tunnel barriers, were developed and optimized. A PDMS-supporting graphene transfer process were introduced to facilitate the wet/dry wafer-scale transfer from metal substrate onto an arbitrarily substrate. In addition, dielectric deposition on graphene using atomic layer deposition (ALD) was investigated. These dielectric layers, mainly, served as the base-collector insulators in the fabricated GBTs. Moreover, the integration of silicon (Si) on the graphene surface was studied. Using the developed fabrication process, the first proof of concept devices were demonstrated. These devices utilized 5 nm-thick silicon oxide (SiO2) and about 20 nm-thick aluminum oxide (Al2O3) as the emitter-base insulator (EBI) and base-collector insulator (BCI). The direct current (DC) functionality of these devices exhibited &gt;104 on/off current ratios and a current transfer ratio of about 6%. The performance of these devices was limited by the non-optimized barrier parameters and device manufacturing technology. The possibility to improve and optimize the GBT performance was demonstrated by applying different barrier optimization approaches. Comparing to the proof of concept devices, several orders of magnitude higher injection current density was achieved using a bilayer dielectric tunnel barrier. Utilizing the novel TmSiO/TiO2 (1 nm/6 nm) dielectric stack, this tunnel barrier prevents defect mediated tunneling and, simultaneously, promotes the Fowler-Nordheim tunneling (FNT) and step tunneling (ST). Furthermore, it was shown that Si/graphene Schottky junction can significantly improve the current gain by reducing the electron backscattering at the base-collector barrier. In this thesis, a maximum current transfer ratio of about 35% has been achieved. / <p>QC 20160503</p>

Graphene

hot-electron transistors

graphene base transistors

GBT

cross-plane carrier transport

tunneling

ballistic transport

heterojunction transistors

graphene integration

graphene transfer

Engineering and Technology

Teknik och teknologier

Nouvelles architectures moléculaires électrodéficientes et solubles pour les transistors organiques à effet de champ de type n stables à l’air / New soluble molecular electron-acceptor architectures for air-stable n-type organic field effect transistors

Gruntz, Guillaume

18 November 2015

Un des enjeux principaux de l’électronique organique est le développement de circuits associant des transistors organiques à effet de champ (OFETs) de type p et de type n stables à l’air ainsi que leur fabrication par voie liquide. Si de nombreux matériaux de type p existent, les exemples de matériaux de type n stables sont plus rares. L’objectif de ce travail de thèse a ainsi été de concevoir, de synthétiser, et de caractériser de nouvelles molécules π-conjuguées électrodéficientes solubles afin de les intégrer dans des transistors organiques à effet de champ de type n (OFETs) stables à l’air. Dans ce but, le coeur aromatique d’un pigment reconnu très stable chimiquement, la triphénodioxazine (TPDO), a été fonctionnalisé avec des fonctions solubilisantes et des groupements électroattracteurs pour moduler ses propriétés de solubilité et augmenter son affinité électronique. Les nombreuses variations structurales réalisées ont conduit à une famille complète de dérivés électrodéficients. Les nouveaux composés, caractérisés à l’état liquide et solide, ont été intégrés dans des OFETs et ont démontré, pour la plupart, un transport de charges négatives efficace. Au-delà de la rationalisation des résultats obtenus lors des synthèses, des caractérisations des matériaux et des performances des dispositifs électroniques, un dérivé tétracyané a rempli l'ensemble du cahier des charges initial (solubilité, mobilité de type n, stabilité à l’air), ce qui valide la démarche adoptée. / One the main challenges of organic electronics is the fabrication of electronic circuits combining p-type and n-type organic field effect transistors which can be processed by liquid route and are stable in air. Even though many efficient p-type organic materials have been reported, the examples of n-type analogues are rare. The aim of this PhD research work was therefore to design, synthesize and characterize new soluble and electron-acceptor π-conjugated molecules and determine their ability to transport electrons in organic field effect transistors (OFETs) under air. In this aim, the aromatic core of a well-known stable pigment, the Triphenodioxazine (TPDO), was functionalized with solubilizing groups and electron-withdrawing functions to tune the solubility and to yield a higher electron affinity. The various structural modifications achieved provided a complete family of electro-deficient materials. The new compounds were characterized in liquid and solid state, and then integrated in OFETs. Most of them led to an efficient negative charge carrier transport. Hereafter of the rationalization of the results during synthesis, characterization of new materials and physical characterizations of devices, a tetracyano derivative has fulfilled the initial project specifications in terms of solubility, electron mobility and air stability of the performances

Transistor organique à effet de champ

Transport de charges négatives

Solubilité

Stabilité

Triphénodioxazine

Triphénodithiazine

Organic field effect transistor

Negative charge carrier transport

Solubility

Stability

Triphenodioxazine

Triphenodithiazine

Electron-Lattice Dynamics in pi-Conjugated Systems

Hultell (Andersson), Magnus

January 2007

<p>In this thesis we explore in particular the dynamics of a special type of quasi-particle in pi-conjugated materials termed polaron, the origin of which is intimately related to the strong interactions between the electronic and the vibrational degrees of freedom within these systems. In order to conduct such studies with the particular focus of each appended paper, we simultaneously solve the time-dependent Schrödinger equation and the lattice equation of motion with a three-dimensional extension of the famous Su-Schrieffer-Heeger (SSH) model Hamiltonian. In particular, we demonstrate in Paper I the applicability of the method to model transport dynamics in molecular crystals in a region were neither band theory nor perturbative treatments such as the Holstein model and extended Marcus theory apply. In Paper II we expand the model Hamiltonian to treat the revolution of phenylene rings around the sigma-bonds and demonstrate the great impact of stochastic ring torsion on the intra-chain mobility in conjugated polymers using poly[phenylene vinylene] (PPV) as a model system. Finally, in Paper III we go beyond the original purpose of the methodology and utilize its great flexibility to study radiationless relaxations of hot excitons.</p> / Report code: LiU-TEK-LIC-2007:4.

Polaron dynamics

Exciton dynamics

pi-conjugated systems

Su-Schrieffer-Heeger (SSH) model

Adiabaticity

Charge carrier transport

Organic electronics.

Computational physics

Beräkningsfysik